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PARASITES AND PARASITOSIS OF THE 
 DOMESTIC ANIMALS 
 
THE MACMILLAN COMPANY 
 
 MACMILLAN & CO., Limited 
 
 THE MACMILLAN CO. OF CANADA. Ltd. 
 
 TORONTO 
 
PARASITES AND PARASITOSIS 
 
 OF THE 
 
 DOMESTIC ANIMALS 
 
 THE ZOOLOGY AND CONTROL OF THE ANIMAL 
 
 PARASITES AND THE PATHOGENESIS AND 
 
 TREATMENT OF PARASITIC DISEASES 
 
 BY 
 
 B. M. UNDERHILL, V.M.D. 
 
 PROFESSOR OF PARASITOLOGY AND INSTRUCTOR IN ZOOLOGY AND 
 HISTOLOGY, SCHOOL OF VETERINARY MEDICINE, UNIVER- 
 SITY OF PENNSYLVANIA, ZOOLOGIST, DIVISION OF 
 LABORATORIES, PENNSYLVANIA STATE 
 BUREAU OF ANIMAL INDUSTRY 
 
 WITH 180 ILLUSTRATIONS 
 
 THE MACMILLAN COMPANY 
 
 1920 
 
 All rights reserved 
 
COPYKIGHT, 1920 
 
 By the MACMILLAN COMPANY 
 
 Set up and printed. Published April. 1920 
 
PREFACE 
 
 In the preparation of this work the author has aimed to present 
 clearh', concisely, and in orderly manner such matter pertaining to the 
 subject at hand as seems most essential to the needs of the student and 
 the practitioner. Notwithstanding its elementary character, the present 
 rapid advances in parasitology have necessitated numerous changes and 
 additions to the manuscript during its preparation. New species and 
 unsettling facts and theories as to some which are not new are, in these 
 days of intensive research, frequently l^eing brought to light and re- 
 ported upon. Some of these findings represent or lead to a distinct 
 advance and, though the observations be in certain cases upon obscure 
 and in themselves unimportant species, they may, by analogy, shed 
 valuable light upon life histories and modes of infection of related forms 
 known to be injurious to domestic animals and man. So frequent are 
 these steps forward that it might almost seem better to leave compara- 
 tive parasitology at the present time to the fragmental attention it has 
 mainly received, and possibly it is to this view that the lack of a recent 
 American volume upon the subject may be attributed. Be that as it 
 may, this book is not intended to be comprehensive, and it contains but 
 little discussion, historical or otherwise, of investigations in the field of 
 medical zoology, — limitations which ma.y, in measure, contribute to it a 
 longer period of usefulness in its present form than could be hoped for 
 in an exhaustive treatise. With but few exceptions, the parasites con- 
 sidered are those most likely to be met with and as to which most of the 
 facts pertaining to their biologv and pathogenicity have lieen well 
 established. 
 
 The treatment of the subject is based upon the advantages of pre- 
 senting it with at least a rudimental attention to the biologic principles 
 involved in parasitism, a knowledge of which is requisite to the proper 
 conception of parasitology and certainly essential to intelligently 
 applied measures of control. The direct and lucid style of the text 
 throughout will, it is hoped, bring these briefly considered fundamentals 
 before the reader in their true bearing upon the whole subject and render 
 the book particularly acceptalile to the general practitioner as well as to 
 the student. 
 
 Teachers will appreciate that laboratory work should supplement the 
 class-room method of study. Of course the student should in every 
 case see the parasite under consideration in so far as this is possible. 
 Methods of labomtor}" technique and the selection of type specimens for 
 
vi PREFACE 
 
 dissection should, in the author's opinion, be left to the teacher, who 
 should certainly be the one best qualified to fornnilatc the course adapted 
 to his needs. No general outline, therefore, as to laljoratory methods 
 has been attempted. 
 
 If, as has been said, orighiality is not the best reconnnendation for a 
 work of this kind, the author feels quite sure that its defects cannot to 
 any great extent be attributed to that source. His observations in the 
 field and laboratory have been utilized in the preparation of the book, 
 but contribute nothing to its pages that is advanced or aggressively 
 critical. Excluding the first three chapters, so much of the sul)ject- 
 matter has been drawn from the published results of the labors of others 
 that the numerous sources cannot well be enumerated here. Acknowl- 
 edgments are especially due to bulletins and articles upon various topics 
 of parasitolog}' written by workers in federal and state bureaus of ex- 
 perimental research. Other sources which have been relied upon and 
 freely used are: 'M. Neveu-Lemaire's Parasitologic des Animaux Domes- 
 iiques; Herms' Medical and Veterinary Entomology; Riley and Johann- 
 sen's Handbook of Medical Entomology; Calkins' Protozoology; Neumann's 
 Parasites and Parasitic Diseases of the Domesticated Animals; Bi-aun's 
 Animal Parasites of Man; The Journal of Parasitology; The American 
 Edition of Hutyra and Marek, and Osborn's Economic Zoology. 
 
 The author wishes to express his sincere appreciation and thanks to 
 his laboratory coworker. Dr. Fred Boerner, Jr., for his assistance in the 
 collection of specimens and in the examination of pathologic material; 
 also to Dr. William J. Lentz for his reading and valuable criticism of 
 parts of the manuscript, and to Dr. C. P. Fitch for his helpful suggestions 
 as to sources of reference. 
 
 Illustrations for a work of this character will ])e an aid to the text in 
 proportion as they are exact and well chosen. For the study of mor- 
 phologic characteristics photographs of actual specimens are often too 
 obscure in detail, and accurate drawings or line sketches are, as a rule, of 
 greater service. It will be observed that man}' of the figures in this 
 book are taken from publications issued by the United States Depart- 
 ment of Agriculture. Probably no better drawings of these subjects have 
 been produced, and the privilege granted to use them is esteemed as a 
 helpful favor of much value to the work. In this connection the author 
 would especially express his gratitude to Dr. L. 0. Howard. Chief of the 
 Bureau of Entomology, to Dr. John R. ]\Iohler, Chief of the Bureau of 
 Animal Industry, to Dr. Herbert Osborn, to Dr. Howard Crawley, and 
 to Dr. B. H. Ransom. Finally, thanks are due to Dr. W. H. Hoedt of 
 Philadelphia, for his skill and interest in preparing the photomicro- 
 graphs and many of the drawings. 
 
 B. ]\I. U. 
 
 Philadelphia, Pa. 
 
CONTENTS 
 
 PART I 
 
 PRELIMINARY CHAPTERS 
 THE EXTERNAL PARASITES 
 
 CHAPTER I 
 
 PAPE 
 
 Introduction 1 
 
 Origin of parasitism; Influences inhibiting organic multiplication; The 
 struggle for existence; The sheltered mode of life; Its effect; Phases of the 
 symbiotic relationship; Example of mutualism; Examples of commensalism ; 
 True parasitism; Adaptive and degenerative modifications of the parasite; 
 Faculties of parasitic and predatory animals compared; Simplicity, primitive 
 and degnerative; The Tunicata; Functions involved in adaptation to para- 
 sitism; The reproductive process in MeJophagus ovinus; Development oi the 
 reproductive function in parasites; Parasitism of Gaslrophilus inteslinalis; 
 Alternation of hosts in life cycle of parasites; The complicated cycle of the 
 liver fluke; The tapeworm as an example of extreme parasitism; Deductions 
 as to the systematic position of parasites through comparison with free-living 
 forms. 
 
 CHAPTER II 
 
 Forms of Parasitism and Influence upon the Host 7 
 
 Terms used in parasitology; Symbiosis; Mutualism; Commensalism; 
 Helotism; Parasitism; Phytoparasites; Zooparasites; Optional occasional 
 parasites; Obligate occasional parasites; Determinate transitory parasites; 
 Permanent parasites; Fixed parasites; Erratic parasites; Determinate 
 erratic parasites; Monoxenous parasites; Heteroxenous parasites; Trans- 
 migration; Incidental or stray parasites; Ectoparasites; Entoparasites; 
 Helminthes; Terms used in the designation of parasitic diseases; Preda- 
 cious and parasitic animals; Factors governing injuiy to the host by para- 
 sites; General etiologic factors. 
 
 CILIPTER III 
 
 Phulum I. Arthropoda 13 
 
 Characteristics of the Arthi'opoda; Characteristics of the class Insecta; 
 Insect methods of reproduction; Duration of life of insects. 
 
viii CONTEXTS 
 
 CHAPTER I\- 
 
 PAGE 
 
 Mosquitoes and Gnats ... 23 
 
 Characteristics of tlic order Diptera; Dipterous iiarasitisni; Charactis- 
 tics of the family Culicida^; Range and prevalence of mosquitoes; Their 
 breeding habits; Their pathologic importance; Tlie transmitter of malaria; 
 Methods of distinguisliiug between Anopheles and Culex; The transmitter of 
 yellow fever; Characteristics and habits of the species Atles caloirus; Effect 
 of mosquitoes upon live stock; Mosquito control; Characteristics of the 
 family Simuliida;; The Southern bufTalo gnat; Effect of its attack upon live 
 stock; Control: Protection and treatment. 
 
 CHAl'TER y 
 
 The Flies 35 
 
 Characteristics of the family Tabanidse; Horse-flies; Gad-flies; Effect of 
 their attack; Protection; Characteristics of the family Muscida; The 
 house-fly; Habits of the house-fly and its relation to the transmission of 
 disease; Its control; Protective measures; The horn fly; Its habits; Effect of 
 its attack; Its control; The tsetse flies; Characteristics of th£ genus Glossina; 
 Distribution and habits of tsetse flies; Their relationship to trypanosomiasis; 
 Investigations by Bruce and others; Tsetse fly control; Characteristics of 
 the family Hippoboscidaj; The "sheep tick" or "louse fly;" Its effect; 
 Treatment. 
 
 chapti:r \T 
 
 The Dipterous Larv.f, 50 
 
 Myasis; The "screw worm fly;" Its habits; Effect of its attack; Pro- 
 tective measures; Treatment; The flesh flies; The blowfly; Its habits; 
 Protective measures; Characteristics of the family CEstridae; The horse 
 bot flies; Gastrophilus inteslinnlls; Its habits and life history; Effect of the 
 fly and larva) upon horses; The red-tailed bot-fly; Its habits and effect; The 
 chin fly; The ox bot or warble flies; Tlunr life history; Their economic im- 
 portance; The sheep bot fly; Its habits and life history; Effect of the at- 
 tack of the fly and its larva>; Protection and treatment. 
 
 CHAPTER VII 
 
 The Fleas 65 
 
 Characteristics of the order Siphonaptera; The dog, cat, and human fleas; 
 Differentiation of species; Life history; Relation of fleas to the transmis- 
 sion of infectious diseases; Treatment and control, 
 
 CHAPTER VIII 
 
 The Lice 70 
 
 The sucking lice; Characteristics of the order Siphunculata; The biting 
 lice; Characteristics of the order Mallophaga; Pediculosis of domestic ani- 
 
CONTENTS ix 
 
 PAGE 
 
 mals in general; Pediculosis of the horse; Pediculosis of cattle; Pediculosis 
 of the sheep and goat; Pediculosis of the hog; Pediculosis of the dog and 
 cat; Pediculosis of man; Control and treatment of pediculosis. 
 
 CHAPTER IX 
 
 Lice of Poultry; The Bedbug 82 
 
 Prevalence and effect of poultry lice; Species infesting chickens; Species 
 infesting turkej-s; Species infesting ducks and geese; Species infesting 
 swan; Species infesting pigeons; Control and treatment of poultry lice; 
 Characteristics of the order Hemiptera; Characteristics of the family Cimi- 
 cida); The common bedbug; Its habits and effect of its bite; The bedbug as 
 a pest of poultry; Control. 
 
 CHAPTER X 
 
 The Mites 94 
 
 Characteristics of the class Arachnida; Characteristics of the order Acar- 
 ina; Parasitism oi the Acarina; Acariasis; Characteristics of the family Ga- 
 masidse; The gamasid mites of poultry; Habits and effect of their attack; 
 Control; Characteristics of the family Trombidiidse ; The harvest mites, 
 chiggers, or red bugs; Habits and effect of their attack; Treatment; The 
 mange, scab, or itch mites; Characteristics of the family Sarcoptidaj; The 
 genera Sarcoptes; Notoedrcs, Otodectes, Cnemidocoptes, Laminosioptes, 
 Cj'toleichus, Psoroptes, and Chorioptes; Their respective characteristics, 
 hosts, and modes of attack; Characteristics of the family Demodecidse; 
 Mange and scabies of the various domestic animals; Sarcoptic mange; De- 
 modectic or foUicular mange; Notoedric or head mange of the cat and rab- 
 bit; Otodectic or auricular mange; Psoroptic scabies; Auricular scabies oi 
 the rabbit; Chorioptic or leg scabies; Symptoms, development, lesions, diag- 
 nosis, and transmission of mange and scabies. 
 
 CHAPTER XI 
 
 Treatment of Mange and Scabies 120 
 
 General considerations; Treatment of sarcoptic mange ot the horse; Of 
 the dog; Of the goat; Of the sheep; Of cattle; Treatment of notoedric mange 
 of the cat and rabbit; Treatment of demodectic mange; Treatment of oto- 
 dectic mange; Treatment of psoroptic scabies of the sheep; of cattle; Of 
 the horse; Of the rabbit, Treatment of chorioptic scabies of the horse; Of 
 cattle. 
 
 CHAPTER XII 
 
 Mange of Poultry 132 
 
 The burrowing mite of poultry-; Leg mange or "scaly leg"; Its course 
 and treatment; The depluming mite; The deep-seated acariases of birds; The 
 family Cytoleichidse ; The connective tissue mite; The air passage mite. 
 
X CONTENTS 
 
 CHAPTER XIII 
 
 PAGE 
 
 The Ticks 136 
 
 Structure of ticks in general; Characteristics of the superfamily Ixo- 
 doidea; Characteristics of the family Argasidte; The fowl tick; Its habits and 
 effect upon the host; Control; The spinose ear tick; Its habits and effect upon 
 the host; Treatment; Characteristics of the family Ixodidse; Description of 
 genera; Species found upon domestic animals in the United States; The 
 Texas-fever or Southern cattle tick; Biological data established by the Zool- 
 ogical Division of the United States Bureau of Animal Industry; Life his- 
 tory of the Texas-fever tick; Its nonparasitic development; Its parasitic 
 development; Loss occasioned by the Texas-fever tick; Progress made in its 
 eradication; The order Linguatulida; Lingualula rhinarin of the nasal cavi- 
 ties of mammals. 
 
 PART II 
 
 THE INTERNAL PARASITES 
 CHAPTER XIV 
 
 Phylum II. Platyhklminthes; The Flukes and Tapeworms 155 
 
 Classification of the parasitic worms; Characteristics of the Platyhelm- 
 inthes; Characteristics of the class Trematoda; The liver flukes; Their life 
 history; Prevalence of fascioliasis; Infection; Migration of flukes within the 
 definitive host and pathogenesis; Fascioliasis of the sheep; Fascioliasis of 
 cattle; Control and treatment; The blood fluke; Bilharziosis; Characteristics 
 of the class Cestoda; Characteristics of the family Tseniidfp; Life history of 
 tapeworms; Their parasitism. 
 
 CHAPTER XV 
 
 T^niasls 174 
 
 General consideration of the effect of tapeworms upon their hosts; Tape- 
 worms of the horse; Tapeworms of cattle, sheep, and goats; Tapeworms of 
 the dog; Dog tapewomis in relation to human infection; Tapewonns of 
 the cat; Tapeworms of the rabbit; Characteristics of the family DiphyUo- 
 bothriidae; Occurrence of species; Treatment of tseniasis of the dog; Pre- 
 vention; Treatment of tseniasis of the cat; Treatment of tseniasis of sheep, 
 goats, and cattle; Treatment of ta?niasis of the horse. 
 
 CHAPTER XVI 
 
 Tapeworms of Chickens 189 
 
 Characteristics of species; Investigations as to their relative occurrence; 
 Symptoms; Control; Treatment. 
 
CONTENTS xi 
 
 CHAPTER XVII 
 
 PAGE 
 
 The Tapeworm Larv^ 194 
 
 Pathologic importance; Forms and their characteristics, Cysticercosis 
 or measles; Beef measles; Its occurrence; Degeneration and vitality of the 
 cysts; Pork measles, Its occuri'ence; Degeneration and vitality of the cysts; 
 Measles of the sheep; Ccenurosis or gid; Its occurrence; Its development; 
 Its post-mortem appearance; Its sj-mptoms; Control and treatment; Echin- 
 ococcosis or hj'datid disease; Structure of the echinococcus cyst; Its de- 
 velopment; Post-mortem appearance in echinococcosis; Sj-mptoms; Con- 
 trol. 
 
 CHAPTER XVIII 
 
 Phylum III. Ccelhelminthes; The Smooth and Segmented Roundworms . . . 216 
 Characteristics of the Ccelhelminthes; Characteristics of the class Xe- 
 mathelminthes; Characteristics of the order Xematoda: Parasitism of the 
 nematode worms in general; General considerations as to treatment. 
 
 CHAPTER XIX 
 
 Nematoda; Family I. AscARro^E; The Large Roundworms of the Intestine 229 
 Characteristics of the Ascaridse; Investigations as to life history; Ascar- 
 iasis; Ascarids of the horse; Occurrence of equine ascariasis; Its etiology, 
 control, and treatment; Characteristics of the famih- Oxjairidse; Oxyuriasis 
 of equines; Ascarids of the dog and cat; Ascarids of the hog and -sheep; As- 
 carids of the ox; The family Heterakida) and heterakiasis of poultry. 
 
 CHAPTER XX 
 
 Nematoda; Family IV. Filariid^e; The Thread-like Worms 244 
 
 Characteristics of the Filariida?; Parasitism; Filaria of the horse; Their oc- 
 currence; Effect of filariasis upon equines; Filaria of sheep and cattle; Filaria 
 of the dog; Hematic filariasis; Filaria of the hog; Filaria of poultry. 
 
 CHAPTER XXI 
 
 Nematoda; Family V. Strongylid^e; Subfamily I. Metastrongylin^ 
 
 Worms of the Respiratory Tract 255 
 
 Characteristics of the Strongylidse ; Parasitism; Strongylosis; Characteris- 
 tics of the JNIetastrongj-linse; Parasitism; Bronchial and pulmonary strongy- 
 losis of the sheep and goat; Its symptoms, course, and prognosis; Bronchial 
 and pulmonary strongylosis of cattle; Its symptoms, course, and prog- 
 nosis; Bronchial and pulmonary strongylosis of the pig; Its occurence and 
 sj-mptoms; Bronchial and pulmonary strongjdosis of the horse; Cardio- 
 pulmonary strongj'losis of the dog; Pulmonary strongylosis of the cat; Post- 
 mortem appearance in bronchial and pulmonary strongj'losis; Develop- 
 ment, etiology, control, and treatment of bronchial and pulmonary strongj'- 
 losis. 
 
xii CONTENTS 
 
 CHAPTER XXII 
 
 PAGE 
 
 Nematoda; Subfamily IT. Trichostroxgylin.e; Worms of the STOiiACH 
 
 AND Intestine 268 
 
 Characteristics of the Trichostrongylinse ; Parasitism; Gastro-intestinal 
 strongylosis of the sheep and goat; Its occurrence; Its symptoms; Gastro- 
 intestinal strongylosis of cattle; Its occurrence; Its symptoms; Post-mortem 
 appearance in gaslro-intestinal strongylosis, Development, etiology, con- 
 trol, and treatment of gastro-intestinal strongj'losis. 
 
 CHAPTER XXIII 
 
 Nematoda; Subfamily III. Stroxgylin.e; Worms of the Large and Small 
 
 Intestines; Other Strongyles 280 
 
 Characteristics of the Strongylinae; Parasitism; Nodular strongylosis of 
 the sheep and goat; Its occurrence; Its development; Its post-mortem ap- 
 pearance; Its symptoms; Treatment; Nodular strongylosis of cattle; Nodu- 
 lar strongylosis of the hog; Strongylosis of the large intestine of the sheep and 
 goat; Strongylosis of the intestines of the horse; Its development; Its symp- 
 toms; Its post-mortem appearance; Intestinal strongylosis of the dog and 
 cat; Other Strongyhnse; Tracheal strongylo.sis of chickens; The kidney 
 worm of the hog; Family Eustrongylidse and eustrongylosis. 
 
 CHAPTER XXIV 
 
 Nematoda; Family VII. Trichinellid.e 299 
 
 Characteristics of the Trichinellidae ; The "whip-worms" of the large 
 intestine; Tnchinclla spiralis and trichinosis; Life history of Trichinella 
 spiralis; Intestinal trichinosis; Muscular trichinosis; Degeneration of the 
 trichina cyst; Infection; Symptoms of intestinal and muscular trichinosis in 
 hogs; Trichinosis in rats and mice; Prophylaxis. 
 
 CHAPTER XXV 
 
 The Thorn-headed Worm; The Leeches 306 
 
 Characteristics of the order A(;anthocephala; The thorn-headed worm of 
 the intestines of the hog; Its life history; Its occurrence; Its pathogenicity; 
 Symptoms produced; Treatment; Characteristics of the class Annelida; 
 Characteristics of the order Hirudinea; The horse leech; The medicinal 
 leech; Sources of infestation by leeches; Their effect upon the animal at- 
 tacked; Treatment. 
 
CONTENTS xiii 
 
 PART III 
 
 ■THE PATHOGENIC PROTOZOA 
 
 CHAPTER XXVI 
 
 PAGE 
 
 PHYLrji IV. Protozoa 311 
 
 General consideration of the Protozoa; Characters differentiating Pro- 
 tozoa from Metazoa; Ameba, its main features for study; Parasitism of 
 the Protozoa; Progress of research; Relationship of arthropods to infection 
 with protozoal diseases; Evolution of pathogenicity in Protozoa; Methods 
 of reproduction in free and parasitic forms; Life history of the malaria or- 
 ganisms; The schizogonic or asexual cycle; The sporogonic or sexual cycle; 
 Classification of pathogenic species. 
 
 CHAPTER XXVII 
 
 The Protozoan Subgroups; Diseases Due to Protozoa 324 
 
 Characteristics of the class Rhizopoda; Infectious entero-hepatitis of tur- 
 keys; Amebic dysentery of man; Characteristics of the class Flagellata; 
 Characteristics of the order Spirochetida; Spirochetosis of poultry; Char- 
 acteristics of the order Trypanosomatida; Parasitism; Transmission of 
 the infecting organisms; Nagana or "fly disease;" Surra, Mai de Caderas; 
 Dourine; Trypanosoma aviericanurn; Characteristics of the class Sporozoa; 
 Characteristics of the order Coccidia; Coccidiosis; Eimeria stiedce; Cocci- 
 diosisof rabbits; Diplospora bigemina; Coccidiosis ot dogs; Coccidium zurni; 
 Red dysentery of cattle; Eimeria avium; Coccidial enteritis of chicks; Char- 
 acteristics of the order Hemosporidia; Piroplasma higeminum; Texas-fever 
 of cattle; Its occurrence; Exposure and development; Its symptoms; The 
 acute type; The chronic type; Prevention and treatment; Characteristics of 
 the order Sarccsporidia; Sarcosporidiosis; Mode of infection. 
 
 Glossary 353 
 
 Index 359 
 
LIST OF ILLUSTRATIONS 
 
 FIG. PAGE 
 
 1. Diagram of an insect 16 
 
 2. Diagram of internal parts of an insect 16 
 
 3. Diagram of insect's heart 17 
 
 4. Mouth parts of a biting insect 17 
 
 5. Diagram showing tracheal system of an insect 18 
 
 6. Abdomen of locust, showing spiracles IS 
 
 7. Head of bee, showing compound eyes, ocelli, and antennse 19 
 
 8. Metamorphosis of the house fly 19 
 
 9. Diagram of segments of arthropod, showing leg muscles, etc 19 
 
 10. Eggs and larvse, of Culex mosquito 2-4 
 
 11. Pupa, of Culex and Anopheles mosquitoes 26 
 
 12. Culex pungens, male and female 27 
 
 13. Anopheles quadrimaculatus, male and female 28 
 
 14. Position of Anopheles and Culex at rest 28 
 
 15. Breathing position of larva, of Anopheles and Culex 29 
 
 16. Eggs of Anopheles 30 
 
 17. The Southern buffalo gnat 32 
 
 18. Larva of Southern buffalo gnat 33 
 
 19. Pupa of Southern buffalo gnat 33 
 
 20. The black horsefly 36 
 
 21. The green-head fly 36 
 
 22. The stable or stinging fly 39 
 
 23. The horn fly 42 
 
 24. Tsetse fly 44 
 
 25. The "sheep tick." 47 
 
 26. The screw worm fly 51 
 
 27. Metamorphosis of the flesh fly 52 
 
 28. Horse botfly, showing eggs, larva, and adult 54 
 
 29. Ox botfly, Hypoderma Uneata 58 
 
 30. Ox botfly, Hypoderma bovis 59 
 
 31. Eggs of Hypodemia lineata 59 
 
 32. Larval stages of Hj^poderma lineata _,. 61 
 
 33. The sheep botfly, showing larva, pupa, and adult 63 
 
 34. The dog flea, anterior portion of body 66 
 
 35. The human flea, anterior portion of Ijodj- 66 
 
 36. The dog flea, showing development and mouth-parts 67 
 
 37. Larva of flea 68 
 
 38. Sucking louse of horse, Hsematopinus asini 73 
 
<vi LIST OF ILLUSTRATIONS 
 
 IG. PAGE 
 
 39. Biting louse of horse, Trichodectes parumpilosus 73 
 
 40. Sucking louse of cattle, Ha?matopiuus eurysternus 74 
 
 41. Sucking louse of calves, Linognathus (Haematopinus) vituli 75 
 
 42. Biting louse of cattle, Trichodectes scalaris 75 
 
 43. Sucking louse of sheep, Linognathus (Hsematopinus) pedalis 76 
 
 44. Biting louse of sheep, Trichodectes sphiprocephalus 77 
 
 45. Sucking louse of hog, Hsematopinus suis 78 
 
 46. Sucking louse of dog, Linognathus (Hsematopinus) piliferus 78 
 
 47. Biting louse of dog, Trichodectes latus 79 
 
 48. Louse of the cat, Trichodectes subrostratus 79 
 
 49. Louse of chicken, Goniocotes gigas (G. abdominalis) 83 
 
 50. Louse of chicken, Lipeurus caponis (L. variabihs) '. . 83 
 
 5L Louse of chicken, Menopum trigonocephalum (Menopon pallidum) . 83 
 
 52. Louse of turkey, Goniodes stylifer 85 
 
 53. Louse of turkey, Lipeurus meleagridis (L. poly trapezius) 85 
 
 54. Louse of turkey, Menopum (Menopon) biseriatum 85 
 
 55. Louse of duck, Lipeuris anatis (L. squalidus) 85 
 
 56. Louse of ducks and geese, Trinotum (Trinoton) luridum 87 
 
 57. Louse of swan, Philopterus (Docophorus) cygni 87 
 
 58. Louse of swan, Ornithonomus (Ornithobius) cygni 87 
 
 59. Louse of pigeon, Goniocotes conipar 87 
 
 60. Louse of pigeon, Goniodes damicornis 87 
 
 6L Bedbug, adult female, mouth-parts etc 91 
 
 62. Diagram of the anatomy of a spider 95 
 
 63. Gamasid poultry mite, young and adult 98 
 
 64. Mange mite of horse 104 
 
 65. Mange mite burrow in human skin 105 
 
 66. Colts affected with sarcoptic mange 106 
 
 67. Leg scab mite of horse 109 
 
 68. Scab mite of sheep, female Ill 
 
 69. Scab mite of sheep, male HI 
 
 70. Follicular mange mite 116 
 
 71. Mange mite of cat and rabbit 118 
 
 72. Auricular scab mite of rabbit 118 
 
 73. Portable dipping vat for sheep 127 
 
 74. Mite of scaly leg of poultry, male and female 133 
 
 75. Foot of fowl affected with scaly leg 134 
 
 76. Capitulum of tick 137 
 
 77. Capitulum, scutum, and fore leg of Texas fever tick 137 
 
 78. Stigmal plates of ticks Margaropus, Ixodes, and Dermacentor. . . . 138 
 78a. Photomicrograph of stigmal plate of Texas fever tick 138 
 
 79. Fowl tick, adult and larva 139 
 
 80. Spinose ear tick, nymphal form 141 
 
LIST OF ILLUSTRATIONS xvii 
 
 FIG. PAGE 
 
 81. The castor-bean tick 143 
 
 S2. The American dog or wood tick 144 
 
 83. Linguatula rhinaria 153 
 
 84. Planarian wonn 156 
 
 85. Liver fluke, Fasciola hepatica 157 
 
 86. Reproductive organs of liver fluke 158 
 
 87. Fasciola hepatica, F. americanus, Dicrocceliuni lanceatum 161 
 
 88. Life history of Hver fluke 162 
 
 89. Blood fluke, male and female 168 
 
 90. Segment of Taenia saginata, showing sexual organs 171 
 
 91. Tapeworms of the horses 175 
 
 92. Tapewonn of cattle and sheep, Moniezia expansa 176 
 
 93. Fringed tapeworm of sheep, anterior segments 177 
 
 94. Tapewonn of dog, Dipjdidium caninum ISO 
 
 95. Rostellum of Dipylidium caninum 180 
 
 96. Egg packet and Cysticercoid of Dipylidium caninum 180 
 
 97. Tapeworm of dog. Taenia hydatigena 180 
 
 98. Tapeworm of dog, Taenia pisiformis 180 
 
 99. Tapewonn of dog, Echinococcus granulosus 180 
 
 100. Rostellum of tapewonn of cat. Taenia taeniaeformis 184 
 
 101 . Diphyllobothriimi latum 186 
 
 102. Tapewonn of chicken, Clioanotsenia infundibulifonnis 189 
 
 103. Scolex of Choanotaenia infundibulifonnis 190 
 
 104. Scolex of Davainea tetragona of chicken 190 
 
 105. Scolex of Davainea echinobothrida of chicken 190 
 
 106. Tapeworm of man, Taenia saginata 196 
 
 107. Diagram of Cysticercus 198 
 
 108. Fragment of beef muscle, showing cysts of Cysticerus bovis 198 
 
 109. Scoleces of Taenia solium, T. saginata, and DiphA'llobothrivun Latum . . . 199 
 
 110. Eggs of Taenia saginata and T. solium 200 
 
 111. Alature segments of Taenia saginata and T. solium 200 
 
 112. Stages in tapeworm development 201 
 
 113. Portions of adult gid tapeworm, Multiceps multicejis 205 
 
 114. Diagrammatic section of Multiceps (Coenurus) cyst 206 
 
 115. Brain of lamb, showing furrows produced by young gid bladderwonn. . 206 
 
 116. Gid bladderwonn, showing immature tapewonn heads 206 
 
 117. Diagram of Echinococcus hydatid 211 
 
 118. Echinococcus granulosus, showing hydatid with brood capsules 214 
 
 119. Transection of Ascaris equi 217 
 
 120. Posterior extremit^^ of male nematode worm 218 
 
 121. Cephalic extremity' of an ascarid worm 229 
 
 122. Ox^vuris equi 236 
 
 123. Belascaris marginata, showing head and male and female 238 
 
xviii LIST OF ILLUSTRATIONS 
 
 FIG. PAGE 
 
 124. Egg of Ascaris lumbricoides 240 
 
 125. Ascaris lumbricoides, male and female 240 
 
 126. Heterakis perspicillum, male and female, and H. vesicularis of poultrj^ 242 
 
 127. Setaria labiato-papillosa, male and female 245 
 
 128. Gong5donema scutata, anterior and posterior views 247 
 
 129. Dirofilaria imonitis, male and female 249 
 
 130. Lung wonn of sheep and goat, Dictj'-ocaulus filaria, male, female, and 
 
 eggs 257 
 
 131. Lung wonn of sheep, goat, and rabbit, Synthetocaulus rufescens, male 
 
 and female 257 
 
 132. Lung worm of cattle, Dictyocaulus viviparous 259 
 
 133. Lung worm of pig, Metastrongylus apri, male and female 260 
 
 134. Stomach worm of sheep, goat, and cattle, Hsemonchus contortus, 
 
 female 269 
 
 135. Hsemonchus contortus, anterior portion of body 269 
 
 136. Hsemonchus contortus, enlarged posterior extremity of male 269 
 
 137. Cooperia curticei, male and female 270 
 
 138. Cooperia curticei, enlarged anterior portion 270 
 
 139. Ostertagia marshalli, male and female 270 
 
 14Q. Trichostrongylus instabiUs, male and female 271 
 
 141. Ostertagia ostertagi, male and female 273 
 
 142. Ostertagia ostertagi, posterior extremity of male enlarged 273 
 
 143. Nematodirus fihcollis, male and female and enlarged anterior portion . . 274 
 
 144. Cooperia oncophora, male and female 274 
 
 145. (Esophagostomum columbianmn, male and female 282 
 
 146. QEsophagostomum columbianum, enlarged anterior portion 282 
 
 147. (Esophagostomum colmnbianum, enlarged bursa of male 283 
 
 148. (Esophagostomum venulosum, male and female 283 
 
 149. (Esophagostomum venulosum, enlarged anterior portion 283 
 
 150. (Esophagostomum venulosum, enlarged bursa of male 283 
 
 151. (Esophagostomum radiatum, male and female 286 
 
 152. (Esophagostomum radiatum, enlarged anterior portion • 286 
 
 153. (Esophagostomum radiatum, enlarged bursa of male 286 
 
 154. Chabertia ovina, male and female 287 
 
 155. Strongjdus equinus, male and female 288 
 
 156. Hook-worm of dog and cat, Ankylostoma canina, male and female . . 292 
 
 157. Bunostomum phlebotomum, male and female 293 
 
 158. Tracheal wonn of poultry, Syngamus trachealis, male and female. . 294 
 
 159. Dioctophjine renale, male 297 
 
 160. Trichuris ovis, male and female 300 
 
 161. Trichuris ovis, egg 300 
 
 162. Trichinella spiralis, male and female 301 
 
 163. Trichinella spirahs, encysted larva in muscle 302 
 
LIST OF ILLUSTRATIONS xix 
 
 FIG. PAGE 
 
 164. Trichiuella spiralis, microphotograph of cyst 304 
 
 165. The thorn-headed wonii, Gigautorhjnichus hirudinaceus 307 
 
 166. Cephalic extremity of thorn-headed wonn 307 
 
 167. The horse leech 308 
 
 168. Anieba proteus 312 
 
 169. Spirocheta palhda 327 
 
 170. Hen sufTering from acute spirochetosis .• 328 
 
 171. Piroplasma bigeminum 348 
 
 172. Fonns of Sarcosporidia, shown in infected muscle 351 
 
 Plates. Page 
 
 I. Texas fever tick, male and female, with details 146 
 
 II. Texas fever tick, stages of engorgement and details 147 
 
 III. Evolution of the parasite of kala-azar 317 
 
 IV. Life cycle of the malaria parasite 321 
 
 V. Various species of Trypanosoma 331 
 
 YI. Percheron stallion before and after development of dourine 338 
 
 VII. Percheron mares, sho\\'ing chronic dourine and last stage 340 
 
 VIII. Coccidian life cycle 344 
 
 TABLES 
 
 Classification of parasites of the class Insecta 20 
 
 Life history of horse botfly, Gastrophilus equi 55 
 
 Life history of sheep botfly, (Estrus ovis 63 
 
 Classification of parasites of the class Arachnida 96 
 
 Sunmaary on nonparasitic periods in de^•elopment of Texas fever tick 149 
 
 Sunmiary on parasitic periods in development of Texas fever tick 150 
 
 Life histories of dog tick and Texas fever tick compared 151 
 
 Classification of parasites of the phylum Platyhehninthes 157 
 
 Life history of liver fluke, Fasciola hepatica 163 
 
 Life history of beef tapewonn. Taenia saginata 172 
 
 The principal tapewomis, with their larvfe and hosts 173 
 
 Synopsis of tapewonn larvse 194 
 
 Life history of the gid tapewonn, Multiceps multiceps 207 
 
 Life history of Echinococcus granulosus 213 
 
 Classification of parasites of the phylum Coelhelminthes 222 
 
 Life history of Trichinella spiralis 303 
 
 Classification of parasites of the phylum Protozoa 322 
 
PARASITES AND PARASITOSIS OF THE 
 DOMESTIC ANIMALS 
 
PARASITES AND PARASITOSIS OF THE 
 DOMESTIC ANIMALS 
 
 PART I 
 
 PRELOIIXARY CHAPTERS 
 
 THE EXTERNAL PARASITES 
 
 CHAPTER I 
 INTRODUCTION 
 
 The earth's vast hiboratory of hvmg matter inchides a flora and fauna 
 in which all of the hiohly diversified forms encomiter conditions operating 
 to restrict their miiltiphcation and to govern the predominance of cer- 
 tain forms over others. These contUtions are constituted, first, by 
 topographic and climatic variations rendering certain localities more or 
 less inhospital)le to some organisms, while others may be uninfluenced or 
 perhaps benefited. Second, there is the behavior of living things toward 
 one another; this may l)e relatively harmonious or there may be an 
 intense rivalry in which organisms encroach or prey one upon the other, 
 the least fit for the strife being driven to less favorable habitats, progres- 
 sively dwarfed, or ultimately becoming extinct. Though most of these 
 inhibitive influences are not apparent to cursory observation, the}' are, 
 nevertheless, numerous and varied as well as constant in their operation, 
 constituting a prime factor in the evolution and specialization of organic 
 forms. 
 
 There is, then, a perpetual struggle for existence, which may lead to 
 the seeking of shelter from the conflict in a changed and often degenerate 
 mode of life to which the organism becomes adaptively modified. Thus, 
 through such uifluences, a terrestrial animal may be driven to an ar- 
 boreal, or even an aquatic or semiaquatic, existence. A defenseless Httle 
 member of the Insectivora burrows and becomes subterranean, while 
 another finds protection in the nocturnal habit; others seek the shelter 
 of caves or rock crevices, and we often find creatures, usually somewhat 
 degenerate, in places which seem to us quite unfavorable to their sup- 
 port. While in such cases the animal continues to lead a free and in- 
 
2 PARASITES OF THE DOMESTIC ANIMALS 
 
 dependent, often solitary existence, on the other hand, a communion of 
 life's interests may be estabhshed between two organisms which, it is 
 surmised, is founded upon some nmtual advantage in the strife. To 
 such association the general term s>Tiibiosis has been applied and each 
 of the organisms concerned is referred to as a SAaubiont. Though there 
 is by no means a uniformity in the appHcation of terms referring to the 
 symbiotic relationship, a usage is adopted here that seems best defined, 
 and by which s>mibiosis is subdivided into the three categories, (1) mu- 
 tualism, (2) commensalism, and (3) parasitism. In the first there is a 
 reciprocal advantage derived from the union; in the second but one 
 s\Tnbiont is benefited though the other suffers no harm, while in the 
 third division one receives an advantage to the detriment of the animal 
 or plant which it invades. There is, however, no sharp line of demarca- 
 tion between these three states of living together, and it may be difficult 
 to determine in some cases whether one or both symbionts receives 
 benefit from the union, or whether one is or is not injured by it. 
 
 One of the more obvious examples of mutualism is the case of the- 
 hermit crab and the sea anemone. This crab selects a shell, as that of 
 the whelk, for its habitation, from the opening of which it projects only 
 its head and claws. On the surface of the shell may often be found a sea 
 anemone fastened near the opening with its mouth and tentacles in the 
 vicinity of the crab's head. The anemone in this position not only in a 
 measure serves to conceal the hermit crab from its enemies, but the 
 creature that would prey upon the crab must first reckon with the 
 dangerous stinging threads with which the tentacles of the anemone are 
 armed. The anemone, in its turn, is benefited by being carried about 
 by the crab and aided in this way in obtaining its food. 
 
 Such associations are not always of mutual advantage, and maj' be 
 more in the nature of an invasion of one animal upon or within the 
 body of another, the invading animal alone deriving benefit, while the 
 animal upon which the association is forced, though not benefiting, 
 ma}^ in no way suffer from it. A familiar form of this living together 
 (commensalism) is the little crab so commonly found in the shell of the 
 oyster. The oyster is not harmed by its presence, but the crab is bene- 
 fited by the protection which the shell affords. Another more curious 
 example of such association is afforded among the vertebrates by the 
 species of Remora, or suck fishes, which have the first dorsal fin modified 
 into a sucking disk on top of the head. By means of this disk it attaches 
 itself to a shark or other large fish, and is thus carried about, detaching 
 itself only to secure food. Its benefit from such association is in being- 
 carried to new feeding grounds without effort of its own, and in the 
 shelter from its enemies which the body of the larger fish may afford. 
 The host, on the other hand, cannot be benefited, nor does it seem to 
 suffer by the presence of its uninvited guest. 
 
INTRODUCTION 3 
 
 AVhether this relationship between different species is of reciprocal 
 advantage or of benefit to but one, neither of the s\anbionts lives upon 
 or at the expense of its co-sjnnbiont, and neither has entirely renounced 
 its independence. In true parasitism the invading animal lives upon the 
 tissues of its host, deprives it of a portion of its nourishment; or is in 
 other wa3'S injurious to it. There are many examples of this form of 
 symbiosis, and students of animal life are familiar with the conditions 
 that seem always to attend it, such as the degenerative and adaptive 
 modifications occurrmg in the parasite. 
 
 It is the common habit of many animals, however, to prey upon the 
 bodies of other animals, and we should distinguish, so far as we may, 
 between those which are predatory and those which are parasitic. The 
 former are free and exercise their powers of sense and cunning in snarmg 
 or chasing their pre}', while the latter, in fully acquired parasitism, live 
 on or in the bodies of their victims, often burrowing into and consummg 
 the bod}' tissues, leading a lazy, beggarly existence in which all of the 
 faculties of special sense and prowess, so highly developed m predatoiy 
 animals, become degenerate and atrophied. 
 
 Parasitism is found throughout the range of animal life from the 
 unicellular to the vertebrate, and, though a sharp distinction between 
 predaceous and parasitic animals may not be made, in view of the de- 
 grading influence of the parasitic habit, the difference between the 
 simplicit}^ of degeneration and the simplicity of primitiveness should be 
 clearly defined. In the development of a primitively simple animal the 
 young stages are more simple than in the adult and it has only simple 
 ancestors. In the degenerate animal, on the other hand, the ancestors are 
 often more complex and the young stages are of a higher grade than the 
 stage of the adult. The adoption of any mode of life which withdraws 
 from the activities necessar}^ to survival in a free existence seems to 
 bring about this condition of degradation. Of this we have a remarkable 
 example outside of the realm of parasitism in the Tunicata. These 
 aberrant animals, in the stage of the free-swimming larva, have a chordal 
 axis which in nearly all of the different species becomes entirely lost 
 before they reach maturity. After passing the "tadpole" stage there 
 follows an extreme specialization to the fixed habit which most tunicates 
 retain throughout their adult life, becommg what are commonly known 
 as sea squirts, mere attached, plant-like sacs, emitting a jet of water 
 when disturbed, and from Avhich all chordate features have been entirely 
 lost. 
 
 The degenerative changes which a parasite undergoes concern mostly 
 the nervous system, the organs of locomotion, and those of nutrition, the 
 nervous system becoming reduced to the most indispensable portion, 
 while of the sense-organs nothing may be left except those of touch. The 
 locomotor apparatus may become modified into claws or hooks for 
 
4 PARASITES OF THE DOMESTIC ANIMALS 
 
 clasping the hairs of the host, or it may ahiiost if not completely dis- 
 appear and be replaced b}^ such organs of fixation as sucking-disks. As 
 the contents of the alimentary canal or tissue fluids of the host upon 
 which the verminous parasite is nourished need scarcely any digestion, 
 the digestive organs become simplified or may be quite lost, the absorb- 
 tion of nutriment in the latter case taking place entirely through the 
 body integument, as in some of the worms which infest the intestines of 
 man and other animals. The degree of decadence will depend upon the 
 degree of dependence upon the host. In this latter respect the parasitism 
 may be optional, as in the case of the mosquito, which may live upon the 
 juices of plants but prefers a meal of warm blood, or it may be obligate, 
 depending upon another for its means of subsistence, though such 
 obligate parasites as the biting flies, fleas, and bedbugs may also live 
 free and only occasionly visit their hosts, a form of parasitism which 
 may be accompanied by little modification of the adaptability to a free 
 life'. 
 
 In the event of the parasite becoming progressively degraded into one 
 which not only seeks its host for food, but has become dependent upon 
 it for both its nutrition and place of abode, all of the above mentioned 
 phenomena of adaptation become more conspicuous. There is furnished 
 a very good example of such a transformation in the sheep tick (Melo- 
 phagiis ovinus), not a true tick, however, but a fly which, originally an 
 occasional visitor, has, like the louse, taken permanent abode upon its 
 host. No longer taking the aerial flight of its discarded free life, this 
 fly has become wingless, and, furthermore, is enabled to pass its entire 
 life cycle upon the body of the host animal by a remarkable method of 
 reproduction involving the retention of the eggs in the oviducts until 
 development has passed through the larval stage. It is not until ready to 
 pass into the stage of the pupa that the larva? are extruded, the pupal 
 case then being attached to the individual wool fibers. From this case 
 the young insect, on becoming sufficiently developed, makes its escape 
 and proceeds to feed and grow, thus rounding out a complete parasitic 
 cycle. 
 
 While the easy life of the parasite tends to degeneration, the perpetua- 
 tion of the species becomes more precarious, and the organs of reproduc- 
 tion undergo a marked development. If a host animal dies most of its 
 parasites, especially those existing in the interior of its body, die with 
 it, and, were it not that the eggs find lodgment in a new host, the parasitic 
 species would in a short time become extinct. The transmission of but 
 few of these eggs is successfully accomplished, and in compensation they 
 must be produced in enormous numbers, well protected from the many 
 elements of destruction which they encounter. The mode of reproduc- 
 tion is one of the principal factors determining the conditions of par- 
 asitism, and, while the above modifications pertain more to those 
 
INTRODUCTION 5 
 
 dwelling continuously upon or within the bodies of their hosts, we have 
 in the ffistridse, among the dipterous insects, a cycle involving internal 
 parasitism duruig the larval stage, a familiar example being the common 
 horse botfly (Gastrophilus intestinalis) , the development of which is 
 given on page 54. It is plain that a very small percentage of the eggs 
 deposited by this fly can reach the horse's mouth, and that, having got 
 thus far, many of the larvae must be destroyed or pass entirely through 
 the intestinal tract without having succeeded in becoming fixed to the 
 mucous membrane. For this there seems to be compensation in the 
 large number of eggs deposited by the persistent female. 
 
 While in some cases the complete life cycle of a parasite requires but 
 one host, often, for reasons stated in the foregoing, two successive and 
 generally specifically different hosts are required. A rather compli- 
 cated example of the latter case is the life history of the common liver 
 fluke (Fasciola hepatica), one of the flat worms infesting in its adult 
 state the livers of Herbivora. It will be noted in referring to the cycle of 
 this parasite, given in detail elsewhere (page 160), that it is a very 
 hazardous one, and that its completion must depend upon the co- 
 operation of numerous favorable conditions. The eggs, of which each 
 individual fluke is capable of producing in the neighborhood of one 
 hundred thousand, must reach the exterior amid surroundings favorable 
 to their hatching. If hatched, the larva must escape its many aquatic 
 enemies and within a few hours find a suitable snail host. Providing the 
 snail is not eaten by a duck, or does not otherwise perish during this 
 phase of the cycle, it issues from its host as the free-swimming cercaria, 
 when it is again liable to fall prey to various small aquatic animals. 
 Escaping this and })ecoming encysted, the chance of any herbivorous 
 animal coming along and swallowing it is very small. The relation of 
 the enormous number of eggs, and the number of individuals which one 
 egg may produce, to the survival of the species amid conditions fraught 
 with such dangers seems quite evident. 
 
 In general it may be said as to the propagation of parasites that their 
 prodigious fecundit}^ and the great vital resistance with which most of 
 them are endowed enables species to survive and perpetuate their kind 
 amid varied destroying influences which otherwise would bring about 
 their extermination. The tapeworms inhabiting the intestines of man 
 and other animals, afford another example of extreme parasitism accom- 
 panied by this remarkable development of the reproductive function. 
 Here is a creature so altered to its degenerate existence that it has be- 
 come devoid of mouth and intestine, the body consisting of a scolex, 
 usually referred to as the head, from which are give off segments which 
 remain united until there is formed, as in Tcenia saginata of man, a 
 band-shaped colony of from twelve hundred to thirteen hundred or 
 more, passing back from the worm's attachment to a length which may 
 
6 PARASITES OF THE DOMESTIC ANIMALS 
 
 exceed twenty feet. After about the six hundredth, each segment is a 
 mature and sexually complete individual, which later, as it is pushed on 
 by new segments formed at the head, becomes filled with fecundated 
 eggs. By the successive detachment of these "ripe" segments and their 
 passage from the body of the host, it has been estimated that Taenia 
 saginata might throw off in a year as many as one hundred and fifty 
 million eggs, of which but an infinitesimal number, as is quite evident, 
 will reach the bodj' of their proper bovine host for larval development. 
 Again, having been so fortunate, it is improbable that the larvae will, 
 while living, reach the intestines of the human host necessary for their 
 further development into adult worms. 
 
 Here, then, is an animal well showing the degree of degeneration 
 which may be reached in extreme parasitism; there are no organs of 
 locomotion, no organs of special sense, no organs of digestion, no organs 
 of respiration, and none of true circulation. The body consists of a long 
 band of connected segments, each, when mature, bisexually complete 
 and in itself a sort of independent reproductive individual, the entire 
 energy of the organism concentrated upon the function of reproduction 
 that the perpetuation of the species may be insured amid the perils with 
 which this process is beset. 
 
 In many forms permanently parasitic there is an early period of 
 development in which organs of locomotion are distinctly present, but, 
 as the animal matures, these fail to develop or become lost. If it is 
 assumed that this gradual loss of organs, change of structure, and protec- 
 tive transmission of the embryo to an intermediate host is due to the 
 parasitic life, it seems reasonable to conclude that all of the parasitic 
 groups have been derived from free-living forms, and that, as parasitism 
 became a more fixed habit, such structural changes were in the course of 
 time brought about as would make this mode of life obhgatory. A re- 
 view of the observed facts, then, in their biologic relationship, leads to 
 the conclusion that symbiosis, of which parasitism is a form, has its 
 causative basis in the struggle for existence, the symbiotic association in 
 more or less measure mitigating the hazards to one or both symbionts. 
 It further follows that, though some forms have undergone an extreme 
 modification, through related contemporary free-living types, their true 
 systematic position may be established. 
 
CHAPTER II 
 
 FORMS OF PARASITIS:^I AND INFLUENCE UPON THE HOST 
 
 Forms of Parasitism 
 
 The student of parasitology will be greatly aided by an orderly and 
 progressive pursuit of the subject, an elementary' requisite to which is a 
 broad conception of what is implied b}' the various terms used in the 
 chapters which are to follow. Those below are not given with the recom- 
 mendation that the}' be memorized as to the exact wording set forth in 
 their definitions; more essential is such an understanding that examples 
 can readily be picked out, a typical illustration always being in mind for 
 application to the tenn at hand. With such a conception the student 
 should be able to fonnulate his own definitions, and this will be of more 
 advantage to him than accepting those set forth according to the con- 
 ceptions of another. 
 
 Though some of the following tenns have been treated of in foregoing 
 introductory remarks, the}^ are here included for more concise definition 
 and to make the list inclusive. 
 
 Symbiosis is the more or less pennanent living together of two plants, 
 two animals, or an animal and a plant, the union being in a measure 
 beneficial to both, or to one with or without hami to the other. 
 
 Symbiont, — one of two organisms partaking of symbiotic relationship. 
 
 Mutualism is a fonn of sjmibiosis in which both sjTubionts are in 
 more or less measure benefited by the union. 
 
 Commensalism is that form of s^inbiosis in which but one sjinbiont 
 is benefited, while its co-s\anbiont is neither benefited nor harmed by 
 the union. 
 
 Helotism is a form of s}^nbiosis in which one organism appears to 
 enslave the other, enforcing it to labor in its behalf. The term is applied 
 to such association in certain insects. 
 
 Parasitism is that form of sjanbiosis in which one symbiont, for pur- 
 poses of procuring food, or food and shelter, visits briefly, or takes up 
 its abode temporarily or pennanently, upon or within the bodj' of its 
 co-s>inbiont which is harmed by the union. The sAinbiont receiving 
 the advantage is known as the parasite, to which the one injured is the 
 host. 
 
 Phytoparasites are parasites which belong with the vegetable 
 kmgdom. 
 
8 PARASITES OF THE DOMESTIC ANIMALS 
 
 Zooparasites are parasites which belong with the animal kingdom. 
 
 Optional Occasional Parasites are those which only fleetingly visit 
 their hosts to obtain nourishment, but are not dependent upon them for 
 either nourishment or shelter. Example, mosquitoes. 
 
 Obligate Occasional Parasites are those which do not permanently 
 live upon their hosts, but are dependent upon them for nourishment and 
 to some extent for shelter. Examples, fleas, bedbugs. 
 
 Determinate Transitory Parasites are those in which the parasitism 
 is hmited to a definite phase or phases in their Hfe history, during which 
 time the parasitism is ol:)ligate and continuous. Examples, botflies, 
 ticks. 
 
 Permanent Parasites are those in which the parasitism extends from 
 the hatching of the egg to the stage of reJDroduction in the adult. Exam- 
 ples, lice, many entozoa. 
 
 Fixed Parasites are those which cannot pass spontaneouslj^ from 
 one host to another. Examples, larvae of botflies, Linguatula, helmin- 
 thes. 
 
 Erratic Parasites are those which in their adult state may pass 
 readily from one host to another of the same or different and widely 
 separated species. Examples, mosquitoes, biting flies, ticks, leeches. 
 
 Determinate Erratic Parasites are those which may pass from one 
 host to another of the same species, or a species closely allied to the one 
 abandoned. Examples, lice, psoric Acarina. 
 
 Monoxenous Parasites are (a) those the eggs of which are expelled 
 by the host, the embryos, while still within the eggs, passing to a new 
 host where hatching and development to the adult occurs. Example, 
 Ascaris. 
 
 (b) The eggs having been hatched, the larvae are noiu'ished in suitable 
 conditions of moisture and temperature, but cannot imdergo further 
 development until they have reached the body of their host. Example, 
 Hemonchus contortus. 
 
 Heteroxenous Parasites are (a) those which pass to their definitive 
 host by an intermediate or transitory host, in which they cannot attain 
 their complete development; consequently, a reciprocal transmission 
 between these hosts is essential to the development and propagation of 
 the parasite. Examples, tapeworms, Plasmodium of malaria. 
 
 (b) The eggs of the parasite are hatched in the Ijody of the host, the 
 embryos invading the tissues of the same individual host and not at^ 
 taining the adult state until they have reached a second host. Example, 
 Trich ineUa sp ira lis. 
 
 Transmigration is a term applied to the passing of heteroxenous 
 parasites from one host to another. 
 
 Incidental or Stray Parasites are those which under natural condi- 
 tions are occasionally found in unusual hosts. Examples, Gigantorhyn- 
 
FORMS OF PARASITISM 9 
 
 chus hirudinaceiis (specific in pig, incidental in man) ; Fasciola hepatica 
 (specific in Her])ivora, incidental in man). 
 
 Ectoparasites (Epizoa) are those which are parasitic to the surface 
 of the body, whether burrowing into the integument, living upon it, or 
 only occasional visitors. Examples, scab mites, ticks, and other Acarina, 
 lice, flies. All of the arthropodal parasites with scarcely an exception. 
 
 Endoparasites (Entozoa) are parasites which enter the body of their 
 host, inhabiting its alimentary canal, blood, and other tissues. Exam- 
 ples, Linguatula, larvae of the botflies, and almost all of the helminths. 
 
 Helminthes is a term under which are grouped all of the worms 
 generally jiarasitic, with the exception of a small number in which the 
 body is annulated. The group is not a natural zoological one and is 
 used mostly in parasitology. 
 
 In terms used to designate parasitic diseases it is customary to apply 
 the name of the genus, or other group name to which the parasite be- 
 longs, as the root, to which is added the suffix asis or osis. As for ex- 
 ample : 
 
 Pediculosis, the condition produced l)y the presence of lice upon 
 the skin; Acariasis, the condition produced by the presence upon the 
 skin of mites and other Acarina; Filariasis, the condition produced by 
 Filaria. And thus we have Ascariasis from Ascaris, Oxyuriasis from 
 Oxyuris, Strongylosis from Strongylidae, Trichinosis from Trichinella, 
 Taeniasis from Tseniidae, Fascioliasis from Fasciola, Helminthiasis from 
 Helminthes, and Trypanosomiasis from Trypanosoma. 
 
 In view of the many factors to be considered, the formulation of 
 exact and limiting interpretations of terms bearing upon kinds of par- 
 asitism is scarceh^ possible. It cannot be claimed for the above series, 
 therefore, that it is entirely satisfactory as stated and defined. For our 
 conceptions we must rely upon the ])ehavior of the typical rather than 
 the isolated or synthetic, and be content to regard anj^ grouping based 
 upon modes of parasitism as more convenient than exact. It is difficult 
 to circumscribe parasitism ; while we speak of the parasitic mode of life 
 as a form of symbiosis, it may well be questioned whether such insects as 
 mosquitoes and biting flies bear a true sjanbiotic relationship to their 
 hosts; their fleeting visits certainly do not constitute the living together 
 as usually implied by the term. Again, we may not be able to draw a 
 distinct fine between certain predaceous and certain parasitic forms. 
 From the more general viewpoint, however, it may be repeated that all 
 predaceous animals voluntarily, by the exercise of their powers of stealth 
 and cunning, seize upon and aim to destroy their prey at once, feeding 
 upon the body. There are parasites which use a degree of stealth in 
 approaching their victims, as certain parasitic Diptera, though the 
 invasion of the body of its victim by the parasite is more often passive 
 than voluntaiy. While the parasite may appropriate a share of the 
 
10 PARASITES OF THE DOMESTIC ANIMALS 
 
 nutriment of its host or feed upon its host's tissues, it is detrimental to 
 the parasite's welfare to destroy its host. To destroy the body of the 
 animal harboring it would mean the sacrifice of the parasite's means of 
 subsistence as well as in most cases its shelter. When the host animal 
 dies its internal parasites die with it, and, if it were not for the previously 
 occurring transmission of their offspring to new hosts, the species would 
 rapidly perish. Serious disturbance or death of the host due to its 
 parasites is usually brought about by their presence in large numbers, 
 in which case there is the operation of numerous pathogenic factors. 
 A fatal termination may follow rapidly, but more often there are afebrile 
 morbid phenomena running a prolonged course. In no case is the victim 
 at once destroyed and wholly or in part devoured. 
 
 The parasite is always smaller and weaker than its host, and in many 
 cases its influence upon the latter is not observable. It may be said in 
 general that the degree of injury will depend upon the following prin- 
 cipal factors: 
 
 Influence Upon the Host 
 
 1. The Number of Parasites Present. — ^A tapeworm or one or two 
 ascarids in the intestines may not produce a noticeable effect upon the 
 host. If these parasites are numerous there may be serious disturbances 
 in the host resulting from the deprivation of nutriment which has been 
 appropriated by the infesting worms, from the toxins which they elab- 
 orate, or a more acute effect may be brought about through obstruction 
 of the bowel by large numbers of the parasites in mass. 
 * 2. Their Location. — An encysted larva of the beef or pork tapeworm 
 in its usual location will do no observable harm to its host, but if it 
 should lodge in the eye or central nervous system it might give rise to 
 serious disorders. As a rule, intestinal parasites are less harmful than 
 those which invade the blood or respiratory tract, while of the external 
 parasites, those which burrow into the integument are more injurious 
 than those living upon the surface. 
 
 3. The Nature of their Food. — Any parasite which feeds upon the 
 tissues of its host is more harmful than one which merely appropriates 
 a share of the latter's ingested nutriment. The blood-sucking worms, 
 when present in considerable numbers, bring about serious depletive 
 disturbances, while such worms as the adult ascarids, nourishing mainly 
 upon the residue of food materials, are, in general, less harmful. Sucking 
 lice, armed with piercing mouth parts, are more disturbing to the animal 
 harboring them than the biting lice which feed upon cutaneous debris 
 and the products of their irritation. 
 
 4. Their Movements. — Serious pathologic conditions may be 
 brought about by the migrations of parasites or their change from a 
 usual to an unusual position. Muscular trichinosis, the collective 
 
INFLUENCE UPON THE HOST 11 
 
 effect of the movement of myriads of embryos of Trichinella spiralis, is a 
 typical instance. An otherwise relatively harmless parasite may work 
 its way into a duct, or, findmg lodgment in an unusual organ, set up 
 inflannnatory changes and abscess formation. Again, by verminous 
 wandering, fistulous connnunications may be established between 
 contiguous organs normally possessing no direct connection. 
 
 5. Age of Host. — Young animals are predisposed to endoparasitic 
 invasion. To forms which penetrate or are more or less migratory, the 
 more tender tissues of the young offer less resistance than in older 
 animals. Verminous broiichitis is a form of strongylosis observed almost 
 exclusively in animals which are immature. The reduced vitalitj- of 
 old age invites the invasion of both external and internal parasites; 
 there is not only a lessened ability to defend from attack, but reduced 
 activities and secretions of the intestines, skin, and other organs de- 
 crease the capability of eliminating either ecto- or entozoa. 
 
 Such external parasites as mosquitoes, flies, ticks, and bedbugs are of 
 greatest pathologic importance as disseminators of infectious diseases, 
 acting either as direct carriers or as intermediate or definitive hosts of 
 the infecting organism. Malaria, Texas fever, and forms of trypan- 
 osomiasis are among diseases which are known to be spread only b}' this 
 means, while the possibilities as carriers of typhoid and other malignant 
 infections engendered by the habits of the connnon house fly are well 
 known. 
 
 That Helminthes elaborate materials toxic to their host has been 
 demonstrated in experiments mth the isolated poisons. It is obvious 
 that, in cases of heavy infestation especially, this toxic effect must be 
 considerably contributed to by the products of decomposition of dead 
 worms. 
 
 Etiology. — So varied are the conditions that surround the propaga- 
 tion and existence of parasites that the consideration of the causes of 
 parasitic diseases is best embodied in chapters devoted to their particular 
 occurrence. However, certain circumstances favoring parasitism may 
 be here briefl}' considered. 
 
 Crowded and miclean housing favors the propagation and spread of 
 parasites of both man and domestic animals. For this reason lice and 
 scab mites find their most favorable season in the winter months, when 
 their transmission from animal to animal is facilitated and the reduced 
 activities of the skin offer less resistance to their invasion. Pediculosis 
 and the scab acariases are seldom seen, however, in stables that are 
 well kept, or among animals where due attention is paid to cleanliness of 
 the skin. The sunnner, on the other hand, is the season of attack by 
 adult parasitic Diptera, and it is during the months at pasture that 
 ticks most rapidly propagate and crawl upon their hosts. 
 
 In helminthiasis the influences of environment as an etiologic factor 
 
12 PARASITES OF THE DOMESTIC ANIMALS 
 
 are more subordinate to the mode of development of the infecting 
 species. Sheep grazing upon low, marshy land and in the vicinity of 
 ponds are more exposed to infestation with flukes, because there are 
 present conditions essential to the molluscan intermediate host in which 
 the fluke at the stage of the miracidium must find lodgment. Infestation 
 of the pig or the ox with the larvae of the tapeworms of man is most 
 likely to occur where untreated human excrement is used as a fertilizer, 
 or where their food may otherwise be directly or indirectly contaminated 
 with such material, while invasion of the human host with the adult 
 worm only occurs after ingestion of the tissues of the larval host. The 
 majority of ova of worms expelled by the host fail to find a new host, or 
 meet with unfavorable conditions and are lost. Some, as those of 
 ascarids, are very resistant and may find their proper host after months 
 of exposure to destructive influences. Migration is facilitated to some 
 extent where hatching takes place with the laying of the egg, as in the 
 strongyles of the respiratory tract and in Trichinella. 
 
 While much remains to be determined as to the life histories of many 
 of the internal parasites, clinical experience indicates that low and wet 
 pasturage, with access to stagnant collections of water, is a strong 
 etiologic factor in helminthiasis, either as harboring possible aquatic 
 intermediate hosts of the worms, or as a vehicle which, directly or by 
 drainage, spreads infestation by dissemination of their germs. 
 
CHAPTER III 
 
 PHYLUM I. ARTHROPODA 
 
 While there are advantages in arranging a description of parasites 
 according to their location, as those of the skin, those of the intestines, 
 those of the liver, those of the circulation, etc., the fact that so many 
 in their life histories pass certain stages in different organs and different 
 species of hosts makes such an arrangement somewhat confused. It 
 seems better, therefore, to treat of the natural history of each parasite 
 in the parasite's order, essentially including such anatomical and zoolog- 
 ical migrations as may be involved, while at the same time considering 
 its pathogenic influences in these varying locations. 
 
 Aside from the phytoparasites, which are not included in this work, 
 the parasites infesting man and domestic animals are distrilnited among 
 four grand divisions or phyla of the animal kingdom, which, in the order 
 of their zoological grade, are Protozoa, Platyhelminthes, Coelhelminthes, 
 and Arthropoda. The last named group contains most all of the external 
 parasites and is the first to be considered in the pages to follow. 
 
 As a foundation for the scientific control of parasitism and for the 
 recognition of adaptations to its various forms, at least an elementary 
 knowledge of the structure and habits peculiar to the phylum and its 
 subdivisions to which the parasite belongs is of essential importance. 
 Only the more prominent structural features upon which the separation 
 of the different groups and their subgroups is based will be given here. 
 For more detailed study the student is referred to an advanced text-l:)Ook 
 in zoology. 
 
 The phylum Arthropoda includes such animals as the craj^fish, crabs, 
 lobsters, spiders, centipedes, and insects. The body is provided with a 
 hard or leathery external chitinous skeleton divided into a number of 
 segments demarcated externally by constrictions, each segment in the 
 adult, or a certain number of the segments, bearing jointed appendages 
 (Fig. 1). There are usually two or more body regions distinguished by a 
 special modification of the constituant segments. In order that move- 
 ments may take place between the segments of both the body proper 
 and of the appendages, the cuticle at these points is thin and delicate 
 (Fig. 9), forming joints which are protected by an overlapping of the 
 heavier chitinous armor. 
 
 All arthropods periodically molt, the process consisting of the break- 
 ing and casting off of the chitinous cuticle after it has loosened from the 
 
U PARASITES OF THE DOMESTIC ANIMALS 
 
 underlying tissue and a new cuticle has been formed. While the cuticle 
 is at first thin and soft, later it becomes hard and unyielding, therefore 
 the moltings are necessar}- for the accommodation of growth and occur 
 periodically as long as this growth continues. Chitin, to which the 
 firmness of the cuticular exoskeleton is due, is an organic substance in 
 which lime salts may be deposited, as occurs in the Crustacea. The 
 skin is never ciliated, nor do ciliated cells occur in any other organs of 
 the body. 
 
 The musculature (Fig. 9) consists of a large number of separate 
 muscles passing from one segment to another and attached at their 
 extremities to the mner side of the skin, their contraction bringing about 
 movements of the segments of the body and appendages one upon the 
 other. They may be attached by so-called tendons, which consist of 
 invaginations of the cuticle surrounded by a corresponding invagination 
 of the epidermis. The muscle fibers are striated and multinuclear. 
 
 The digestive tract (Fig. 2) passes directly, or with little flexion, 
 through the bodj^, the mouth being at the anterior end and usually 
 ventral, the anus posterior. Accessory organs, as salivary glands and 
 liver, may or may not be present. 
 
 Of the circulatory system (Figs. 2 and 3) the most constant portion is 
 the heart, which is usually tubular and located dorsally. On each side of 
 the organ are openings provided with valves through which the blood 
 passes to be propelled forward. From the large arteries the blood may 
 pass directly into blood sinuses, or it may course through capillaries and 
 veins, though the vascular system is never entirely closed. The blood is 
 usualty a colorless fluid with colorless amoeboid corpuscles. 
 
 In aquatic forms (Crustacea) respiration is b}' gills, while in the air- 
 breathers it may be by tracheae (Figs. 5 and 6), consisting of tubular 
 ramifications from without to within the body, or by peculiar infolding 
 modifications of the integument functioning as lungs. In some of the 
 lower forms respiratory organs are entirely absent, the function in such 
 cases being diffused over the entire body surface. 
 
 In various spaces within the bodies of Arthropoda are frequently 
 found fat bodies, a connective tissue the cells of which, richly laden with 
 fat, serve as a store of nourishment. The fact that products of tissue 
 metabolism, such as uric acid, have been found m the fat body, leads to 
 the conclusion that it also acts as a place of storage for substances of 
 excretion before their elimination by the excretory organs, which latter 
 greatly vary in the different groups. In insects and arachnids these 
 organs are represented by the Malpighian tubes, long glandular canals 
 which open into the posterior portion of the digestive tract. 
 
 The nervous system consists typically of a ventral chain of ganglia 
 connected by a double longitudinal nerve cord. In well-developed seg- 
 ments the ganglia are large, and a pair of ganglia to each segment might 
 
ARTHROPODA 15 
 
 be expected, as in the annelid worms. In the Arthropoda, however, 
 there are differences due to fusion of the segments, in which case there 
 is also fusion of their ganglia. Such fusion is usually accompanied by 
 more or less shortening of the body, an example of which is afforded b}^ 
 the spiders and crabs where the whole ventral chain unites in a single 
 ganglionic mass. From the most anterior of the ventral ganglia there 
 spring two nerve cords which pass on either side of the esophagus to 
 unite above it with the paired cerebral ganglion or brain, Ijong in the 
 head. This ganglion remains distinct, its dorsal position preventing its 
 fusion with ganglia of the ventral chain. 
 
 Of the sense organs the most highly developed are the eyes, which are 
 compound (Fig. 6), or appear as simple ocelli. In many arthropods 
 there are both of these forms, while others are provided only with ocelli, 
 and in some arthropods eyes are absent. In the compound eyes the 
 cuticle covering them is divided into hexagonal facets, the number of 
 which varies with different groups from a dozen to two thousand or 
 more, each of these areas corresponding to a small chitinous lens. The 
 compound eyes are two in number, while the number of oceUi varies. 
 The latter are very small and have their highest development in the 
 spiders. 
 
 With rare exceptions the sexes are separate, and reproduction is 
 generall.y by fertilized eggs, though parthenogenesis occurs, in some 
 cases having a certain relationship to the life history. Usually the sexes 
 can be readily distinguished by the difference in size and by various 
 modifications of the appendages. 
 
 Of the subgroups of the phylum Arthropoda only those containing 
 parasitic species of medical interest will be considered in this work. 
 These are included in the two classes Insecta and Arachnida, which, 
 with scarceh' an exception, contain all of the external parasites. It is 
 not correct, however, to say that the arthropodal parasites are exclusively 
 external, as certain insects and arachnids pass a phase of their develop- 
 ment within the bodies of their hosts. 
 
 Class I. Insecta 
 
 Arthropoda (p. 13). — In number of species the insects constitute 
 the largest of all animal groups. The body is essentially segmented, and 
 is di\'ided into three regions, — head, thorax, and abdomen, which are 
 distinctly marked off from each other (Fig. 1). 
 
 The head is usuall}- freely movable at its jmiction with the thorax, 
 and typically bears on each side a compoimd eye (Figs. 1 and 7), be- 
 tween which there may be a varying number of simple ocelli. 
 
 Arising from the head are a pair of antennae which consist of seg- 
 ments varying in size, shape, and number according to species. 
 
16 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 The mouth parts (Fig. 4) undergo great modification, though all may 
 be referred to a common type. This is well presented in its primitive 
 
 condition by the grasshopper, 
 in which we have the labrum, 
 or upper lip, represented b}' a 
 broad unpaired plate situated 
 in front of the mouth. Under 
 the labrum is a parr of strong- 
 jaws, the mandibles, each con- 
 sisting of a single unsegmented 
 piece with a cutting innei' edge, 
 the two having a lateral move- 
 ment. Following the mandibles 
 is the first pair of maxillae which 
 are prehensile and gustatory in 
 function. These have a num- 
 ber of joints and bear curved 
 and segmented palpi. The sec- 
 ond pair of maxillae are fused 
 to form a single plate, — the la- 
 bium, which is accessory in func- 
 tion to the first pair of max- 
 illae, and, like the latter, bear a 
 pair of segmented palpi. The 
 labium forms the posterior and 
 the labrum the anterior bound- 
 ary of the mouth. 
 
 The thorax (Fig. 1) has three 
 a middle, — the. mesothorax, 
 
 Fig. 1. — Diagram of an Insect, with Head and 
 Thoracic Segments Disarticulated: a, head, 
 bearing compound eyes, simple ocelli, and 
 antennae; b, prothorax; c, mesothorax; d, meta- 
 thorax; e, abdomen; f, ovipositor. The pro-, 
 meso-, and metathorax each bear a pair of legs; 
 the meso- and metathorax each a pair of wings. 
 1, Coxa; 2, trochanter; 3, femur; 4, tibia; .5, tar- 
 sus, terminating in a claw (after Orton, by 
 Dodge; Copyright, 1894, by Harper & Brothers). 
 
 segments, an anterior, — the prothorax 
 
 Fig. 2. — Diagram of the Principal Internal Anatomical Parts of an 
 Insect: m, mouth; or, crop; st, stomach; i, lower portion of intestine; 
 a, anus; h, heart; s, salivary glands; c, cerebral ganglion; n, ventral 
 ganglion; Mp, Malpighian tulDules; o, ovaries; g, genital aperature (after 
 Boas, by Kirkaldy & Pollard). 
 
 and a posterior, — the metathorax. 
 somewhat fused. 
 
 The last two of these are usuallv 
 
ARTHROPODA 
 
 17 
 
 There are three pairs of legs, each thoracic segment l^earing one pair 
 (Fig. 1). The leg is divided into five articulated parts, — coxa, trochanter, 
 femur, tibia, and tarsus. The attachment to 
 the bod}' is by the short coxa, to which is joined 4, 
 the trochanter which is also short. Following •'^Cr^<f7^'~>r~>''~^ 
 the trochanter are two long segments, — the fe- v ^ 
 
 mur and tibia, the former considerably thicker fig. 3.— Diagram of In- 
 than the latter and contaming the muscles. The sect's Heart: c, constriction 
 
 tarsus, or foot, follows the tibia, and consists of between two chambers; V, 
 ', „ , , , , • valves (after Boas, bj' Kirk- 
 
 a number ot short segments, the last bearmg aidy & Pollard), 
 hook-like structures, or claws. 
 
 Usualh' there are two pairs of wiiigs arising dorsally from the meso- 
 
 FiG. 4. — Mouth-parts of Locust, a biting insect: Labruni, or upper-lip, 
 above, on each side of which are the mandibles, or upper pair of jaws. 
 Labium, or under lip, with labial palpi below. Ma.xillae, or lower pair of 
 jaws, with maxillary palpi, to right and left (from photomicrograph of 
 mounted specimen, by Hoedt). 
 
 and metathorax (Fig. 1). They consist, when fully developed, of two 
 closely apposed chitinous outgrowths, between which are extensions of 
 
18 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 the blood sinuses and tracheae. Sometmies the anterior, sometimes the 
 posterior pair is the larger, and both may be flexible and adapted for 
 flight. In some insects (beetles) the anterior pair is modified to form 
 wing-shields, or elytra, which are hard, but 
 slightly flexible, structures serving to cover 
 and protect the posterior wings during rest. 
 Some insects possess but one pair of wings 
 (dipterous), while in others wings are entirely 
 absent (apterous). 
 
 The abdomen is segmented, the number of 
 segments varying with different groups. Each 
 segment consists of two cuticular plates (Fig. 6), 
 the dorsal tergite and the ventral sternite, 
 which are united laterally by a softer mem- 
 brane, the pleurite. There are no abdominal 
 limbs or limb-like appendages. 
 
 Respiration is by tracheae (Fig. 5), a system 
 of tubes containing air. These communicate 
 with the outside by 
 the spiracles (Fig. 
 6), small s>anmet- 
 r i c a 1 1 y disposed 
 openings located 
 laterally, one pair 
 on the meso- and 
 one pair on the 
 metathorax and a 
 pair on each of the 
 abdominal segments 
 except the most posterior. Just inside of the spiracles the tracheae are 
 usually united by longitudinal trunks from which are given off fine 
 branches which ramify and anastomose within the body. Respiration 
 is effected by abdominal movements of contraction and expansion. 
 
 Insects are mostly oviparous. In some the developed embryo is 
 released from the egg while still within the body of the parent, or this 
 may occur just as the egg is extruded. There are also pupiparous forms 
 where the young pass from the body of the female ready to enter the 
 pupal stage in their development. 
 
 In order that the newly hatched larvae may be supplied with nourish- 
 ment, the eggs are generally deposited where suitable food is present. 
 In many insects oviposition occurs by means of an ovipositor, a tube- 
 like organ which is developed from the posterior abdominal segments 
 and which may project free from the body or may be retracted into it. 
 In the Hjmienoptera the ovipositor may be modified to serve as a sting, 
 
 Fig. 5. — Diagram show- 
 ing the chief trunks of the 
 tracheal system of an in- 
 sect (after Boas, by Kirk- 
 aldy & Pollard). 
 
 Fig . 6. — Abdomen of Lo- 
 cust, s howing Spiracles 1, 2,13, 
 4, 5, 6, 7 and 8, one on each side 
 of each of the abdominal seg- 
 ments; A, auditory sac (drawn 
 in part from Packard's Zool- 
 ogy). 
 
ARTHROPODA 
 
 19 
 
 Fig. 7. — Head of 
 the bee, showing 
 compound eyes, the 
 three ocelH, and the 
 antennae. — Magni- 
 fied (after Orton, by 
 Dodge; Copyright, 
 1894, by Harper & 
 Brothers) . 
 
 a weapon of defense provided with poison glands. From its nature the 
 sting is essentially onh' possessed by the females. 
 
 Some insects on leaving the egg develop directly to the adult stage, 
 the larva in most cases differing from the adult prin- 
 cipalh' in the absence of wings. In such cases there 
 is a slight change of form with successive molts, 
 the wings being ultimateh' acquired. Here the meta- 
 morphic process is not thorough, and is therefore 
 referred to as mcomplete metamorphosis. The ma- 
 jorit}^ of insects when hatched from the egg bear 
 no resemblance to the adult, and there is no observ- 
 able gradual approach to this form. The larva is 
 characteristically worm-like and an active and vora- 
 cious feeder, a number of molts occurring with the 
 increase in size during this stage. There then 
 intervenes between the larval and adult stages a 
 period of pupation, during which the animal is quies- 
 cent and a series of changes 
 
 occur in the body. At the 
 
 conclusion of these changes the pupal case 
 
 splits and the imago emerges, which, with 
 
 the unfolding of the ap- 
 pendages and hardening 
 
 of the cuticle, has in all 
 
 essentials developed into 
 
 the complete sexual 
 
 adult. In this form 
 
 of development the 
 
 changes are distinct, and 
 
 the process is referred 
 
 to as complete meta- 
 morphosis (Fig. 8). 
 The duration of life 
 
 in insects, including the 
 
 stages of the egg, larva, 
 
 pupa, and adult, usually 
 
 does not extend bej^ond 
 
 a year. With quite a 
 
 number it is much 
 
 shorter than this, while 
 
 with others it maj' be a 
 
 matter of several years, 
 
 an extreme example of 
 
 larval longevity being 
 
 Fig. 9. — Diagram of termi- 
 nal segments of arthropod leg, 
 with muscles, a, articulation; 
 f, flexors; e, extensors Cafter 
 Boas, by Kirkaldy & Pollard). 
 
 Fig. 8. — Metamor- 
 phosis of the House Fly, 
 showing oval, larval, 
 pupal, and adult stages. 
 On the right is an en- 
 largement of the foot; 
 on the left, the foot pad, 
 showing sticky, glandu- 
 lar hairs; on upper left, 
 a tsetse fly (from photo- 
 graph of drawing by 
 author). 
 
20 PARASITES OF THE DOMESTIC ANIMALS 
 
 afforded by the seventeen-year cicada. Most of the insect Hfe is occupied 
 bj' the larval stage, during which the greatest growth takes place. With 
 a few exceptions, as honey bees and ants, the period of the adult is short, 
 in some cases a few daj^s or even hours. The life of the adult is de- 
 voted to the activities concerned in reproduction, and the insect usualh'' 
 dies when this is accomplished. 
 
 Of the class Insecta the five following orders contain parasites of 
 medical importance: 
 
 Order I. Diptera — Flies, gnats, and mosquitoes. 
 
 Order II. Siphonaptera — Fleas. 
 
 Order III. Siphunculata — Sucking lice. 
 
 Order IV. Mallophaga — Biting lice. 
 
 Order V. Hemiptera — Bedbugs and allies. ^Vv^^s-a.^ 
 
 Classification of Parasites of the Class Insecta 
 
 Phylum I. Arthropoda. P. 13. 
 Class A. Insecta. P. 15. 
 Order 1. Diptera. P. 23. 
 
 Family (a) Culicidse. Mosquitoes. P. 24. 
 Genus and Species: 
 
 Culex pungens. Pp. 25, 26. 
 Anopheles quadrimaculatus. P. 26. 
 A. pmictipennis. P. 28. 
 Ades calopus. P. 29. 
 Family (b) Simuliida?. Buffalo gnats. P. 31. 
 Genus and Species: 
 
 Simulium pecuarum. Animals attacked, equines and cattle. 
 P. 32. 
 Family (c) Tabanidse. Horseflies, gadflies. Animals attacked, 
 equines, cattle. P. 35. 
 Genus and Species: 
 
 Tabanus atratus. P. 35. 
 T. lineola. P. 36. 
 Family (d) Muscidse. House fly and allies. P. 37. 
 Genus and Species: 
 
 Musca domestica. Injurious to man and domestic animals 
 
 by irritation and contamination. P. 37. 
 Stomoxvs calcitrans. Animals attacked, equines and cattle. 
 
 P. 39! 
 Lyperosia irritans. Animals attacked, cattle. P. 41. 
 Glossina palpalis. Animals attacked, man, and domestic 
 
 and wild animals. P. 44. 
 G. morsitans. Animals attacked, same. P. 44. 
 G. longipalpis. Animals attacked, same. P. 44. 
 
ARTHROPODA 21 
 
 Chiysomyia macellaria. Larvae attack flesh and mucous 
 
 surfaces of man and lower animals. P. 50. 
 Sarcophaga sarraceniae. Larvae attack fresh meat and 
 
 wounds of animals. P. 52. 
 Calliphora vomitoria. Larvae attack fresh and decomposing 
 meat and wounds. P. 52. 
 Family (e) Hippoboscidae. P. 47. 
 Genus and Species: 
 
 Melophagus ovinus. Host, sheep. P. 47. 
 Family (f) CEstrida?. Botflies. P. 53. 
 Genus and Species: 
 
 Gastrophilus intestinalis. Host, equines. P. 53. 
 G. hemorrhoidalis. Host, equines. P. 57. 
 G. nasahs. Host, equines. P. 57. 
 Hypoderma lineata. Host, cattle. P. 57. 
 H. bovis. Host, cattle. P. 58. 
 CEstrus ovis. Host, sheep. P. 62. 
 Order 2. Siphonaptera. P. 65. 
 
 Family (a) Pulicida?. Fleas. P. 65. 
 Genus and Species: 
 
 Ctenocephalus canis. Host, dog. P. 65. 
 C. felis. Host, cat. P. 65. 
 Pulex irritans. Host, man. P. 65. 
 Order 3. Siphunculata. Sucking lice. P. 70. 
 Family (a) Pediculida^. P. 70. 
 Genus and Species: 
 
 Haematopinus asini. Host, equines. P. 73. 
 H. eurysternus. Host, cattle. P. 74. 
 Linognathus vituli. Host, cattle. P. 74. 
 L. pedalis. Host, sheep. P. 76. 
 L. stenopsis. Host, goat. P. 77. 
 Ha?matopinus suis. Host, hog. P. 77. 
 Linognathus piliferus. Host, dog. P. 78. 
 Pediculus humanus. Host, man. P. 79. 
 P. corporis. Host, man. P. 79. 
 Phthirius pubis. Host, man. P. 79. 
 Order 4. Mallophaga. Biting lice. P. 7L 
 Family (a) Philopterida?. P. 71. 
 Genus and Species: 
 
 Trichodectes equi. Host, equines. P. 73. 
 
 T. pilosus. Host, equines. P. 73. 
 
 T. scalaris. Host, cattle. P. 75. 
 
 T. sphaerocephalus. Host, sheep. P. 76. 
 
 T. chmax. Host, goat. P. 77. 
 
22 PARASITES OF THE DOMESTIC ANIMALS 
 
 T. latus. Host, dog. P. 78. 
 
 T. subrostratus. Host, cat. P. 79. 
 
 Goniocotes gallinae. Host, chicken. P. 82. 
 
 G. gigas. Host, chicken. P. 82. 
 
 Lipeurus caponis. Host, chicken. P. 83. 
 
 L. heterographus. Host, chicken. P. 83. 
 
 Goniodes styhfer. Host, turkey. P. 84. 
 
 Lipeums meleagridis. Host, turkey. P. 84. 
 
 Philopterus icterodes. Hosts, ducks and geese. P. 84. 
 
 Lipeums anatis. Hosts, ducks and geese. P. 84. 
 
 Philopterus C3'gni. Host, swan. P. 86. 
 
 Ornithonomus cygai. Host, swan. P. 86. 
 
 Goniocotes compar. Host, pigeon. P. 86. 
 
 Goniodes damicornis. Host, pigeon. P. 86. 
 
 Lipeurus columbse. Host, pigeon. P. 86. 
 Family (b) Liotheidse. P. 71. 
 Genus and Species: 
 
 Menopum trigonocephalum. Host, chicken. P. 83. 
 
 M. biseriatuni. Host, turkey. P. 83. 
 
 Trinotum luridum. Hosts, ducks and geese. P. 84. 
 
 T. lituratuni. Hosts, ducks and geese. P. 86. 
 Order 5. Hemiptera. P. 89. 
 Family (a) Cimicidse. P. 90. 
 Genus and Species: 
 
 Cimex lectularius. Hosts, man, poultry, etc. P. 90. 
 
CHAPTER IV 
 
 MOSQUITOES AND (iXATS 
 
 Order I. Diptera. — Insecta (p. 15). The dipterous insects have only 
 the anterior pair of wings developed, the posterior pair being repre- 
 sented b}' rudimentary structures called halteres, or balancers, which 
 are supposed to function as organs of balance. In some parasitic forms 
 (sheep '4ick," bat fly) wings are entireh' wanting. 
 
 The head, thorax, and abdomen are sharply defined. The mouth 
 parts are adapted for sucking, the haustellum, or sucking tube, being- 
 formed by the labium and labrum, within which lie the mandibles and 
 maxillae, which may be modified into blade-like structures for piercing. 
 With this structure the insect sucks the juices of plants or penetrates the 
 skin of animals and feeds upon their blood. In the flies the antennae are 
 short, consisting of but three well-developed joints. The three thoracic 
 segments are frequently fused, and the tarsi have five segments. 
 
 Metamorphosis is complete. The larvae are apodal grubs, maggots, 
 or wrigglers, the latter aquatic (mosquitoes). 
 
 Parasitism. — The dipterous group of insects includes a number of 
 species varying in their grade of parasitism from optional occasional to 
 obligate occasional and permanent. They are chiefly of importance 
 from the medical viewpoint as carriers of bacterial and animal parasitic 
 infection, investigations within recent 3'ears well establishing the fact 
 that certain serious and often fatal diseases of man and domestic animals 
 are spread by these insects either as essential hosts or as direct carriers 
 of the infectrtig organism. As essential hosts a part of the development 
 of the pathogenic organism must essentially be undergone in the insect. 
 As direct carriers they may inoculate directly into the blood with con- 
 taminated piercing or biting mouth parts, or the}-- may simply trans- 
 port disease germs upon their bodies and appendages, contaminating 
 wounds, food, or any object upon which they may alight. 
 
 As blood-sucking pests and sources of torment in the habitations of 
 man and in the fields and stables of his live stock, many of these two- 
 winged insects are of veiy considerable economic as well as pathologic 
 importance. In view of all that at the present time can be charged 
 lip against them, the}' are well worthy of the increasing attention they 
 are recei\'ing with a view to their more effectual control. 
 
 Of the families of the order Diptera containing parasitic species, six 
 are here considered, as follows: 
 
24 PARASITES OF THE DOMESTIC ANIMALS 
 
 Family I. Culicidse — Mosquitoes. 
 Family II. Simuliidse — Buffalo gnats. 
 Family III. Tabanidae — Horseflies. 
 Family IV. Muscidae — House fly and allies. 
 Family V. Hippoboscidae — Sheep "tick." 
 Family VI. (Estridae— Botflies. 
 
 Family I. Culicid^; Mosquitoes 
 
 Diptera (p. 23). — The mosquitoes are slender-bodied Diptera with 
 narrow wings which have a distinctive fringe of scale-like hair upon 
 their margins, and in most cases also on each of the wing veins. In the 
 female the prol)oscis is long, slender, and adapted for piercing. The 
 
 Fig. 10. — Egg-mass of Culex pungens, above; young larva, greatly enlarged, at right; 
 young larvae, less enlarged, below; enlarged eggs above at left (after Howard, Bui. No. 4, 
 Bureau of Entomology, Dept. of Agr.). 
 
 males do not suck blood, differing from the females in the absence of 
 the piercing stylets and in the possession of plumose antennae. 
 
 Mosquitoes have an adaptation to a very wide range, flourishing 
 equally as well in the frigid regions of the Arctic and Antarctic as in the 
 humid heat of the tropics. Until comparatively recent years few species 
 Avere known, but more intensive study, in view of their importance as 
 carriers of disease and as pests of man, has brought the mosquito fauna 
 of the world up to about one hundred genera including seven hundred 
 species, of which there are about fifty known in the United States. 
 
 Breeding Habits. — In the larval stage all the known mosquitoes 
 are aquatic, l^ut such differences occur in their life histories and habits 
 
MOSQUITOES AND GNATS 25 
 
 that 110 one species will serve as typical of the group. In observations 
 conducted by L. O. Howard at Washington, D. C. (1900 Rept.), upon 
 the species Cidex pungens it was determined that the eggs were laid upon 
 the water surface in masses of a variety of shapes, often described as 
 boat-shaped because a common form is that of a pointed ellipse (Fig. 10). 
 The number of eggs in each mass varied from two hundred to four hun- 
 dred, all arranged perpendicularl}' and in longitudinal rows. The in- 
 dividual eggs are slender, somewhat pointed at the tip, and at the bottom 
 broader and blunt, having a length of 0.7 mm. and a diameter of 
 0.16 mm. at the base. 
 
 It has been demonstrated that under the advantageous conditions 
 of the warm summer months eggs may hatch in less than a day from the 
 time they are deposited. The larvae, issumg from the 'under side of the 
 egg mass, are elongate, with head, thorax and alxlomen distinct, the 
 head bearing prominent antenna? each consisting of a single segment. 
 About the mouth is a mass of prehensile filaments. The abdomen is 
 segmented, and respiration is by tracheae which open at the apex by 
 means of the anal siphon. They appear to undergo four molts, and, 
 under favorable conditions, may be transformed into pupae in about 
 seven days. Studied at a period when the larva is nearly full grown, 
 it is seen to remain near the surface of the water with its respiratory 
 tube at the exact surface and its mouth below receiving food which is 
 directed to it by the rotary movements of the mouth filaments. Occa- 
 sionly the larva descends below the surface, but, by a series of wrigglings, 
 quickly returns. The return is only accomplished by considerable 
 exertion, as, once below the surface, the tendency of the larva is to sink 
 rather than to rise. If, therefore, for any reason it is unable to suffi- 
 ciently exert itself to again reach the surface, it will perish. The eflficacy 
 of the film of oil spread upon the water may be thus explained; it not 
 only prevents access to the air, but, by its deleterious effect, renders the 
 larva unable to exert sufficient muscular force to recover the position 
 necessary for respiration and buoyancy. 
 
 The transformation to the pupal stage, occurring under favorable 
 conditions aljout the seventh day, is marked by a great enlargement of 
 the thoracic segments (Fig. 11). Here the reverse of the just described 
 physical phenomena obtains; the pupa is lighter than water, and, unlike 
 the larva, effort is required to sink rather than to rise. It remains mo- 
 tionless at the surface, when disturbed descending to the bottom by 
 violent wrigglings. As soon as these exertions cease it will again grad- 
 ually rise. The differential structure of the pupa is noticeable in the 
 tnlargement of the thorax, and in that the air tubes no longer open at 
 the abdominal apex, but through two ear-like processes on the thorax, 
 the pupa remaining ujiright at the water's surface instead of head down- 
 ward as in the larval stage. Since the adult insect emerges from its 
 
26 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 pupal case at the thorax, there is an apparent adaptability in this re- 
 versal of position. 
 
 The common house or ''rain barrel" mosquito of the Northern 
 United States, Culex pimgens (Fig. 12), breeds throughout the summer, 
 broods developing wherever there may be standmg water, as in pools, 
 troughs, cans, discarded bottles, gutters, etc. The adults of this species 
 may pass the winter in the shelter of darkened retreats, such as the 
 cellars of houses, behind furniture, outbuildings, and wood piles, 
 emerging from their hibernation in the spring to deposit their eggs. 
 Many first spring broods in temperate climates hatch from eggs that 
 have been carried over the winter months, the eggs seeming to stand 
 desiccation in dry locations to promptly hatch in pools left by the spring 
 
 Fig. 11. — Pupa of Culex pungens at left; pupa of Anopheles quad- 
 rimaculatus at right — greatly enlarged (after Howard, Bui. No. 25, 
 Bureau of Entomology, Dept. of Agr.). 
 
 rains, or even in water from melting snow during the warmer days of 
 late winter. 
 
 In refutation of the assertion often made that mosquitoes cannot 
 ovulate without a meal of warm blood, it has been demonstrated in 
 experiments upon some of our common blood-sucking species that fe- 
 males as well as males can not only be kept alive for a long period when 
 given access only to plants, but will, under such conditions, repeatedl}^ 
 breed. 
 
 Pathologic Importance. — While their preference for blood has made 
 them of primary general interest as pests in the habitations of man, 
 mosquitoes are of the greatest importance medically, not only as possible 
 direct transmitters of disease, but as specific bearers of infection, bring- 
 ing about such diseases as malaria, yellow fever, and possibly filariasis. 
 There have been many convincing demonstrations that malaria is 
 transmitted exclusively by the bite of mosquitoes, only, however, by 
 species belonging with the anopheles group, of which Anopheles quadri- 
 
MOSQUITOES AND GNATS 
 
 Fig. 12. — Culex pungens: a, fomalo, from side; b, male, from above; c, front 
 tarsus of same; d, middle tarsus; e, hind tarsus; f, genitalia of same, i, scales from 
 hind border of wing; h. scales from disk of wing — enlarged (after Howard, Bui. 
 No. 4, Bureau of Entomology, Dept. of Agr.). 
 
28 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 m-aculatus (Fig. 13) and A. punctipennis have been most often observed 
 in the United States. While elaborate keys and tables are necessary even 
 to the entomologist for more exact differentiation, it is not a difficult 
 matter to decide whether a mosquito is or is not a transmitter of malaria, 
 
 Fig. 13. — Anopheles quadrimaculatus: Adult: male at left, fe- 
 male at right — enlarged (after Howard, Bui. No. 25, Bureau of 
 Entomology, Dept. of Agr.). 
 
 the two genera Ciilex and Anopheles being readily distinguished by the 
 following more prominent characteristics : 
 
 The adult Culex, when at rest upon a wall, usually holds the body 
 
 Fig. 14. — Anopheles at left, Culex at right — enlarged (after Howard, Bui. No. 25, 
 Bureau of Entomology, Dept. of Agr.). 
 
 parallel with the wall, or with the abdomen slightly inclined toward it, 
 the angle formed by the abdomen with the head and thorax giving a 
 
MOSQUITOES AND GNATS 
 
 29 
 
 hunchback appearance. The proboscis projects forward but not suffi- 
 ciently so as to be on a line with the axis of the body (Fig. 14). The 
 palpi in the female are short, in the male usually long. The wings, as a 
 lule, are without spots. 
 
 Adults of the anopheles group when thus at rest hold the body at an 
 angle of about forty-five degrees with the wall's surface, the abdomen 
 directed outward (Fig. 
 14) . The proboscis 
 projects forward on a 
 line with the axis of 
 the body. In both 
 sexes the palpi are 
 about as long as the 
 proboscis. The wings 
 are usually spotted. 
 
 The larva of Culex, 
 when at the surface 
 of the water, rests in 
 an oblique or vertical _ 
 position with the re- 
 spiratory tube at the 
 exact surface (Fig. 15). 
 
 The resting larva of 
 Anopheles floats in a 
 horizontal position just 
 beneath the surface. 
 There is no respiratory 
 tube, the spiracles 
 opening on the eighth 
 abdominal segment 
 which is applied to 
 the surface (Fig. 15). 
 
 Eggs of Culex are de- 
 posited upon water in 
 masses, the rafts of eggs 
 often being more or less 
 boat-shaped (Fig. 10). 
 
 Anopheles lay their eggs upon water unmassed, the eggs floating 
 singly by lateral expansions (Fig. 16). 
 
 The mosquito breeding in our Southern States which carries yellow 
 fever from man to man, ^Edes calopus iStegomija calopiis, S. fasciata), 
 is rather peculiarly marked. Upon each side of the thorax is a broad, 
 silveiy, curved line, between which there are two parallel median lines 
 and a slender discontinuous line, the whole pattern presenting somewhat 
 
 Fig. 15. — At top, half grown larva of Anopheles in 
 breathing position, just beneath the surface film. At 
 bottom, half grown larva of Culex in breathing position 
 — greatly enlarged (after Howard, Bui. No. 25, Bureau 
 of Entomology, Dept. of Agr.)- 
 
30 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 the shape of a lyre. At the base of each abdominal segment is a narrow, 
 silvery band, while on each side there is a silvery spot. At the base of 
 each segment of the black legs there is a distinct white band. 
 
 Highly domestic, this species will breed in collections of water about 
 and within the habitations of man, the larvae often being found in small 
 household water receptacles, such as flower pots, vases, etc. Of its 
 habits acquired by long association with man, Howard thus speaks: "It 
 approaches stealthily from behind, retreating upon the slightest alarm. 
 
 Fig. 16. — Group of eggs of Anopheles quadrimaculatus as they appear resting 
 naturally on the surface of the water— enlarged (after Howard, Bui. No. 25, 
 Bureau of Entomology, Dept. of Agr.). 
 
 The ankles and, when one is'sittmg at a table or desk, the under side of 
 the hands and wrists are favorable points of attack. It attacks silently, 
 whereas other mosquitoes have a piping or humming note. The warning 
 sound has doubtless been suppressed in the evolutionary process of its 
 adaptation to man. It is extremely wary. It hides whenever it can, 
 concealing itself in garments, working into the pockets and under the 
 lapels of coats, and crawling up under the clothes to bite the legs. In 
 houses it will hide in dark corners, under picture moldings and behind 
 the heads of old-fashioned bedsteads. It will enter closets and hide in 
 the folds of garments." 
 
MOSQUITOES AND GNATS 31 
 
 Effect upon Live Stock. — That mosquitoes are a source of much 
 annoyance and actual suffering to live stock can be attested to by stock- 
 men. Horses and cattle pasturing upon low lands and amid vegetation 
 where the insects abound are especially exposed to attack, the pests 
 often hovering about them in clouds, while upon the bodies of the 
 animals large numbers may be seen with abdomens engorged with the 
 blood of their victims. Loss of condition and the falling off of produc- 
 tiveness in dairy herds must essentially follow this interference with 
 their pasturage and comfort. 
 
 Control. — The most effectual preventive measures dealing with mos- 
 quitoes are those directed against the larvie. The abolition of breeding 
 places being of first importance, all receptacles for standing water, such 
 as rain barrels, cans, vaults, gutters, etc., should be removed, covered, or 
 otherwise made impossible to access and propagation of mosquitoes. 
 Pools should be drained, or, if this is not feasible, ma^- be treated with 
 kerosene; or small fish, which feed upon the larvae, may be introduced 
 into the mosquito-breeding ponds. The quickest and most satisfactory 
 way to destroy larvae and pupae is by the formation of the kerosene 
 film upon the water's surface. The oil is best applied for this purpose 
 as a spray, or, if but a small area is to be treated, it may be thrown upon 
 the surface and the water then vigorously stirred. About one ounce of 
 kerosene to fifteen square feet of water surface will be sufficient, and this 
 application should be repeated at intervals of about three weeks. 
 
 Such measures are directed only against local species, and, essentially, 
 there must be community action for it to be effective. Migratory forms, 
 such as are bred in the marshes near our coasts, cannot thus be reached, 
 their eradication constituting a problem demanding state control. 
 
 For indoor protection in mosquito-infested districts, screening is of 
 course essential. In spite of the most thorough screening, however, 
 mosquitoes will enter in various ways, as through openmg doors and upon 
 the clothing of persons passing in. As remedies against those which 
 have gained access to houses various kinds of repellents are used. Burn- 
 ing pyrethrum powder will often rid a room of mosquitoes, a convenient 
 method being to sprinkle the powder upon a heated shovel; or small 
 cones may be molded from the dampened powder and, after drying, 
 burned. Oil of pennyroyal or citronella applied to handkerchiefs or 
 lightly touched to the hands and face, though objectionable to some, 
 will usually insure a ]5eaceful night against the pests. 
 
 Family II. Simuliid.e 
 
 Dipt era (p. 23). The flies of this family are known as black flies, 
 black gnats, or buffalo gnats, the latter name derived from their peculiar 
 humpback appearance. They are dark colored, with short thick body, 
 
32 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 short eleven-segmented antennae, no single eyes, broad wings, and stout 
 legs. Only the females are provided with piercing mouth parts. 
 
 The larvae, so far as known, are aquatic. The eggs are deposited in a 
 compact layer upon some object, usually rock, near the surface of a 
 flowiiig stream. Upon hatching the larvae drop into the stream and live 
 attached to sticks, stones, or other objects under the surface of swiftly 
 running water. They may detach themselves and move about in a 
 looping manner similar to that of the measuring worm, or they may 
 be carried by the current for considerable distances. Respiration is 
 carried on by gill-like processes. 
 
 SiMULIUM PeCUARUM 
 
 The Southern Buffalo Gnat (Fig. 17). Simuliidae (p. 31). The adult 
 female is nearly a quarter of an inch in length, the male somewhat 
 
 smaller. The color of the body is 
 black, and it is covered with light 
 brown hairs which are arranged upon 
 the thorax in such a manner as to give 
 a longitudinal striped appearance, the 
 abdomen showing upon its dorsal side 
 a broad grayish stripe widening out 
 toward the abdominal apex. The 
 male notably differs from the female 
 in that the eyes are much larger and 
 join each other in the middle line. 
 The individual facets on the' upper 
 part of the eye are considerably larger 
 than those of the female. 
 
 The larva (Fig. 18) agrees in gen- 
 eral appearance with that of other 
 species of Simulium. It is about 
 three-eighths of an inch in length, 
 twelve-segmented, somewhat con- 
 stricted in the middle, enlarging to- 
 ward both ends. The posterior end 
 is the larger and is somewhat club- 
 shaped. In addition to the mouth, 
 the head possesses two fan-shaped bodies which are prehensile in func- 
 tion. On the top of the last abdominal segment there are rows of 
 booklets, while in the vicinity of the rectum are organs of respiration 
 consisting of three tentacles to which the large tracheae lead. 
 
 The pupa (Fig. 19) has a peculiar tuft of respiratory filaments starting 
 from each side of the thorax. The upper portion of the pupal case is 
 open, exposing the head and permitting the respiratory filaments to 
 
 Fig. 17. — Simulium pecuarum, female 
 — enlarged (after Osborn, Bui. No. 5, 
 Bureau of Entomology, Dept. of Agr.). 
 
MOSQUITOES AND GNATS 
 
 33 
 
 have free access to the water. The pupa is firmly attached to sticks, 
 leaves, or other submerged objects. On emerging from the pupal case 
 the fly at once rises to the surface and, expanding its 
 wings as it runs upon the water for a short distance, flies 
 swiftly away. 
 
 Occurrence and Efifect. — The buft'alo gnat has been 
 found in Alaska and throughout the Eastern United 
 States, but appears in greatest numbers in the South, 
 especially about the mouths of rivers and creeks. During 
 the worst years the whole of the Lower Mississippi Valley 
 as far north as St. Louis may be invaded. 
 
 The attacks b\' swarms of this bloodthirsty and vic- 
 iously active insect upon southern live stock is a source 
 of serious injury and loss. Cattle and horses will mani- 
 fest the presence of the swarms by frantic efforts to de- 
 fend against the attack, cattle rushing wildly about and 
 horses and mules trying to escape by running awa^-. 
 The most destructive raids of the fly usually occur in 
 the months of March and April. They are exceedingly 
 
 swift in their flight, darting at their pj^ 
 victims in search of a suitable place to muiium pecua- 
 draw blood, and in their bite instilling J"''™' ,^f Y"^"!"' 
 
 , T • 1 1 • /• larged (after Os- 
 
 a poison. Many ammals die irom ex- born, Bui. No. 5, 
 combmed with the 
 
 haustion, combmed with the toxic Bureau of Ento- 
 effects of the poison from the bites. ™°J°^^'' ^^p*- °^ 
 Bronchitis and pneumonia, resultmg 
 from the inhalation of large numbers of the insects 
 from which the exhausted animal becomes totally 
 unable to defend itself, may also contribute to the 
 conditions leading to its miserable death. 
 
 Control. — Outbreaks in heavily infested districts 
 may be lessened in frequence and severity by the 
 clearing out of logs and other debris in the beds of 
 streams, thus reducing the number of objects for 
 attachment of the larvse. Unlike those of the mos- 
 quito, the larvae of Simulium thrive best in swiftly 
 running and well aerated water, therefore the re- 
 moval of any submerged object causing shallow and swift h' moving 
 water reduces the possibilities for breeding at this point. 
 
 Protection. — The black gnat dislikes smoke, therefore, as prevention 
 against its attacks in fields and barnyards, the mamtenance of smudges 
 is of value. Other repellents, such as fish oil, oil of tar, or other oleagin- 
 ous and resinous substances, either singly or in combination, are 
 applied to the surface of the body, affording a measure of protection 
 
 Fig. 19. — Simulium 
 pecuarum, pupa — en- 
 larged (after Osborn, 
 Bui. No. 5, Bureau of 
 Entomologv, Dept. of 
 Agr.). 
 
34 PARASITES OF THE DOMESTIC ANIMALS 
 
 from attacking swarms. The most effectual protective measure is the 
 sheltering of animals in a cool dark stable during the hours of the day 
 when the swarms are most active. 
 
 Treatment. — Animals weakened by the bites may be given a dif- 
 fusive stimulant and have the parts locally treated with a solution of 
 bicarbonate of soda or ammonia water. 
 
CHAPTER V 
 THE FLIES 
 
 Family III. Tabanidae. — Diptera (p. 23). This family includes 
 the so-called horseflies or gadflies. The head and e3'es are large, the 
 latter often of a brilliant color. The third segment of the antennae has 
 four to eight rings. The proboscis of the female is adapted for piercing 
 the skin of animals. The males do not attack animals; their mouth 
 parts are less powerful than those of the females and are adapted for 
 feeding upon the juices of plants. The bod}- has fine hairs; there are no 
 bristles. The flight is strong and swift and is accompanied with a 
 tormenting buzzing noise. 
 
 The eggs of Tabanidae are deposited in masses upon vegetation grow- 
 ing in wet marshy ground. The larvae are carnivorous and are aquatic 
 or live in moist earth. 
 
 Tabaxus Atratus 
 
 Tabanidae (p. 35). This is the common large black horsefly, having 
 a M'ide distribution in the United States. It is one of the larger species 
 of the family, measuring an inch or more m length and having a body so 
 uniformilv black as to attract attention even when it is upon the wing 
 (Fig. 20)." 
 
 The eggs are deposited in masses, usually upon the stems of plants or 
 grasses growing in the vicinity of water. In about seven to ten days 
 there is hatched a large cylindrical larva which tapers to a point at both, 
 ends and has an integiunent that is somewhat transparent (Fig. 20, a). 
 At this stage it lives mostl}^ in moist earth into which it burrows actively, 
 feeding mainly upon worms and the larvae of other insects. While the 
 period of larval life is long, in some observed cases lasting several months 
 to a year, the stage of the pupa (Fig. 20, b) is short, the fly emerging from 
 its case after a few daj-s of pupation. It is probable that the broods are 
 carried over the winter in the larval stage. 
 
 Effect. — The black horsefly is common throughout the summer 
 months, attacking cattle and horses usualh' in the open sunny pasture, 
 and inflicting with its long piercing mouth parts a painful wound. For- 
 tunately it does not attack in swarms as does the buffalo gnat, nor does 
 it instill with its bite as much poison. There is evidence of the severity 
 of its wound, however, in the drop of blood which wells up from the seat 
 of puncture after the insect has left its victim. While there is little 
 
36 PARASITES OF THE DOMESTIC ANIIVIALS 
 
 after-effect from the bites of these flies they are a source of much tor- 
 ment to Hve stock, not only in the pain produced by their punctures, 
 but in their pecuhar buzzing, which often terrorizes nervous animals, 
 
 their frantic and heed- 
 less efforts to escape not 
 infrequentlj^ resulting 
 in injury. 
 
 There can be no 
 doubt that the Taba- 
 nidae are concerned in 
 the transmission of cer- 
 tain blood diseases of 
 live stock. It is signif- 
 icant as to their possi- 
 bihties as carriers of 
 anthrax that their at- 
 tack seems to be more 
 commonl}'- d ir e c t e d 
 against cattle than 
 horses. 
 
 Protection. — Little 
 can be done toward 
 repelling the attacks of the flies. Horses at work are protected in a 
 measure by covering them with nets. Where the flies are numerous and 
 especially tormenting it is advisable to remove pasturing animals to a 
 well-shaded retreat during the warmer and sunnier parts of the day. 
 
 Fig. 20. — Tabanus atratus: a, larva; b, pupa; c, adult 
 (after Osborn, from Riley, Bui. No. 5, Bureau of Ento- 
 mology, Dept. of Agr.). 
 
 Tabanus Lineola 
 
 Tabanidffi (p. 35).— The Green-head Horsefly (Fig. 21). This is the 
 most widely distributed species in North America. It is about five- 
 eighths of an inch in length. E^^es large and bril- 
 liant green, abdomen brown, with a conspicuous 
 grayish line running longitudinally on its dorsal 
 side. It is from this marking that its specific 
 name is derived, while the peculiar coloring of the 
 eyes gives to it the common name "Green-head." 
 
 The oval, larval, and pupal stages are passed uneok (after Osbom; 
 in moist places, and in other respects the life cycle from Packard, Bui. No. 5, 
 is similar to that of Tabanus atratus, though the 
 larval period is probably not so long. 
 
 The Green-heads appear in especially large numbers in marsh}^ dis- 
 tricts during the brightest and hottest days of the summer. They 
 attack in greater numbers than the Black Horseflies, and, especially 
 
 Fig. 21. — Tabanus 
 
 Bureau of Entomology, 
 Dept. of Agr.). 
 
. THE FLIES 37 
 
 during warm and sunny weather, their harassing bites cause much 
 torture to horses and cattle. They do not fly in cloudy weather, and 
 they perish with the frosts of earl}^ autumn. 
 
 Family IV. Muscid.e 
 
 Diptera (p. 23). — These flies are small to moderately large, with bodies 
 thinly covered with hairs or bare. The bristles of antennae are feathery. 
 The abdomen is four-segmented and smooth except for bristles near the 
 
 The larvae are apodal maggots, feeding upon decaying animal or veg- 
 etable matter. 
 
 MUSCA DOMESTICA 
 
 The common house fly (Fig. 8). Muscidae (p. 37). — The mature in- 
 sect is 02ie-fourth to five-sixteenths of an inch in length; dorsal region of 
 thorax grayish in color and bearing four longitudinal stripes; abdomen 
 yellowish. The mouth parts are trumpet-shaped, adapted for sucking 
 up liquids but not for piercing. 
 
 Life History. — In about ten days after emerging from the pupal 
 case the female fly seeks suitable material upon which to deposit her 
 eggs. This may be any decaying vegetable matter, though usually 
 horse stable manure. About one hundred eggs are deposited at each 
 laying, of which there are several at intervals of three to five days. In 
 eight to twentj^-four hours a white, footless larva is hatched. After 
 five daJ^s to one week of feeding and and growing, during which period 
 it undergoes two molts, the larva enters the pupal stage, the larval skin 
 serving as its puparium. Before entei'ing this stage the maggot may 
 crawl away from its breeding place and burrow for a short distance 
 into the adjacent ground, or find lodgment under a board, stone, or 
 dried crust of manure. The stage of pupation lasts from five days to 
 one week, and at its termination the adult fly emerges. 
 
 According to the longer periods given, the time required for develop- 
 ment from the egg to the imago is fifteen days. This time, however, is 
 greatly influenced by temperature, under the most favorable conditions 
 of which the period for complete metamorphosis may be reduced to ten 
 days; a fact always to be reckoned with in dealing with control of the fly 
 through the regiilar and systematic removal of stable manure or other 
 material which may serve as its breeding bed. 
 
 In the warm midsummer season adult flies may live for six to eight 
 weeks, though it is probable that the average period will not exceed 
 thirty days. The}' may survive the winter in a state of hibernation, 
 seeking their retreats in the late fall months, and coming forth with the 
 warm da^'s of early spring to crawl upon the windows as they seek the 
 warm sunlight or exit from houses. 
 
38 PARASITES OF THE DOMESTIC ANIMALS 
 
 Habits and Relation to Disease.— While, so far as known, the 
 house fly is not an essential host to pathogenic organisms of man and 
 the mammalian domesticated animals, it is, by its structure and filthy 
 habits of feeding, one of the most dangerous of disease-transmitting 
 insects. Omniverous in habit, it will feed upon decaying vegetable and 
 putrid animal matter, excrement, vomit, sputum, or other revoltingly 
 filthy material. Direct from such sources of infection it may pass to 
 the food upon our tables to which it is equally attracted, leaving a 
 trail of contamination wherever it may drag its filthy parts. 
 
 From the viewpoint of the bacteriologist it would seem superfluous to 
 discuss the house fly as a carrier of disease-producing bacteria. The 
 form of its proboscis, habit of regurgitating its food, its six bristly feet 
 (Fig. 8), each terminated by a sponge-like structure secreting a stick}'- 
 substance, together with the vile material which it visits, make it both 
 by structure and habit an ideal transmitter of such infectious diseases as 
 typhoid fever, dysentery, cholera, glanders, anthrax, and ophthalmia. 
 Furthermore, positive evidence of the degree to which this insect is a 
 carrier of bacteria has been well set forth by laborator}^ experiment. 
 
 Control. — As a widely disseminated menace to public health the 
 house fly presents a problem that can only be successfully dealt with by 
 community action. The measures taken should look to control rather 
 than elimination, the latter, however desirable, being scarcely possible 
 under present conditions. While it prefers horse manure, it is known 
 that almost any fermenting material will serve as a breeding place, and 
 it therefore follows that, in order to successfully combat this pest through 
 its sources of propagation, all such material must be systematically re- 
 moved, screened off, or so treated as to render it unsuitable for the 
 development of the larvae. Manure should be removed at least once a 
 week, and if possible at once spread upon the fields. Kitchen garbage 
 should be likewise removed, and in the meantime kept in tightly closed 
 receptacles. Access of flies to the vaults of outhouses can be prevented 
 by their proper structure and screening. 
 
 Protection. — As to measures of protection to the household against 
 flies, there is little to be said that is not of common knowledge. The 
 first of these to be mentioned is the thorough screening of doors and 
 windows. Kitchens being especially attractive to flies, they should be 
 doubly protected by screening the back porch, the screen doors at these 
 locations being well fitting and made to withstand their frequent use. 
 Flies that have gained entrance are best gotten rid of by burning pyre- 
 thrum powder. A good method for the treatment of a room is to sprinkle 
 the powder upon a hot shovel after first closing the doors and windows; 
 if the kitchen, the powder may be sprinkled over the stove. It is best 
 applied at night, leaving the room tightly closed. In the morning the 
 flies will be found lying about dead or stupefied, when they may be 
 
THE FLIES 39 
 
 swept up and Ijurnod. The use of poisonous liquids set around in dishes 
 has but httle efficacy and for other reasons is not to be reconunended. 
 Sticky .fly paper, to be most effectual, should be placed in parts of the 
 room where there is most sunlight, as in the vicinity of windows. 
 
 In this connection it should be borne in mind that adult house flies 
 and their allies seek the light, while their larvse avoid it, characteristics 
 referred to in the first case as light positive and in the second as light 
 negative. This habit as to light is to be reckoned with and taken ad- 
 vantage of in measures looking to fly control. 
 
 Stomoxys Calcitrans 
 
 Strotnoxys stabulans. Sta])le fly; stinging fly. Muscidse (p. 37). 
 About the size of the house fly. The ciplor is brownish gray; proboscis 
 black, slender, bent near its base, and extending forward from the head, 
 fitted for piercing. The thorax bears four longi- 
 tudinal stripes which may be more or less broken. 
 The abdomen is stout, grayish, and spotted dor- 
 sally. The wings hyaline, and when at rest widely 
 spread apart at the tips. The fly rests with its 
 head well elevated and- with wings sloping later- 
 ally downward and outward (Fig. 22). 
 
 The eggs are about one nun. in length, cur^'ed 
 
 ., , -i. • 1 r • 1 J. , Pig. 22. — btomoxys cal- 
 
 on one side, on the opposite side straight and eitrans, enlarged. 
 grooved. The larva resemble those of the house 
 
 fly. They ma>' be differentiated by the posterior stigmal plates, 
 which in the larviP of the house fly are large, irregularly oval, and close 
 together, while in Stomoxys they are smaller, round or triangular, and 
 much farther apart. 
 
 Life History. — The life-cycle of the stable fly is considerably longer 
 than that of the house fly; like the latter it breeds in horse manure, but 
 not to the same extent. Manure well mixed with straw is that most 
 sought. Ideal for the deposition of its eggs are damp and fermenting 
 collections of such material as cut grass, alfalfa, hay, grain, or piles of 
 weeds. The eggs are deposited deep into the fermenting mass, and, 
 under favorable conditions of temperature, will incubate in about three 
 days. The larvae are active feeders and complete their growth in from 
 twelve to thirty days. As in related flies, the puioarium is formed by 
 the hardenhig of the last larval skin. The duration of the pupal stage 
 will again vaiy according to weather, lasting from six to twenty days, or, 
 if cool, it may be much longer. About twelve days may be taken as an 
 average period. The time required for complete development may 
 accordingly be set down as from twenty-five to thirty days under 
 ordinarih' favorable conditions. It is proi)able that the species is car- 
 ried over the whiter months in our Northern States in the larval and 
 
40 PARASITES OF THE DOMESTIC ANIMALS 
 
 pupal stages. Development with the appearance of adult flies will 
 occur in warm stables during this season. 
 
 Occurrence and Effect. — The stable fly is of world-wide distribution, 
 and is connnonly mistaken for the house fly, the term "biting house 
 fly" being often applied to it from its habit of entermg our houses durmg 
 damp, rainj^ Vv^eather and in the cooler days of early autumn. It may 
 quickly be distinguished from the common house fly, however, bj^ its 
 elevated head when at rest, its protruding, baj'onet-like proboscis, and 
 its wings, which are widely spread apart at the tips. 
 
 Though commonly called the stable fly, Stomoxys is found in far less 
 numbers about stables than is the house fly, and, as it will not visit such 
 filth as does the latter, it is not such an offender agamst the cleanliness 
 of dairy and other food products. Both sexes of Stomox^'s, however, 
 are vicious blood-suckers, and their bite is especially a source of torture 
 to thin-skhmed, sensitive animals. Typically an out-of-door fly, it is 
 most likely to enter stables in the cooler days of late summer or early 
 autumn when it will attack horses and cattle, attaching itself by prefer- 
 ence upon the legs. Their sharp sting is manifested by the stamping, 
 kicking, and general restlessness of the victims. The punctures are 
 often followed by the formation of papules which may coalesce and 
 rupture, leaving a scaly, more or less thickened skin with hairs scant, 
 lusterless, and erect. To the dairy they are a source of loss in milk 
 production through the worry and unrest caused by their attacks. 
 
 Relation to Disease. — The possibilities of the stomoxys fly as a 
 disseminator of infectious diseases have in recent years received con- 
 siderable attention. Its habit of visiting a number of hosts before 
 becoming engorged with blood, together with its deep puncture, war- 
 rants us in charging agamst this species possibilities in the transmission 
 of anthrax in cattle and glanders in horses. By some authors it is re- 
 garded as a carrier of the trypanosome {Trypanosoma evansi) which 
 produces surra of horses. Of this, however, there is no conclusive experi- 
 mental evidence. As to the responsibility of the stable fly for the spread 
 of infantile paralysis, it will be suflficient here to quote Riley and Johann- 
 sen, who, after reviewing the evidence, thus state their conclusions 
 (1915): "The evidence at hand to date indicates that acute anterior 
 pohomyelitis, or infantile paralysis, is transmitted by contact with 
 infected persons. Under certain conditions insects may be agents in 
 spreading the disease, but their role is a subordinate one." 
 
 Control. — Control measures consist in removing materials which 
 afford favorable breeding places for the fly. Collections of moist and 
 fermenting feed material, such as have been mentioned, should be re- 
 moved and scattered in a layer suflficiently thin to insure thorough 
 drying. It will then be unsuitable for the development of stomoxys 
 larvae, as they require considerable moisture. Manure in which there is 
 
THE FLIES 41 
 
 mixed considerable straw affords a favorable niediuni for the propaga- 
 tion of this fl}^ — a further reason for its systematic removal to be at once 
 spread upon the fields, as stated in control measures for the house fly. 
 It should be borne in mind, however, that stables are not predominant as 
 breeding places of the fly under consideration, as is the case with the 
 house fly. Stomoxys is attracted to stables because the animals from 
 which it obtains its meal of blood are contained there. The favorite 
 material for the deposition of its eggs is likely to be found elsewhere. 
 These flies like the open, and chstricts far from stables may be overridden 
 with them. 
 
 Protection. — Little can be done in the way of direct protection of 
 live stock against the attacks of stable flies beyond thorough screening, 
 the effectiveness of which is much lessened by the frequent opening of 
 doors customary about stables. Means of keeping them out should be 
 especially looked to in cloudy, damp weather, and in the cool mornings 
 of early autumn, at which times they are most likely to seek the interior 
 of stables and houses. 
 
 Lyperosta Irritaxs 
 
 Hcematohia serrata.— The horn fly (Fig. 23). Muscids (p. 37). About 
 half as large as the house fly and like it in shape and color. The mouth 
 parts are adapted for piercmg and sucking blood, but differ from those 
 of the stable fly in that the palpi are almost as long as the proboscis and 
 are slightl}' spatulate. 
 
 The eggs (Fig. 23, a) are about L25 mm. in length, irregularly oval, and 
 reddish brown in color. They are deposited in the fresh dung of cattle, 
 and, under favorable conditions of temperature, will hatch in about 
 twenty-four hours. 
 
 Life History. — Newly hatched larvae are about 2.5 mm. in length, 
 and pure white. When full grown they are about 7 mm. in length and 
 somewhat darker in color. The larvae burrow into the dung and reach 
 their full growth in about four days (Fig. 23, b). When ready to trans- 
 form into the pupal stage the larvse descend into the dryer parts of the 
 dung, or for a short distance into the ground beneath it. The puparium 
 (Fig. 23, c) is about 4.5 mm. in length, irregularly ellipsoidal, and dark 
 brown in color. The pupal stage occupies from five to ten days, therefore 
 the time for full development from the deposition of the eggs will be, 
 according to the above, from ten to fifteen days. 
 
 Occurrence and Habits. — The horn fly is an importation from 
 Europe, making its first appearance in the vicinity of Philadelphia about 
 the year 1886. It was first noticed as a pest to cattle in this country in 
 1887, from which tune it has spread rapidly and at present is found in 
 practically all parts of the United States and the greater part of Canada. 
 
 The popular name ''horn fly" is derived from the habit peculiar to 
 
42 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 this species of clustering about the base of the horn, though this only 
 occurs when they are quite abundant. Their purpose in collecting here 
 seems to be for rest in a location where they are not liable to be dis- 
 turbed. There is a somewhat prevalent belief that the flies damage the 
 horn by eating into it, depositing eggs, and developing maggots which 
 may penetrate to deeper structures, etc. This is a popular error for 
 which there is no foundation, for, beyond "fly specking," it has not been 
 observed that the flies do any injury to the horn. 
 
 Field study will show that this insect assumes two characteristic posi- 
 tions. In the resting position, as they are found when upon the horns. 
 
 Fig. 23. — Lyperosia irritans: a, egg; b, larva; c, puparium; d, adult in biting 
 position — all enlarged (after Osborn, from Riley and Howard, Bui. No. 5, Bu- 
 reau of Entomology, Dept. of Agr.). 
 
 the wings are held nearly flat down the back, overlapping at their bases 
 and moderately diverging at their tips. The proboscis is extended for- 
 ward, and the legs are not widely spread. When active and feeding, on 
 the other hand, the wdngs are slightly elevated and held almost at right 
 angles to the body, while the legs are spread. The proboscis is nearly 
 perpendicular in position, and penetrates the skin of the animal at- 
 tacked. To secure this position it works its way to the skin, and is 
 usually observed more or less covered by the hairs. In damp, rainy 
 weather they may be noticed as particularly abundant beneath the 
 hairs of the ventral surface of the body. 
 
 Effect. — Horn flies appear early in May and become most abundant 
 in July and August. With the coming of cold weather they disappear, 
 
THE FLIES 43 
 
 their full period depending uiDon season and latitude. During the time 
 of their activity they are a veritable pest to cattle, causing interference 
 with their grazing and disturbance of their rest, with consequent un- 
 thrift and serious loss in productiveness. Horses do not escape their 
 annoyance, but cattle seem to be the special object of their attack. 
 Though the damage done is chiefly through their torment, the con- 
 siderable amount of blood extracted from the animal by the large 
 swarms which feed upon it must seriously contribute to the weakening 
 effects. Further, as in all blood-sucking Diptera visiting cattle, we are 
 justified in inferring that this fly may be a transmitter of infectious blood 
 diseases, such as anthrax, though as to this there has as yet been little 
 if any investigation. 
 
 Control. — In control measures two lines of procedure should be fol- 
 lowed, one looking to prevention of multiplication, the other directly 
 protecting cattle from attack. Of these the former is most effective and 
 involves, such treatment of breeding places as will prevent larval develop- 
 ment. As eggs are deposited in fresh dung, which must remain moist for 
 the proper nourishment of the hatched larvae, any treatment of the 
 droppings which will cause them to rapidly dry out will prevent or 
 greatly inhibit larval development. Scattering or thinly spreading this 
 manure, as may be done by a rake or by drawing })rush across the fields, 
 will accomplish this; the latter method, more economical in time and 
 labor, is best adapted for large pasture areas. Hogs running with cattle 
 will serve to scatter the manure to a large extent. The use of lime, which 
 may be applied by simply throwing it over the droppings in the pasture, 
 is very effective in destroying the larvae. While piles of cow manure, 
 especially those containing considerable straw, afford good breeding 
 places for the stable fly, the horn fly will not seek this material to any 
 great extent for the deposition of its eggs. 
 
 Protection. — For the direct protection of cattle a number of oleagin- 
 nous repellents are recommended. A mixture of fish oil and tar, equal 
 parts, applied to the regions most attacked, is one in general use. Almost 
 any oily or greasy substance is of value, though causing the animal to 
 become somewhat unsightly from adhermg collections of dust and dirt. 
 Sprays of kerosene emulsion (page 48) may be used with advantage, 
 though the effectiveness of such treatment is very transient. The 
 following mixture is recommended by the Kansas Experiment Station: 
 resin (pulverized), one part; shaved soap, one part; water, one-half part; 
 fish oil, one part; oil of tar, one part; kerosene, one part; water, three 
 parts. The resin, soap, fish oil, and one-half part water are boiled to- 
 gether until the resin is dissolved, then the three parts water are added, 
 and finally the kerosene and oil of tar. The mixture should be thor- 
 oughly stirred and lioiled for fifteen minutes. This preparation when 
 cool and applied as a spray will act as an effective repellent for twenty- 
 
44 
 
 PARASITES OF THE DOMESTIC ANIIVIALS 
 
 four to forty-eight hours. It is necessar}-, therefore, to regularly repeat 
 the application if the animals are to be continuously protected. Re- 
 pelling agents are best applied in the evenmg when cattle are stabled or 
 yarded. 
 
 Tsetse Flies 
 
 Genus Glossina.— Muscidge (p. 37). The tsetse flies (Fig. 24) are 
 about the size of house flies, or may be somewhat larger. The general 
 color is light brown. When at rest the proboscis projects in front of the 
 head. At the base of the proboscis is a bulbous enlargement, arista 
 
 Fig. 24.— Tsetse fly. 
 
 plumose above. The resting wings are folded scissors-like over the back. 
 
 These flies are found only in certain areas in Africa. 
 
 Glossina Palpalis.— Glossina (p. 44). This species is 8 to 9 mm. 
 (5/16 to 3/8 of an inch) in length. The color is brown dusted with gray. 
 The antennae are black. All segments in the hind tarsi are black. The 
 fourth and fifth segments of the fore tarsi are black. The halteres are 
 white. 
 
 Glossina Morsitans.— Glossina (p. 44). About the same size and 
 color as G. palpalis. The antennae are dark. The first three segments 
 of the hind tarsi are yellow, the fourth and fifth segments black. The 
 fourth and fifth segments of the first and second pairs of tarsi are black. 
 ^ Glossina longipalpis is a species which in characteristics and distribu- 
 tion is almost identical with G. morsitans. 
 
 Breeding Habits and Habitat.— The Glossina deposit hatched larva 
 among roots of tropical vegetation. When deposited the larvae are well 
 
THE FLIES 45 
 
 advanced and within a few hours enter upon the pupal stage which re- 
 quires from six to eight weeks. Occurring only in Africa, they are most 
 abundant in heavily wooded districts penetrated by water courses. 
 Both sexes are blood-sucking, and it is in such locations that they are 
 most likely to find the wild animals upon which they feed. 
 
 Relationship to Trypanosomiasis. — As transmitters of trypanoso- 
 miasis to man and domestic aniinals, tsetse flies maj' be regarded as the 
 world's most dangerous insects. The first observation of trj'panosomes 
 in the blood of mammals was made b}^ Lewis, who in 1877 described a 
 trypanosome {Trypanosoma lewisi) of the blood of a rat. Three years 
 later another trj^panosome (7". evansi) was studied as the cause of surra 
 in horses. When Bruce in 1894 demonstrated the relationship between 
 tsetse fly disease of horses in Africa, the cause of which was unknown, 
 and nagana, trypanosomes received much more attention as to their 
 pathogenic importance. The further investigations of Bruce as to the 
 part played by the tsetse fly in the transmission of this disease are best 
 given in his own account, from which the following is an excerpt: 
 
 "When it was once established that the two diseases were the same, 
 experiments were made to And out how the animals became infected, 
 whether the fly was the carrier or the mere concomitant of the low-lying, 
 mihealthy district, and, if a carrier, if it was the only carrier of the disease 
 from sick to healthy animals. Horses taken down into the fly country, 
 and not allowed to feed or drink there, took the disease. Bundles of 
 grass and supplies of water, brought from the most deadly parts of the 
 fly country to the top of Ubombo and there used for fodder for healthy 
 horses failed to convey the disease. Tsetse flies caught in the low country 
 and kept in cages on top of the mountain, when fed on affected animals, 
 were capable of giving rise to the disease in healthy animals up to forty- 
 eight hours after feeding. Tsetse flies brought up from the low country 
 and placed straight way upon healthy animals were also found to give 
 rise to the disease. The flies were never found to retam the power of 
 infection for more than forty-eight hours after they had fed upon a sick 
 animal, so that if wild tsetse flies were brought up from the low country, 
 kept without food for three days, and then fed on a healthy dog, they 
 never gave rise to the disease. In this way it was proved that the tsetse 
 fly, and it alone, was the carrier of nagana. Then the question arose as 
 to where the tsetse flies obtained the trypanosomes. The flies lived 
 among the wild animals, such as buffaloes, koodoos, and other species of 
 antelopes, and naturally fed on them. It seemed that, in all probabilitj^, 
 the reservoir of the disease was to be found in the wild animals. There- 
 fore, all the different species of wild animals obtainable were examined 
 both by the injection of their blood into healthy susceptible animals, 
 and also by direct microscopic examination of the blood itself. In this 
 way it was discovered that manv of the wild animals harbored this 
 
46 PARASITES OF THE DOMESTIC ANIMALS 
 
 trypanosome in their blood. The parasites were never numerous, so 
 that it was only after a long search that they could be discovered by the 
 microscope alone. The wild animals did not seem to be affected by the 
 trypanosomes in any way; they showed no signs or sjanptoms of the 
 disease, and it, therefore, appeared probable that the tiypanosomes lived 
 in their blood as harmless guests, just as the trypanosome of the rat lives 
 in the blood of that animal." 
 
 As Trypanosomu brucei is now known to be the organism causing the 
 fatal nagana of horses and mules of Africa, so T. gamhiense is known to 
 be the cause of sleeping sickness of man. The relationship of the tsetse 
 fly to human trypanosomiasis was shown in a way very similar to that 
 by which Bruce reached his conclusions. While the tsetse species 
 Glossina morsitans and G. longipalpis are especially concerned in the 
 transmission of nagana, and G. palpalis likewise related to sleeping sick- 
 ness, it has been shown by students in the field of protozoology that not 
 only biting flies, but mosquitoes, lice, and leeches may carry trypano- 
 somes from one vertebrate host to another. 
 
 Experiment has shown that the trypanosomes adhering to the pro- 
 boscis of the biting fly after it has fed upon the blood of an infected 
 animal rapidly lose their vitality, becoming sufficiently attenuated 
 within fortj'-eight hours to be noninfective. The fl}', therefore, can 
 only inoculate mechanicalh^ that is by the puncture of its soiled pro- 
 boscis," within a few hours after it has become a carrier of the infecting 
 organism. It is now known, however, that trypanosomes taken into 
 the stomach of the fly with its meal of blood pass through a metamor- 
 phosis involving sexual forms, and that at the end of about twentj'-eight 
 days the fly may again become infective. At this time the parasites 
 have reached the salivary glands and here they remain during the re- 
 mainder of the life of the fly. How long such a fly may retain its power 
 to infect is yet a question, though it has been found by the Sleeping 
 Sickness Commission to be at least three months. The duration of the 
 life of the tsetse fly has only been observed upon specimens in captivit}^, 
 but it is probable that it is about four to six months. 
 
 Control. — Measures looking to the control of the breeding of the 
 flies are limited practically to exclusion owing to the fact that the larval 
 period is passed within the body of the female, hence offers no opportu- 
 nity for attack through sources of larval food supply. The fact that 
 tsetse flies seek the vicinity of water courses surrounded by wooded 
 areas may be taken advantage of in excluding them from locations of 
 settlement. With a view to this it has been recommended that clearings 
 be made over an area of six hundred to eight hundred yards at some 
 distance from streams of water, the water supph' l^eing obtained from 
 wells. The difficulties presented, however, in the control of the fly are 
 numerous and in many features seem unsurmountable. The ultimate 
 
THE FLIES 
 
 47 
 
 solution of the problem probably lies in innnunization against the 
 tsetse fly diseases, as to which little progress has yet been made. 
 
 Family V. Hippoboscid^ 
 
 Diptera (p. 23). — The body is flattened. Wings are present or absent. 
 The wing veins are crowded toward the anterior margin. The head is 
 sunk into an emargination of the thorax; the antennae inserted in pits 
 near mouth; mouth j:)arts adapted for piercing and sucking blood. 
 The legs are stout, terminated by .strong claws. The abdomen is large 
 and sacular with segments indistinct. 
 
 The Hippoboscidse are pupipai'ous, the eggs being hatched and 
 nearly the whole of the larval stage passed within the body of the parent. 
 The larvae are extruded only when nearly ready to transform into pupae. 
 
 All are parasitic upon birds and mannnals. Hippohosca equina is a 
 winged species occurring upon the horse, and known in England as the 
 forest fly. 
 
 ^NIelophagus Ovixus 
 
 The sheep "tick." — Hippoboscidae (p. 47). Three-si.xteenths to one- 
 quarter of an inch in length. The color reddish or grayish brown. 
 The wings and halteres are ab- 
 sent. The head is small and 
 sunken into the thorax; ab- 
 domen large, sac-like, and 
 covered with short spines 
 (Fig. 25). 
 
 Life History. — INLatured lar- 
 vs are extruded from the body 
 of the female and at once enter 
 upon their pupation, the red- 
 dish brown pupae adhering to 
 the wool fibers. The pupal 
 stage occupies three to six 
 weeks according to season and 
 temperature, the shorter jieriod 
 occurring during the sunnner. 
 At sexual maturity the deposi- 
 tion of pupae begins, each fe- 
 male depositing from eight to 
 ten. Probably the life of the 
 tick will not exceed four to five 
 months. 
 
 Occurrence. — The sheep tick is distributed over all parts of the 
 workl where sheep are kept. Its parasitism is continuous, the pupiparous 
 
 Fig. 25. — Melophagus ovinus (from photo- 
 graph of mounted specimen, by Hoedt). 
 
48 PARASITES OF THE DOMESTIC ANII^L\LS 
 
 habit of bringing forth its 3'oung adapting it to spend its whole hfe upon 
 the host from which it never migrates miless to attach to another animal 
 of the same species. It is probable that this migration occurs principally 
 at the time of shearing when the ticks leave the sheared sheep and crawl 
 upon the lambs. Off the host the ticks will not survive longer than a 
 few days, probably all will be dead within a week. 
 
 Effect. — All breeds of sheep are ahke subject to attack, the presence 
 of the "tick," or "louse," as it is commonly called, and the injmy which 
 it causes, being a matter of common knowledge to sheep breeders. Sheep 
 are not materially affected by a few, but if in larger numbers, their 
 presence will be manifested by rubbing, scratching, and biting at the 
 fleece. Loss of flesh and general unthriftiness will occur in badly in- 
 fested animals. Where the ticks are prevalent lambs may be attacked 
 by large numl^ers at shearing time, in which condition many will die 
 unless promptly relieved. 
 
 Treatment. — In the winter months, when the long wool will not 
 permit of other treatment, the ticks may be greatly reduced in number 
 by the use of pyrethrum powder which should be freel}^ blown deep into 
 and upon the fleece over all parts of the body. The most effectual treat- 
 ment is best applied after shearing and consists of the application by 
 dipping or as a wash of such remedies as creolin, zenolium, lysol, or 
 cresol, used in two to three per cent, strength. Decoction of tobacco, 
 in strength of three to four per cent, is also used, but, to avoid danger of 
 nicotine poisoning, should not be applied to all parts of the bodj^ at once. 
 Kerosene emulsion, which has a wide range of usefuhiess in the treat- 
 ment of external parasites, is another of the numerous dips resorted to 
 in this connection. The emulsion may be made either with milk or soap 
 according to the following formulae : 
 
 Milk emulsion. — To one part milk add two parts kerosene and churn 
 by a force pump or by other means of agitation. Dilute the resulting 
 emulsion with eight to ten times its bulk of water. 
 
 Soap emulsion. — Dissolve one-half a pound of hard soap in one gallon 
 of hot water and, while still at near boiling point, add two gallons of 
 kerosene. Emulsify b}^ use of force pump or other means of agitation. 
 Dilute one part emulsion with eight or ten parts water. 
 
 These emulsions maj^ be used in the proportions given as a spray, 
 wash, or dip. 
 
 None of these dips will kill the pupae, and, therefore, keepmg in 
 mind the life histor}' of the parasite, the treatment should be re- 
 peated in about twenty-four daj^s. If the dipping has been done in 
 the cooler weather of autumn, this interval should be accordingly 
 prolonged. 
 
 As the movement of the ticks from the sheep to the lambs takes place 
 principally at the time of shearing when the insects are removed from 
 
THE FLIES 49 
 
 their host with the fleece, it is well at this time to keep the lambs at 
 some distance from the stored wool. This precaution should be ob- 
 served for at least a week from the time of shearino-, at the termination 
 of which period the ticks which have l)een removed with the wool will 
 be dead. 
 
CHAPTER VI 
 
 DIPTEROUS LARV^ 
 
 Flesh flies, blowflies, botflies. — The larvae of these flies produce a 
 form of parasitism to which the term myasis (also myiasis, and myiosis) 
 is appHed. Various forms of myasis are recognized according to the 
 location of the larvae, as cutaneous, muscular, nasal, gastric, and intes- 
 tinal. With certain species, as those of the family CEstridse, or true 
 botflies, the larval parasitism is obligate upon or within a living host 
 anhnal, while the larvae of the flesh and blowflies of the family Muscidae 
 may attack either living or dead, usually decomposing, tissue. 
 
 Chrysomyia Macellaria 
 
 Compsomyia macellaria; Cochliomyia macellaria, Screw worm fly. — 
 Muscidae (p. 37). Three-eighths to half an inch in length; color bluish 
 green with metallic reflections. There are three longitudinal black 
 stripes upon the thorax. The head is reddish or yellowish brown; 
 thorax and abdomen covered with stiff black hairs (Fig. 26) . 
 
 The eggs are about 1 mm. in length, white and cylindrical. They 
 are deposited in masses of three hundred to four hundred upon dead 
 and decaying flesh and upon wounds, sores, or within the nostrils or 
 other natural mucous openings of man and lower animals. Hatching 
 may occur in from one to twelve hours from the time the eggs are 
 deposited. 
 
 The larvae are white, apodal, slender, and quite active. The head 
 and segments are provided with spines which facihtate their burrowing 
 into the living or putrefying flesh upon which they feed, a habit which 
 gives to the mature insect its common name of screw worm fly. Under 
 most favorable conditions the full larval growth is reached in three days, 
 at which time they may be half an inch or more in length. When mature 
 they leave the flesh upon which they have been feeding and bury them- 
 selves in the earth near by, in which location they enter upon pupation. 
 
 The pupae are 6 to 9 mm. in length, somewhat barrel-shaped, and 
 dark brown in color. The pupal stage may last from six to twelve days. 
 
 Occurrence and Effect. — The screw worm fly is widely distributed, 
 being found throughout North and South America. In the United 
 States it is especially abundant in the South, where it is responsible for 
 the most serious cases of human myasis occurring in this country. It 
 begins to attack in June, but has its greatest period of activity in the 
 
DIPTEROUS LARVAE 
 
 51 
 
 three months which follow. In its attacks upon man it usually deposits 
 its eggs in the nostrils or mouth while the individual is sleeping. It is 
 especially attracted if the parts are unclean, as from the discharge of 
 nasal catarrh or collections of vomit about the lips. Persons in a drunken 
 stupor are especially liable to attack. For the same reason open sores 
 contaminated by collections of pus or blood are equally attractive to it. 
 
 The fl3''s greatest injury as a pest to domestic animals in the United 
 States occurs in the Southwest, where cattle are the greatest sufferers 
 from its ravages. In these animals the flies are attracted to wounds of 
 operations, such as dehorning, branding, castrating, etc., and to injuries 
 such as may result from hooking or 
 barbed wire. In fact any open 
 wound or exposed mucous mem- 
 brane, especially if soiled with an 
 odorous discharge, is a favorite seat 
 of attack. 
 
 Upon hatching, the larvae at once 
 proceed to attack the tissues and 
 maA' rapidly produce a serious de- 
 struction and mutilation. Thej^ grow 
 rapidly as they consume the tissues 
 adjacent to them, and in locations, 
 as parts of the limbs where there is 
 little fleshy covering, the bones may 
 be laid bare. 
 
 Protection.-As most of the fatal ^^^ 26.-Compsomyia macellaria-en- 
 cases of myaslS m man from this larged (after Osborn, from Francis, Bui. 
 cause are due to deposition of eggs ^o. 5, Bureau of Entomology, U. S. Dept. 
 
 in the nostrils while the person is ° " ^^ 
 
 sleeping, the first measure of precaution is to protect from attack by the 
 use of netting. Those sleeping out of doors in infested regions are most 
 exposed, but sleeping rooms should also be thoroughh' screened. Open 
 jiores and wovmds should of course be kept free from collecting discharge 
 and covered with clean, drj' dressing. The same precautions as to 
 (ileanliness of wounds and exposed mucous membranes applies to domes- 
 tic animals. The vulvae of cows recently fresh, especially if there has 
 been a retention of the placenta, and the navels of calves offer favorite 
 points for attack and should particularly be guarded. 
 
 Treatment. — Where sores and exposed mucous membranes have 
 already become infested with worms a disinfecting wash, such as a one 
 to three per cent, solution of carbolic acid, should be used. For injection 
 into regions where the maggots have penetrated, the injection of carbolic 
 acid or creolin in about five per cent, strength will destroy worms with 
 which it comes in contact. Chloroform diluted to a strength of about 
 
d 
 
 52 PARASITES OF THE DOMESTIC ANIMALS 
 
 twenty per cent, is also recommended for this purpose. An ordinary 
 machinist's oiler affords a practical method of applying such agents. It 
 has the advantage of deep application without waste of the material. 
 For deeply infested wounds a final packing of oakum and oil of tar should 
 be applied, and this should be covered by a protective dressing of tar 
 and oakum as a prevention from further attack. 
 
 Sarcophaga SaRRACENIvE 
 
 A flesh fly.— Muscidse (p. 37). In markings somewhat similar to the 
 house fly, but considerably larger. The general color is light gray; eyes 
 reddish brown. Body spiny. 
 
 The female deposits larvae upon fresh meat, or in the wounds of living 
 animals. Under favorable conditions the larval stage is completed in 
 
 about six days. The 
 mature larvae crawl to 
 a convenient shelter 
 where they undergo a 
 .- A, . . • wi fl 1 fl /c I > pupation from which 
 
 Fig. 2/. — Metamorphosis of the flesh fly (Sarcophaga) : , , , • • r- 
 
 a, eggs;b , young larva just hatched; c, d, full-grown larvae; the adults ISSUC Ul trom 
 
 e, pupa; f, imago (after Ortoii, by Dodge; Copyright, 1894, twelvC to fourteen 
 
 by Harper & Brothers) . ^j^,^,^ (p.g_ 27) . 
 
 Protection. — The flesh flies are of world-wide distribution, and are 
 of most importance as they affect fresh meats in the household or meats 
 in storage. As a protection in such cases the flies should be screened off 
 at some distance, as larvae which have been deposited in the vicinity of 
 meat will crawl to it, though it may not be accessible to the flies. 
 
 To prevent their attack upon wounds, the same general procedure 
 may be adopted as recommended for the preceding species. 
 
 Calliphora Vomitoria 
 
 Blowfly. — Muscidse (p. 37). Somewhat larger than house fly; eyes 
 brownish in color; abdomen bluish green with metalic luster and usually 
 pollinose. 
 
 The eggs are oval, white in color, and are deposited upon decomposing 
 animal and vegetable matter and in wounds of animals. Hatching may 
 occur in from a few hours to one or two days, the shorter periods occurring 
 in hot weather. After from three to nine days of feeding, the matured 
 larvae seek the ground, become buried for a short distance, and in this 
 location enter upon their stage of pupation. The time required for the 
 entire life cycle, including a prepupal period of several clays, may be 
 from two to five weeks, depending greatly upon temperature. Under 
 ordinary conditions it would piobably occupy al^out three weeks. 
 
 The blowfly agrees with the flesh fly in its habits, with the exception 
 
DIPTEROUS LARVyE 53 
 
 that it deposits eggs instead of living larvae. After hatching the manner 
 of attack and the effect upon infested meat and wounds is much the 
 same and calls for the same treatment. 
 
 Family VI. CEstrid^ 
 
 Diptera (p. 23). Botflies, warble flies. The head is large, bearing two 
 faceted eyes widely separated, antennae short and sunken into pits in 
 the front of the head. The mouth parts are rudimentary, most all of the 
 flies living in the adult stage without food. The body is heavy and 
 somewhat hairy. The coloration is usually inconspicuous. 
 
 The larvai are thick and twelve-segmented, the first two segments 
 not alwaj^s distinctly separated. There is no demarcation into body 
 regions, only a cephalic and anal end can be distinguished. The body- 
 segments are frequently provided with rows of spines. Buccal hooks 
 may or may not be present. Tracheal openings are at the posterior 
 extremity. 
 
 The larvae are parasitic in the stomach and intestines, mucous mem- 
 branes, subcutaneous connective tissue, nasal passages, and sinuses of 
 facial bones of mammals ; other parts are also invaded by their migrations. 
 When completely developed the larva leave these locations in the host 
 and pass to the ground where they enter the pupal stage. 
 
 The flies of the family QCstridae are of world-wide distribution. 
 
 Gastrophilus intestinalis {G. equi). Qilstridae (p. 53). The horse 
 botfly (Fig. 28, h). The body of the female is one-half to five-eighths of 
 an inch in length and is very hairy. The head, thorax and abdomen are 
 brown. The wings are transparent with dark spots, those near the center 
 passing entirely across the wing transversely. The abdomen is rather 
 long and tapers to a point. In the males, which are rarely seen, the 
 abdomen is light brown or yellow, and it is not tapering. In other re- 
 spects the males closely resemble the females. 
 
 The larvae (Fig. 28, c, d and g) when full grown are about three- 
 fourths of an inch in length. At the head extremity are two buccal 
 hooks by which attachment is made to the gastric mucosa (Fig. 28, e). 
 The body-segments are bordered by short spines (Fig. 28, d). 
 
 Habits. — Like other members of the Q^stridae, the horse botfly at 
 matuiity is extremely active, flying chiefly during the warmest and 
 bi-ightest days of the summer, and generally frequenting pastures in 
 the vicinity of woods. It is the habit of the female to hover near the 
 horse with its long, pointed abdomen bent downwaid and forward. The 
 fly then darts toward the horse, deposits its egg, retreats, and again 
 hovers until ready to repeat the operation. The eggs (Fig. 28, a and b) 
 are yellow in color, about one-sixteenth of an inch in length, and tapering 
 toward the attached end, the free end being provided with an operculum 
 which is set obliquely and gives to this end somewhat of an obliquely 
 
54 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 cut off appearance. The}' are generally deposited upon the hairs of the 
 anterior parts of the body, as upon the forelegs, breast, shoulders, and 
 under side of the body, regions which are most readily reached by the 
 lips of the horse. It is not uncommon, however, for eggs to be attached 
 to the sides of the neck, lower jaw, cheeks, mane, and other parts, the 
 larvae in such cases reaching the mouths of horses by their licking or 
 nipping at each other. 
 
 Life History. — The eggs are deposited rapidly with their free ends 
 down, and adhere to the hairs by a viscid substance which quickly dries 
 
 Fig. 28 — Gastrophilus intestinalis: a, egg — enlarged; b, egg — natural size; c, young larva; 
 d, young larva — much enlarged, showing spiny armature; e, oral hooks; f, body spines; g, 
 full-grown larva — twice natural size; h, adult female (after Osborn, Bui. No. 5, Bureau of 
 Entomology, U. S. Dept. of Agr.). 
 
 and gives them a firm attachment. At this time they contain larvae 
 which have undergone a more or less advanced development. 
 
 Observations upon the botflies during recent years have been some- 
 what disturbing to conclusions formerly held and apparently necessitate 
 a certain revision of the life histories which have generally been given for 
 them. According to the observations of Roubaud (1917) upon Gas- 
 trophilus intestinalis, the eggs of the fly do not open spontaneously, and 
 the larvae may not escape from them for several weeks. The opening 
 of the operculum and freeing of the larva probably occurs when the 
 horse rubs an itching or irritated area with his nose or bites it with his 
 teeth, the horse rarely hcldng itself. By experiments with bot larvae on 
 guinea-pigs Roubaud demonstrated that when the hatched larva is 
 brought in contact with the buccal mucosa it at once burrows into this 
 membrane and lies parallel to its surface. In two or three days it dis- 
 appears, but he notes that one was seen traveling along the side of the 
 
DIPTEROUS LARV.E 55 
 
 tongue for nine daj's, during which time it grew to three times its first 
 dimensions. Before leavmg the buccal mucosa the larvae probably 
 undergo a molt and then proceed to the stomach. These observations 
 indicate that the larvae of the botfly escape from the eggs when the horse 
 bites at his skin or rubs it with his lips, and that the}' burrow into the 
 buccal mucosa where they undergo a degree of development before 
 passing to the stomach. 
 
 Within the stomach cavity the larva fixes itself to the walls bj- its 
 buccal hooks. Later the head becomes deepl}' mserted into an alveolus 
 which is formed mider the influence of the irritation to the mucosa. In 
 this position the larva feeds upon the tissue juices and the products of 
 the irritation which it sets up, becoming fully grown in about ten months. 
 The period of larval development usually terminates from May to 
 August, more especially in June, due to the fact that the deposition of the 
 eggs occurs most actively in the month of August. At this time the 
 larva becomes detached from the gastric mucosa, passes to the intestines, 
 and with the mtestinal contents leaves the body of its host. 
 
 The change into the pupal stage is made either in the horse manure 
 or after the larva has burrowed for a short distance into the ground. 
 At the termination of pupation, which lasts from four to six weeks, the 
 matured fly creeps out, and, after fertilization by the male, proceeds to 
 deposit ova for another generation. 
 
 Tabular Review of Life History of Gastrophilus Intestinalis 
 L Adult Flv. — (August.) 
 
 I 
 
 2. Eggs . — Attached to hairs of horse (Aug. and Sept.); 
 
 I approximately 2 weeks. 
 
 3. Young Larvae. — Upon or within mucosa of horse's 
 
 I mouth. 
 
 4. Larvae (Bots). — Attached to wall of horse's stomach. 
 
 I Stages 3 and 4 approximateh' 10 
 
 I months. 
 
 5. Pupae . — Free (June) ; approximately 6 weeks. 
 
 6. Adult Fly.— (August.) 
 
 Effect. — The degree of injury due to the presence of the larvae of 
 this botfl}' will depend upon their number and location. .That the 
 stomach may be invaded by a considerable number of bots without 
 apparent disturbance to this organ is probably due to the fact that they 
 most commonly attach to the esophageal portion, this region of the 
 horse's stomach havhig a less important part in the function of digestion 
 
56 PARASITES OF THE DOMESTIC ANIMALS 
 
 than that toward the pyloris. Where they occupy the glandular right 
 half, especially if in large numbers, they interfere with the digestive 
 secretion and its proper contact with the gastric contents. In excep- 
 tional cases they may be sufficiently numerous about the pyloris to 
 form an obstruction to the passage of food material into the small intes- 
 tine; or even the duodenum itself may be invaded. Under these latter 
 conditions the larvae bring about nutritive disturbances and may cause 
 attacks of acute indigestion with its accompanying manifestations of 
 pain. When we consider, however, the large number of horses essentially 
 harboring the larvae of the horse botfly, as indicated by the widespread 
 prevalence of the insect, we must conclude that they are comparatively 
 inoffensive, for in most cases there is an entire absence of any apparent 
 disturbance and, with the exception of the voiding of the bots, nothing 
 during the life of the animal which would lead to suspicion of their 
 presence. 
 
 Treatment. — The larv« of Gastrophilus are so resistant that treat- 
 ment having in view their destruction or expulsion has been generally 
 unsatisfactory. Such agents as preparations of tar, benzine and turpen- 
 tine, which are sometimes used for this purpose, add irritation to an 
 already irritated gastric mucosa and, for this reason, in connection with 
 their general ineffectiveness, the advisability of their use is questionable. 
 AVhere the presence of the bots in sufficient numbers to cause disturbance 
 to the health of the animal is suspected, gastric irritation may be allayed 
 to some extent by feeding mucilaginous materials, such as flaxseed meal. 
 Hay in such cases is best fed chopped, and a substantial nutritive diet 
 should be looked to as compensatory to the loss of nutriment. 
 
 A treatment recommended by Peroncito and Bosso (1894) consists 
 in the administration of carbon bisulphide to adult horses in gelatin 
 capsules, each containing 8 to 12 grams (2 to 3 drams). After fasting for 
 twelve to twenty hours, the horse is given one capsule ; after one hour a 
 second capsule is given, and after another hour a third. As carbon 
 bisulphide is strongly irritant, care should be taken in the administration 
 of the capsules that the cap does not become detached and that they do 
 not become crushed in the mouth. 
 
 In so far as clinical observation can determine the presence of bots, or 
 lead to the conclusion that a remedy has caused the expulsion of any 
 considerable number of them in proportion to the infestation, this treat- 
 ment is said to be generally satisfactory. It seems reasonable to con- 
 clude that an agent sufficiently active to cause the expulsion of these 
 robust larvae from their secure attachment would have a severely irritant 
 effect upon the gastric mucosa, though this membrane of the stomach 
 appears to have a greater tolerance for such assaults than that of other 
 regions of the alimentary tract. 
 
DIPTEROUS LARV.E 57 
 
 Gastrophilus Hemorrhoidalis 
 
 The red-tailed botfly.— CEstridse (p. 53). Somewhat smaller than 
 6'. intestinalis. Dark brown color, yellowish hairs upon the face; trans- 
 verse black band upon thorax. The abdomen is covered with fine hairs 
 which in the middle are dai-k and posteriorly oranp;e-red. The wings are 
 clear. 
 
 This species of horse botfl}^ is found in common with (t. intestinalis in 
 North America and Europe. 
 
 The females attach their ova to the hairs of the horse, preferably 
 those about the lips. The hatched larvae cause an irritation which 
 impels the horse to pass its tongue about its lips, thus carrying the 
 parasite into the mouth. In other respects its life history is essentially 
 the same as that of G. intestinalis. The larvae differ from those of the 
 latter in being somewhat smaller and in their dark-red color. There is 
 also some difference in their habitat in that they attach usually to the 
 pyloric portion of the stomach, and when fully developed pass on to the 
 rectum where they remain for some time, assuming a green color before 
 l)eing voided. 
 
 Effect. — The presence of the larvae of this fly in considerable num- 
 bers in the folds of the i-ectal mucous membrane may cause an anno\'ing 
 irritation, inducing violent efforts at defecation. Such cases, however, 
 are extremely rare, and, as a rule, little or no evidence is given by the 
 animal of their presence. 
 
 Gastrophilus nasalis. — (EstricUe (p. 53). This species, connnonly 
 called the chin fly, is about 1 cm. ('Vs of an inch) in length. The body is 
 hairy and yellowish red in color. The wings are without spots. 
 
 Law describes the larvae as "furnished with a row of spines on each 
 ring from the second to the ninth on the dorsal surface, and as far as the 
 tenth on the ventral. There is an unarmed part in the center of the 
 eighth and ninth rings on the dorsal surface." 
 
 The fly deposits its eggs about the lips and nostrils. Th<> larvae attach 
 to the mucosa of the upper part of the small intestine. 
 
 Fitch states (1918), as to New York State, that from examination of 
 the larvae it would seem that Gastrophilus nasalis is quite as frequent 
 as G. intestinalis. 
 
 Hypoderma Lixeata axd H. Bovis 
 
 The ox botflies; warble flies (Fig. 29).— CEstridae (p. 53). Hypodernia 
 lineata is about five-eights of an inch m length. The general color is 
 black; body more or less covered with hairs. The front, sides, and back 
 of the head, sides of thorax, and last segment of the abdomen are covered 
 with long yellowish white hairs. 
 
 This fly is found in all parts of the United States, but more especially 
 
58 
 
 PARASITES OF THE DOMESTIC ANIIVLVLS 
 
 ill the southern portion as far north as Illinois, Iowa, and Nebraska. 
 It makes its appearance in the spring or earty summer and is at once 
 attracted to cattle, depositmg its eggs on the hairs, frequently upon 
 those about the heel, a habit which gives to the ^y its southwestern 
 name "heel-fl}'." 
 
 The entire length of the egg is 1 mm. and its width 0.2 mm. In color 
 it is a yellowish white. The eggs are firmly attached to the hairs by 
 
 means of a clasping projec- 
 tion which connects with 
 the egg proper by a short 
 pedicle (Fig. 31). Usually 
 they are deposited upon 
 the hairs in groups of four 
 to six. 
 
 Hypoderma Bovis. — (Es- 
 tridse (p. 53). This species 
 is commonly referred to as 
 the European warble fl.y, 
 though it occurs also in 
 Canada and the United 
 States. It is, in fact, said 
 to be more common in some 
 pai-ts of this country than 
 H. lineata. Its length, ex- 
 clusive of the ovipositor, as 
 stated by Neumann, is 13 
 to 15 mm. {}/2 to % of an 
 inch), which is 1 to 2 mm. 
 longer than H. lineata. The 
 general color is black, face 
 gra}^; abdomen black; head, 
 thorax, and abdomen hairy. 
 The hairs from the base to the tip of the abdomen vary in color from 
 white or 3^ellow to black; orange red at posterior third. The legs are 
 black, yellow at their terminations; wings somewhat brown. 
 
 As to the differentiation of the larvse of these two species, Herms 
 writes as follows: "The life history of the two species is very similar. 
 The larvse are different enough to distinguish them readily. The fully 
 grown larva of H. bovis is longer, 27 to 28 mm., H. lineata about 25 mm. 
 The two species are distinguished on the basis of their spiny armature. 
 In H. lineata each segment of the larva is provided with spines except 
 the last, the ring upon which the stigmata are located, while in H. bovis 
 all except the last two are armored." 
 
 Life History. — Dr. Cooper Curtice, from his researches in 1890, 
 
 Fig. 29. — Hj^poderma lineata (after Osborn, from 
 Insect Life, Bui. No. 5, Bureau of Entomology, U. S. 
 Dept. of Agr.). 
 
DIPTEROUS LARV.E 
 
 59 
 
 
 k: 
 
 /yp /^ 
 
 ^p\\^\\ 
 
 ^^^ 
 
 yi \^ 
 
 J 
 
 \ 
 
 concluded that the larv£e of Hypoderma lineata are taken into the mouths 
 
 of cattle by licking the parts where the eggs are attached, the eggs under 
 
 this influence hatching at once. 
 
 From the mouth the larva, according 
 
 to this investigator, is carried to the 
 
 esophagus, the walls of which it 
 
 penetrates. While lodged in the 
 
 esophagus it molts, and the body be- 
 comes ciuite smooth. For a period 
 
 of several months thereafter it 
 
 wanders through the connective 
 
 tissue beneath the skin or between 
 
 muscles, and ultimately reaches a 
 
 point beneath the skin of the back. 
 
 Here the larva again molts and the 
 
 spiny processes reappear upon its 
 
 body. It now cuts a small opening 
 
 through the skin, and places its 
 
 anal spiracle near this orifice in order to get air. In this location the 
 
 larva lives upon the products of the inflammation which its presence 
 
 sets up, such as bloody serous exudate and pus. It now develops rapidly 
 
 and again. molts, at which time the grub is fat, yellowish-white in color, 
 and an inch or more in length. Reaching the 
 maturit}^ of its larval period (Fig. 32, g and i), 
 which lasts about ten months, it works its wa}' 
 out of the orifice at the summit of the tumor 
 and drops to the ground, into which it may 
 burrow for a short distance. Here it enters 
 upon the pupal stage, the hardened larval skin 
 becoming the protecting case for the pupa 
 within. After about four to six weeks of 
 pupation the adult fly escapes by pu.shing off 
 the cap at the end of the pupal case. 
 
 Dr. Sevmour Had wen, in notes on ''The 
 
 Fig. 30. — Hypoderma Ijovis (after Os- 
 born, from Brauer, Bui. No. 5, Bureau of 
 Entomology, U. S. Dept. of Agr.). 
 
 PfFiG 
 
 T Life History of Hypoderma bovis and H. linea- 
 turn'' based on observations made at Agassiz, 
 
 -Eggs of Hypo- 
 derma lineata, showing clasp- 
 like processes — much enlarged 
 (after Osborn, Bui. No. 5, 
 Bureau of Entomology, U. S. 
 Dept. of Agr.). 
 
 British Columbia (Journal of the American 
 
 Veterinary Medical Association, June, 1917) 
 
 summarizes as follows: 
 
 '^Hypoderma lineatum lays its eggs as early 
 
 as April 15th, but the usual laying period 
 is during the month of May. At Agassiz they have never been cap- 
 tured later than May 30th. Hypoderma bovis (Fig. 30) begins in the 
 early part of June and continues up to the beginning of August. 
 
60 PARASITES OF THE DOMESTIC ANIMALS 
 
 Between the last appearances of H. lineatum and the first of H. hovis 
 there is usually a period of ten days when the cattle are immune from 
 attack of either species. H. hovis frightens cattle much more than 
 H. lineatum. The eggs take about a week to hatch; the larvae bore 
 through the skin in the coarser porous parts, taking several hours in the 
 process; at this stage they are rather less than 1 nun. long. The lesions 
 resulting from this penetration are caused partly l)y bacterial invasion 
 and partly by anaphylactic reactions; those produced by H. lineatum 
 being more severe. For the skin lesions I have proposed the name of 
 hypodermal rash. At this point there is a hiatus in the life history as it 
 is not positively known how the larvae reach the esophagus, where they 
 are subsequently found, most likely in the loose connective tissues under 
 the skin up to the region of the throat and into the esophagus where the 
 muscles bifurcate. Passing down the esophagus they follow the sub- 
 mucosa and are almost always found lying along the long axis of the 
 canal. Whilst in the esophagus small edematous swellings are found 
 surrounding the grubs, these are sterile and are anaphylactic in char- 
 acter, the exudate contains large numbers of eosinophilic leucocytes but 
 no pus cells. The earliest record made at Agassiz was on August 15th, 
 when a larva 3.4 mm. was found and several slightly larger. According 
 to Carpenter, continental observers have found them smaller than this. 
 H. lineatum makes its appearance in the backs of cattle about Decem- 
 ber 15th and H. bovis about a month later. The larvae at this time have 
 grown to about 1.5 cm. and are of the same size in the neural canal and 
 under the skin which they have just reached. At this age it is difficult 
 to separate the larvae of the two species, but Mr. F. C. Bishopp has, I 
 believe, discovered good distinguishing marks between the species. The 
 life histories overlap at this period making it difficult to follow the 
 migration, but in the latter part of the season (the middle of March) 
 the last larvae to leave the gullet are at the paunch end. They pass out 
 under the pleura and go to the neural canal either up the crura of the 
 diaphragm or up the posterior border of the ribs, entering the canal by 
 the posterior foramen, from there they descend the canal under the 
 dura mater, emerge again through the foramen and reach the back, 
 forming the characteristic swellings commonly called warbles. The 
 larvae follow connective tissue exclusively and no larvae have been dis- 
 covered in muscular tissue. The mature larvae leave the animals' backs 
 from the early part of the year up to the first days of July. The periods 
 for the two species have not been fully worked out, but judging from 
 what records we have of the pupal period and the time of year the flies 
 are about, H. lineatum begins to emerge in February and finishes about 
 May 1st. H. bonis begins about May 1st and ends approximately on 
 July 1st. The average pupal period for H. bovis is 32.5 days and for 
 H. lineatum a little less. The duration of the life of the flies is short 
 
DIPTEROUS LARV.E 
 
 61 
 
 re . T. -^ 
 
62 PARASITES OF THE DOMESTIC ANIMALS 
 
 seeing that they cannot feed. This hfe history apphes to Agassiz, 
 British Cohunbia; doubtless in other countries variations will be noticed, 
 but the period spent by the larvae within the host must be of the same 
 duration, seeing that animals' temperatures are the same the world over." 
 
 Effect. — Cattle seem to be much annoyed by the attacks of these 
 flies in depositing their eggs, and in the endeavor to escape will often 
 enter mire holes or injure themselves in other ways. Probably the most 
 important damage from the insect is that to hides, these being dis- 
 counted from twenty-five to fifty per cent, according to the number of 
 punctures by the grubs. 
 
 Treatment. — Treatment is best applied in the months of January 
 and February when the grubs have become sufficiently developed that 
 the small tumors in which they are lodged may be felt by running the 
 hand along the back of the animal. The application at this time of a 
 little kerosene or mercurial ointment to the summit of the swelling will 
 destroy the grub. By March the tumors may be distinctly seen as 
 prominent lumps upon the skin of the back. The orifice at the summit is 
 now large enough to permit of the forcing out of the grub by careful 
 pressure. Grubs thus removed should be at once destroyed to prevent 
 the possibility of their finding favorable conditions for development 
 into the adult fly. 
 
 QllsTRUS Ovis 
 
 The sheep botfly (Fig. 33, 1 and 2) .— CEstridce (p. 53). About one- 
 half an inch in length ; yellowish-gray color ; slightly hairy. The abdomen 
 is spotted with white and yellow; posterior portion covered with fine 
 hairs. The wings are transparent. 
 
 Occurrence and Life History. — This species is of world-wide dis- 
 tribution, and is the most important insect pest with which sheepmen 
 have to deal. The flies make their appearance with the coming of warm 
 weather from early June to July, like other (Estridae, flying on bright 
 and warm days and ceasing their activities about the month of October. 
 The female, which is difficult to observe owing to its small size and rapid 
 flight, deposits living larvae in the nostrils of the sheep. At this time 
 the larva is creamy-white in color and about one-sixteenth of an inch 
 in length (Fig. 33, 6). Later it becomes darker, and at maturitj^ reaches 
 a length of about three-quarters of an inch (Fig. 33, 4 and 5). Upon the 
 cephalic segment there are two hooklets the points of which are curved 
 downward and backward. With the aid of these the larva at once pro- 
 ceeds to work its way upward through the nasal passages until it reaches 
 the frontal sinuses where it attaches by its hooklets to the lining mem- 
 brane. Here it feeds upon mucus and serous exudate induced by the 
 irritation of its presence. 
 
 The larva remains in this location about ten months, at the end 
 
c. 
 
 2 
 
 " 1 
 
 ^ 
 
 pill 
 
 i 
 
 DIPTEROUS LARV.E 63 
 
 of which tmie, having reached its larval maturity, it detaches from the 
 mucous membrane and passes to the nasal passages from which it is 
 expelled by the violent sneezing which it excites in its host. Having 
 reached the ground, it quickly buries itself, contracts withm its smooth 
 dark shell, and enters upon its pupal stage (Fig. 33, 3). After from four 
 to six weeks of pupation the mature insect emerges. 
 
 Effect. — Both sheep and goats suffer from the attacks of this fly. 
 Sheep are especially disturbed by it, and in their efforts to avoid its 
 attack will toss the head, thrust the nose into the ground, or dash about 
 in frenzy. The grubs cause much 
 irritation to the sensitive mem- 
 brane which lines the cavities of 
 the head both by the booklets 
 with which they make their at- 
 tachment and by the spines cov- 
 ering the ventral region. Further- 
 more, if numerous, and the mucus 
 secreted is not sufficient for their 
 nourishment, the grubs will feed 
 upon the membrane itself. The 
 disturbance to the host will be 
 manifest accordmg to the number 
 of grubs present; if there are but 
 few, there may be no more than 
 a slight catarrhal discharge with 
 occasional sneezuig. In heavy 
 infestation there is a profuse 
 muco-purulent nasal discharge with frequent sneezing and tossing of the 
 head, the respiratory passages in some cases becoming so filled as to 
 bring the animal to the verge of suffocation. The appetite is lost, and 
 emaciation and weakness may progress until there is inability to rise, 
 death in such cases soon following. 
 
 Tabular Review of Life History of (Estrus Ovis 
 
 1. Adult Fly. — (June to October.) 
 
 I 
 
 2. Hatched Embryos. — Deposited in nostrils of sheep. 
 
 \ 
 
 3. Larvse. — Attached to lining membrane of sinuses of 
 
 I sheep's head. Stages 2 and 3 approximately 
 
 I 103^ months. 
 
 4. Pupse. — Free; approximately 6 weeks. 
 
 Fig. 33. — CEstrus ovis: 1 and 2, adult fly; 
 3, pupa; 4, full-grown larva, dorsal view; 
 5, same, ventral view; 6, young larva. 1 and 
 2 natural size, the others enlarged (after 
 Osborn, from Riley, Bui. No. 5, Bureau of 
 Entomology, U. S. Dept. of Agr.). 
 
 5. Adult Fly 
 
64 PARASITES OF THE DOMESTIC ANIMALS 
 
 Treatment. — The location of the grubs and the tortuous extremity 
 of the canals leading to such regions render the application of remedies 
 looking to their dislodgment but partly effective at best. Benzene ap- 
 plied by lifting the head and pouring a teaspoonful into each nostril, 
 has been recommended. As one side is treated the head should be 
 held elevated and the nostril held shut for half a minute. The remedy 
 is then likewise applied to the other side. In severe cases a few of the 
 grubs ma.y be dislodged by a feather dipped in turpentine which is 
 passed as far as possible up the nasal passage and rotated so as to apply 
 it to as much of the surface as can be reached. Valuable breeding 
 animals showing severe infestation may be treated by trephining the 
 sinuses. 
 
 Prevention. — To prevent the fly from depositing its larvae the noses 
 of the sheep ma}^ be smeared with tar. For the convenient application 
 of this preventive remedy many flock owners use salt logs in their pas- 
 tures. Into these logs two-inch holes are bored at intervals of about 
 six inches in each of which a little "salt is kept during the fly season. 
 Two or three times a week tar is smeared with a brush around these 
 holes in such manner as to smear the noses of the sheep as they en- 
 deavor to reach the salt. The logs should be of sufficient length to enable 
 all the sheep to get to them. 
 
CHAPTER VII 
 THE FLEAS 
 
 Order II. Siphonaptera. — Insecta (p. 15). Members of this order 
 have the body compressed laterally, and the color is usually dark brown. 
 The head is small, generally bearing a single ocellus on each side, com- 
 pound eyes are absent. The mouth parts are suctorial but differ from 
 those of the order Diptera in that the true haustellum is lacking, the 
 sucking structure consisting of the ventrally grooved labrum and the 
 two mandibles, which form a half-open tube (Fig. 36, e and £). The 
 maxillae are sharp and serve to puncture the skin. The three thoracic 
 segments are distinct, each bearing a pair of well-developed legs, the 
 posterior pair being especially long, powerful, and adapted for leaping, 
 which is the principal mode of progression. 
 
 Metamorphosis is complete. The larvae are long, slender, without 
 feet, and somewhat hairy. When mature the larva spins a cocoon and 
 enters upon a distinct pupal stage. During this stage the pupa takes 
 the form of the adult with the appendages enveloped in a hard pupal 
 case. At no stage in the metamorphosis are there traces of the supposed 
 ancestral wings. It is probable, however, that the fleas have descended 
 from winged forms, and they are usually considered as being closely 
 related to the Diptera. 
 
 There are many species of fleas, most of them inhabiting various wild 
 birds and mammals. It will be sufficient here to consider the following 
 three of the family Pulicidse : 
 
 1. Ctenocephahis cam's, the dog flea. 
 
 2. Ctenocephahis felis, the cat flea. 
 
 3. Pulex irritans, the human flea. 
 
 The two species of Ctenocephahis can easily be distinguished from 
 Pulex by the presence in the former of comb-like spines on the lower 
 margin of the head and on the hinder margin of the prothorax. These 
 spines are dark colored, stout and closely placed (Figs. 34 and 35). 
 The dog and cat flea have long been placed together under the one 
 species Pulex serraticeps, but a later classification recognizes a specific 
 difference based principally upon the form of the head. In Ctenoceph- 
 alus cams the head, when seen from the side, is rounded in front and 
 somewhat less than t\vice as long as high. The head of C. felis, seen from 
 the side, is more acute angled in front and is long, being fully twice as 
 long as high. The head of Pulex irritans, with its absence of spines, is 
 
66 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 more regularly rounded than that of the dog flea, and bears two bristles, 
 one low, in the vicinity of the maxilla, the other below the eye. 
 
 Life History.— In their life history the fleas undergo a complete 
 metamorphosis. The eggs are oval, 0.5 mm. in length, and in color 
 pearly white (Fig. 36, a). They are deposited loosely and unattached 
 among the hairs of the host, dropping off readily during the movements 
 of the animal. The period required for the eggs to incubate may be 
 from one to four days or longer, depending much upon temperature. 
 
 The larvae are white, elongate, apodal, and have thirteen segments, 
 each provided with bristles (Fig. 37) . They are very active and, avoiding 
 the light in every way possible, seek such shelter as is afforded by crev- 
 
 FiG. 34. — The dog flea, anterior 
 portion of body (after Osborn, Bui. 
 No. 5, Bureau of Entomology, 
 U. S. Dept. of Agr.). 
 
 Fig. 35. — The human flea 
 (Pulex irritans), anterior por- 
 tion of body (after Osborn, 
 Bui. No. 5, Bureau of Entomol- 
 ogy, U. S. Dept. of Agr.). 
 
 ices in the floor, carpets, rubbish, or bedding of kennels, such material 
 containing fecal or other organic matter upon which they feed, being 
 especially favorable for their development. 
 
 The length of the larval stage varies considerably under the influence 
 of temperature. It may be from seven to thirty days, during which 
 time there are two molts. Just before entering the pupal stage the 
 larva spins a white silken cocoon within which the pupa (Fig. 36, c) is 
 lodged (Fig. 36, b). Transformation to the fully developed imago — 
 again depending upon temperature and moisture — will occupy from 
 five to ten days. The time required for the development of the mature 
 insect from the deposited egg is, therefore, from thirteen to forty-four 
 days, with twenty-eight days as probal^ly a fair average under our 
 ordinary climatic conditions. 
 
 Habits and Relation to Disease. — Nearly all species of fleas have 
 some one host upon which they prefer to live, but they will often live 
 and thrive upon other animals. The human flea will infest dogs and 
 
THE FLEAS 
 
 67 
 
PARASITES OF THE DOMESTIC ANIMALS 
 
 cats and may be found upon these animals in common with the species 
 usually infesting them. As a pest of the household the human flea is 
 more commonly found in Europe and the western part of the United 
 States, while in the eastern United States houses may be rendered un- 
 inhabitable for a time by the presence of the dog and cat flea. 
 
 Fleas are of importance as tormenting parasites of man and domestic 
 animals, but of late have received greater attention in the field of med- 
 icine as carriers of disease. It is known that bubonic plague, which 
 during recent years has made its appearance on the Pacific and Gulf 
 coasts of the United States, is transmitted by these insects. Tseniasis 
 of the dog, due to the presence of Dipylidium cani- 
 num, may be conve\^ed to humans as well as to dogs 
 through the intermediation of the dog flea, while a 
 disease of infants known as kala azar, occurring 
 in countries bordering on the Mediterranean, is 
 thought to be transmitted by fleas. 
 
 Usual Hosts. — Our larger domestic animals, such 
 as horses, cattle, and sheep, are rarely attacked b,y 
 fleas. Hogs are somewhat less free from them, but, 
 if occurrmg in these animals, the infestation is most 
 always light and causes little disturbance. Dogs, 
 cats, rabbits, fowls, and pigeons are especial ob- 
 jects of attack. Yomig dogs and those chamed 
 up are more likely to be infested as they live amid 
 conditions favorable to the breedmg of the insects 
 from the laying of the eggs to their full develop- 
 ment, which is particularl}-^ favored by litter and 
 wooden floors. Unlike lice, fleas do not pass their 
 entire cycle upon the host, nor are they limited to a particular species. 
 The dog and cat flea will readily attack man, and in this country is more 
 troublesome to him than the human flea. 
 
 Vitality. — When feeding upon blood, which is the only food taken 
 by the adults, fleas will live from several months to a year. Off a host 
 the dog and cat flea will not survive longer than about two months, the 
 length of life under such conditions being considerably shortened if the 
 w^eather be hot and dr}-. 
 
 Treatment and Control. — Where habitations are infested by these 
 insects it is of first importance as a measure of control that dogs, cats, 
 and other domesticated animals kept about the premises receive treat- 
 ment that will rid them of the parasites. The harbormg animals maj' 
 be dusted with Persian insect powder (pyrethrum), the remedy being 
 applied liberally and driven well under the hair, preferably after the 
 skin has been slightl.y moistened. This will not kill the fleas but will 
 stupify them, in which condition they will drop off or may be combed 
 
 Fig. 37.— Pulex irri- 
 tans, larva. 
 
THE FLEAS 69 
 
 from the hairs. It is well to place the animal while undergoing this 
 treatment upon a large sheet of paper which may later be rolled up and 
 burned with the collected fleas. In severe cases creolin or lysol solutions 
 in two per cent, strength may be used. Quite effectual, but more expen- 
 sive, is the preparation consisting of Peruvian balsam, ten parts; creolin, 
 two parts; alcohol, one hundred parts which is recommended in the 
 treatment for lice and scab mites upon small animals. In the treatment 
 of cats, puppies, and chicks the powder is preferable to the last men- 
 tioned preparations. 
 
 Following treatment animals should not ])e permitted to re-enter 
 their sleeping quarters until all litter has been removed and burned. 
 In order that this cleanhig up process may be effectual every detail 
 must be looked to. Collections of dirt and dust between floor boards 
 must be removed, as well as every particle of bedding or rubbish that 
 may harbor a flea brood. After this preparation the quarters should be 
 thoroughly cleaned with hot, soapy water and, when drj'^, sprayed with 
 kerosene or kerosene emulsion (formulae, page 48) as an additional pre- 
 caution. For kennels a bedding should be used which can be frequently 
 replaced, as shavings or straw. Carpet or matting should never be used 
 for this purpose. 
 
 Household Infestation. — In dealing with household infestation it is 
 first necessary to exclude flea-bearing animals from the premises or 
 destroy the adults which are producing the eggs upon these hosts. Flea 
 larvse find excellent conditions for development under tacked-down 
 carpets or matting and in spaces between floor boards. The floor 
 covering, whatever it may be, should be removed, beaten, and thor- 
 oughly aired. The floors may then be swept and the dust, which con- 
 tains many eggs and larvae, collected and burned. Kerosene should 
 then be applied with a mop in such manner that it will penetrate all 
 cracks and crevices in the floor and beneath the baseboards. Benzene 
 is often advised for this purpose, but, owing to the extreme danger of 
 ignition, its use, excepting under the most careful supervision, is not 
 to be recommended. 
 
 Following these eradicative measures the floor coverings may be re- 
 placed, but before doing so it is well, as an additional precaution, to 
 sprinkle the floors Avith pyrethrum powder. This will work into the 
 fabric and make the carpet or matting an unfavorable harbor for any 
 larvai or adults which may have escaped the eradicative measures. 
 Where the floors are oiled and rugs used instead of carpets or matting, 
 the problem of getting rid and keeping rid of such an infestation is much 
 lessened. 
 
CHAPTER VIII 
 
 THE LICE 
 
 There has been much disagreement among various authors as to the 
 systematic arrangement of the hce. The classification given here, if 
 faulty, will perhaps at least serve the purposes of this work until exacting 
 systematists have better settled the matter. 
 
 Order III. Siphunculata. — Insecta (p. 15). The Sucking Lice. — The 
 lice of the order Siphunculata have the suctorial mouth parts at the 
 anterior border of the head, the movable proboscis being formed of the 
 upper and lower lips (Fig. 38). Within this is the sucking-tube which is 
 projected beyond its sheath and buried in the skin when used to aspirate 
 blood. The eyes are two simple ocelli, one on each side. The antennae 
 are short. The thorax is usually broader but shorter than the head, with 
 indistinct division into three segments. The legs are short and thick, the 
 tarsi terminatrng in a single claw. There are no wings. The abdomen 
 is large and generally elliptical in outline. The last abdominal segment 
 is rounded in the male with an opening for the penis. Li the female 
 this segment is notched and has two small terminal appendages. The 
 female is from L5 to 5 mm. in length, the male somewhat smaller. 
 
 Life History. — The metamorphosis is incomplete. The young, which 
 leave the eggs by an operculum, have the shape of the adults but do not 
 acquire the adult color and consistency until after several molts. 
 
 jhe eggs as they are extruded from the female are glued fast to the 
 hairs of the host by means of a viscid secretion. In this position they 
 are commonh^ referred to as nits, which, with the aid of a hand glass, 
 will be observed to have somewhat the shape of a barrel with the at- 
 tached end rounded and a blunt free extremity (Fig. 40, e). 
 
 Hatching occurs in from five to six days, the young in general re- 
 sembling the adults excepting in size. They become mature in about 
 four weeks. 
 
 The sucking lice come into one family, the Pediculidse. All are per- 
 manent parasites, the entire life cycle being spent upon the host. All 
 are limited to a specific host, and will only accidentally inhabit a host of a 
 different species. Therefore if the host is known, the specific identity 
 of the parasite is readily determined. 
 
 The characteristics of the species are here given under their respective 
 host animals. It may be said of the sucking lice in general that the head 
 is inserted directly on the thorax, their antennae are five-segmented; the 
 
THE LICE 71 
 
 segments of the abdomen numlier eight or nine, and their tarsi are 
 terminated by a single claw. 
 
 Order IV. Mallophaga 
 
 The Biting Lice. — Insecta (p. 15). The members of the order of 
 biting lice resemble the sucking lice in general form, but differ from them 
 mainly in that they are nuich smaller and have the mouth parts adapted 
 for biting and mastication. They may be at once distinguished by the 
 head and mouth parts; the head is usually rounded, triangular, squared, 
 or crescent-shaped, and is broader than the thorax (Fig. 39). Upon the 
 under side of the head are located the mandibulate mouth pieces adapted 
 for cutting and feeding upon epidermic scales, hairs, feathers, and 
 other cutaneous products. The eyes are simple ocelli located back 
 of the short antennae and are often indistinct. The thorax is generally 
 narrow, the prothorax being distinct, the two posterior segments fused. 
 The legs are adapted for either clasping or running; in the first case the 
 tarsi terminate in a single claw (Philopterida?), in the second the tarsi 
 are long and terminate in two claws (Liotheidae). Wings are absent. 
 The abdomen is generally elliptical; it may be elongate, or short and 
 broad, approaching a globular outUne. Their relatively small size and 
 hard, flattened bodies facilitate their movement among the hairs close 
 to the body. 
 
 In their breeding habits and life history the Mallophaga agree with 
 the preceding order. 
 
 Although the order has been variously subdivided, it will be sufficient 
 here to place the biting lice according to their hosts in the two families 
 Philopteridse and Liotheidae, the former including the biting lice of 
 mammals and birds, the latter the lice of birds only. 
 
 Biting lice, like the suctorial, are limited to a specific host, which as a 
 uile they do not voluntarily leave unless it is to crawl upon another 
 host of the same species, in which case the migration is ordinarily ac- 
 complished when the bodies of the host animals are in contact. Lender 
 conditions of severe infestation among poultry some of the parasites 
 may pass to the roosts and nests and, by contact, even to the bod}' of a 
 mannnalian host, but they will not survive such migrations for more than 
 a few hours. 
 
 Pediculosis of Domestic IMammals 
 
 The condition commonly known as lousiness is medically referred to 
 as pediculosis, a term correctly applied whether the condition be due 
 to the presence of either the sucking or the biting species. The term 
 phthiriasis should properly be restricted to infestation with the genus 
 Phthirius in particular. 
 
 Lousiness is usually- accompanied by an unthrifty condition, not 
 
72 PARASITES OF THE DOMESTIC ANIMALS 
 
 necessarih' resulting from, but rather predisposing to the attack, the 
 reduction in the functional activity of the skin in such condition afford- 
 ing an inviting habitat for the parasites. Herbivorous animals which 
 have been kept for a prolonged period upon dry feed, as during the 
 winter months, are those most likely to be infested, lice rarely being 
 found upon these animals after they have been turned upon more 
 succulent food and the winter coat has been shed. 
 
 There is, in fact, little valid excuse for the presence of these parasites 
 upon our domestic animals at any time. Infestation is usually the 
 accompaniment of uncleanly, impoverished, and crowded conditions of 
 stabling or yarding. Well housed, well fed, and regularly groomed 
 animals offer no attractions to lice, and animals so cared for will not 
 have them. Excepting in accidental and transient incidents, their pres- 
 ence upon man or domesticated beast reflects upon man in either case. 
 
 Whether the degree of discomfort and injury to an animal due to the 
 presence of lice upon its l)ody is slight or serious in its consequences will 
 depend upon the number present and the group to which thej^ belong. 
 The sucking lice, piercing the skin and feeding upon the blood and 
 exudate, cause a much more intense pruritus than that occasioned by 
 the biting lice which, in their habit of feeding upon surface epidermic 
 products and debris, have more the nature of scavengers. 
 
 The presence of the lice, as well as their location, is indicated by the 
 pruritus, by their eggs or nits upon the hairs, and the debris of their 
 molts. The irritation of the itching and rubbing, together with the loss 
 of blood if suctorial lice are numerous, results in emaciation and general 
 unthriftiness of an animal likely to have ])een in poor condition before 
 becoming infested. 
 
 While the presence of lice may be unmistakably evident, it should 
 be made quite sure that there is not also present a form of acariasis. 
 Lice fi-equently invade animals suffering from scabies, and the pruritus, 
 with the accompanying scaly and scabby condition of the skin, may be 
 due to scab mites, which, minute and deeply located, may be readily 
 overlooked. The presence of these can only be determined with cer- 
 tainty by examination of epidermic scrapings from beneath the scabs. 
 For their detection and examination the microscope is necessai;;y'. They 
 are, however, often difficult to discover, and the material is best sub- 
 mitted to a laboratory for examination if such is available. More de- 
 tailed methods of diagnosis and treatment of this condition are given 
 elsewhere under the discussion of the scab mites. 
 
 Pediculosis of the Horse 
 
 Horses, mules, and asses harbor one species of sucking louse, Hcema- 
 topinus asini, and two species of biting lice, Trichodectes equi and T. 
 pilosus. 
 
THE LICE 
 
 73 
 
 38. — Hsematopinus 
 asini (after Osborn, from 
 Comstock. Bui. No.^ 5, 
 Bureau of Entomology, U. 
 S. Dept. of Agr.). 
 
 1. Haematopinus asini (H. macrocephalus).— PediciilidiB (p. 70). 
 Head long and narrow; antenna attached at lateral protuberances be- 
 hind which are notches lodging the eyes. Anterior to this the head is 
 more narrow with borders parallel, terminating 
 in a blunt point. The thorax is much shorter 
 than the head and widens posteriority. The 
 abdomen is oval, with stigmata placed in the 
 middle of lateral protuberances on the margins 
 of segments. The general color is yellow, the 
 thorax brownish. The female is 3 to 3.5 mm., 
 the male 2.5 mm. in length (Fig. 38). 
 
 2. Trichodectes equi (T. parumpilosus). Phil- 
 opteridie (p. 71). — Head slightly longer than 
 broad and semicircular in front of the antennae 
 which are set well back. The abdomen is oval 
 
 and bears eight trans- 
 verse dark bands, each 
 upon the anterior por- 
 tion of a segment and 
 extending from the 
 middle line about half- 
 way to the margin. 
 
 The general color of the abdomen is yellowish, 
 the head, thorax, and legs chestnut (Fig. 39). 
 3. Trichodectes pilosus. Philopteridae 
 (p. 71). — Somewhat smaller than the preced- 
 ing species. Head broader than long, rounded 
 in front, and slightly widened at the temples. 
 The anteimse are inserted well forward, almost 
 on a line with the head's anterior border, in 
 which respect it markedly differs from T. equi. 
 The abdomen tapers posteriorly and has upon 
 the middle ofthe first seven segments darkened 
 spots, less conspicuous than the bands simi- 
 larly located upon T. equi. The head, thorax, 
 legs, and abdomen are hairy on both surfaces. 
 The general color is yellow. 
 
 Pediculosis caused b}- suctorial lice upon the 
 horse is usuall}' located at the base of the mane 
 and forelock, and at the root of the tail. The hairs about these parts 
 are likely to be scant, broken, or the skin entirely denuded, due to 
 the rubbing against anything within reach. During the act of rubbing 
 the animal has a peculiar habit of protruding the upper lip, or, if in 
 reach of another animal, will gently bite it. 
 
 Fig. 39. — Trichodectes 
 parumpilosus (after Osborn, 
 Bui. Xo. 5, Bureau of Ento- 
 mology, U. S. Dept. of Agr.). 
 
74 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Biting lice are less common upon horses than suctorial. They are not 
 often found on the upper parts of the body, more frequently occupj'ing 
 the regions of the neck, breast, and between the fore and hind legs. 
 They cause less pruritus than the sucking lice, though the animals will 
 frequently rub bare places at the regions infested. Both forms may 
 coexist upon the same animal. 
 
 Pediculosis of the Ox 
 
 Two species of suctorial lice inhabit the ox, Hcematopinus eurysternus, 
 — the short-nosed ox louse, and Linognathus vituli, — the long-nosed ox 
 louse. Of the biting species there is but one, Trichodectes scalaris. 
 
 1. Haematopinus eurysternus. Pediculidse (p. 70). — Head relatively 
 short and broad, rounded in front; thorax about twice as wide as long, 
 
 Fig. 40. — Haematopinus eurysternus: a, female; b, rostrum; c, 
 ventral surface of the last segments of male; d, same of female; e, egg; 
 f, surface of same greatly enlarged (after Osborn, Bui. No. 5, Bureau 
 of Entomology, U. S. Dept. of Agr.). 
 
 widest posteriorly. The abdomen is oval and much larger than that of 
 the sucking louse of the horse. On the lateral margin of each abdominal 
 segment is a slightly colored tubercle. In the female two black blotches 
 are laterally located on the terminal segment. The general color is 
 yellowish gray. The female is 2 to 3 mm., the male 2 mm. in length 
 (Fig. 40). 
 
 2. Linognathus vituli (Haematopinus vituli). Pedicuhda? (p. 70). — 
 Somewhat smaller than the preceding. The head is long and narrow 
 and somewhat sunken in the thorax, as in a notch. The thorax is about 
 as broad as long. The abdomen, like the head, is long and narrow, 
 giving to the entire insect a long and slender appearance. The general 
 color is a deep chestnut. The female is 2.5 to 3 mm., the male 2 to 2.5 
 mm. in length (Fig. 41). 
 
THE LICE 
 
 75 
 
 This species is found upon calves, though it will also, — probably as 
 frequently, — infest adults. 
 
 3. Trichodectes scalaris. Philopterida^ (p. 71). — Head cone-shaped, 
 rounded at the temples and in front, about as broad at the temples as 
 long. The antennoe are inserted well back 
 and are usually directed backward. The al)- 
 domen is not so tapering as in the ])iting louse 
 of the horse, and the median spots are larger, 
 forming bands which are quite distinct. The 
 general color is white. It is somewhat smaller 
 than the species uifesting the horse (Fig. 42). 
 This is a very common and widely dis- 
 tributed species, frequently found upon cattle 
 in cohabitation with the sucking lice. 
 
 Pediculosis of 
 the ox, caused 
 by either the 
 short or long- 
 nosed species, 
 is most likely 
 to be found 
 about the ears, 
 
 base of the head, and along the dorsal 
 line of the neck, back, and loins. The 
 intense itching causes the animal to rub 
 against any convenient object, and there 
 is frequent licking of the parts which can 
 be reached with the lough tongue. As a 
 result of this rubbing large patches of 
 skin may be entirely denuded of hair, 
 and the skin itself in severe cases may 
 become pustular and scabby. 
 
 Contrary to what has been observed 
 in the horse, biting lice probably occur 
 more frequently upon the ox than the 
 sucking species, therefore lousiness of 
 cattle is usually accompanied by less 
 itching. As to their location the l)iting lice of cattle do not limit them- 
 selves, usually spreading to all parts of the body. They may frequently 
 be observed crawling out upon the hairs and, when one is removed and 
 examined with a hand glass, one or more hairs will often be found in the 
 clutch of its claws. 
 
 Fig. 41. — Hsematopinus 
 vituli: female, under surface 
 of last segments of abdomen 
 of same (after Osborn, Bui. 
 No. 5, Bureau of Entomol- 
 ogy, U. S. Dopt. of Agr.). 
 
 Fig. 42. — Trichodectes scalaris 
 (after Osborn, Bui. No. 5, Bureau 
 of Entomology, U. S. Dept. of 
 Agr.). 
 
76 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Pediculosis of the Sheep 
 
 This animal has one suctorial louse, — Litiognathus pedalis, and one 
 biting louse, — Trichodedes splicer ocephalus. 
 
 1. Linognathus pedalis (Hsematopinus pedalis). Pedicuhdae (p. 70). 
 — Has the same general shape as the short-nosed ox louse, but is 
 somewhat more slender. It is also much lighter in color, giving it a 
 somewhat immature appearance (Fig. 43). 
 
 Fig. 43. — Hsematopinus pedalis: a, adult female; b, ventral view of terminal seg- 
 ments of same; c, terminal segments of male; d, egg (after Osborn, Bui. No. 5, Bu- 
 reau of Entomology, U. S. Dept. of Agr.). 
 
 This species is rare. It is said to occur only where the hair is short 
 upon the legs and feet, especially about the dew-claws. It is from this 
 location that it gets its common name, "sheep-foot-louse." 
 
 2. Trichodectes sphaerocephalus. Philopterida (p. 71). — Head 
 broad as long, giving the rounded appearance from which the specific 
 name is derived. The abdomen is elliptical, each segment having a 
 median band which is somewhat rounded upon its anterior border. 
 The general color is white (Fig. 44). Of rather rare occurrence. 
 
 The common so-called "louse" of sheep is not a true louse, but the 
 degenerate fly Melophagus ovinus, described elsewhere under the par- 
 
THE LICE 77 
 
 asites of the order Diptera. Pediculosis, properly so called, is seldom 
 met with in sheep. While the sucking lice are localized to the lower 
 parts of the legs, the biting lice lie deep in the wool, close to the body, 
 seriousl}'- altering the fleece by cutting the fibers with 
 their mandibles. Their location makes the condition 
 rather a difficult one to contend with. 
 
 'Pediculosis of the Goat 
 
 Goats have one suctorial species, — Linognathus steno])- 
 sis. The biting louse, — Trichodectes climax, is fairly com- 
 mon and is the only species of this genus upon goats that 
 is well established. _Tn- 
 
 1. Linognathus stenopsis (Hsematopinus stenopsis). ehodeotes spha?- 
 Pediculidae (p. 70). — Head long, narrow, and rounded in rocephaius (af- 
 front; there are two lateral notches, below which are tf ^f °r„S!!I: 
 widened temples, r rom these the head narrows rapidl}' of Entomology, 
 and becomes deeply fitted into the thorax. The thorax U. s. Dcpt. of 
 is widest posteriorly where it is somewhat concaved upon ^^''' 
 
 the abdomen. The abdomen in outline is an elongated oval with stig- 
 mata near lateral margins of segments. The female is 2 mm.; the male 
 1.5 mm. in length. 
 
 2. Trichodectes climax. Philopteridse (p. 71). — Head quadrangular 
 in shape and broader than long. The abdomen is oval with median 
 dark bands upon the segments. The head and thorax are reddish 
 brown ; the abdomen is pale yellow. 
 
 During the winter months especially', goats are apt to harbor lice in 
 rather large numbers. As in other animals the sucking louse produces 
 the greater irritation. The skin ma}'^ become bare in places with numer- 
 ous inflamed and ulcerated areas covered with crusts. In Angora goats 
 especially, the biting louse causes a great depreciation from its habit of 
 cutting the hairs with its mandibles. 
 
 Pediculosis of the Hog 
 
 Domesticated and wild hogs have one species of louse, Hcematopinus 
 suis (H. urius). This is the largest known member of the suctorial 
 group. The head is very long and narrow, cone-shaped, and rounded 
 in front; just posterior to the attachments of the antennae are horn-like 
 protuberances, forming deep notches. The thorax is somewhat broader 
 than long; dark, transverse bands may be noted upon the legs. The 
 abdomen is oval in outline, with distinct segment borders; the stigmata 
 are upon prominent lateral protuberances. The thorax is brownish 
 red in color; the head and abdomen yellowish gray. The female is 5 
 mm.; the male 4 mm. in length (Fig. 45). 
 
 This louse is a very active blood sucker, living upon hogs of any age 
 
78 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 or condition and everywhere where these animals are found. The 
 intensity of the pruritus produced is proportionate to the parasite's 
 size, the skin, as they increase in nuniberS; becoming covered with 
 papules and scales. The constant itching and worry, which. seems to 
 
 be most severe at night, is evidenced 
 by the restlessness of the animals 
 and their violent scratching against 
 any available object. Such a con- 
 dition seriously interferes with the 
 growth and fattening of hogs, and 
 young pigs especially will often 
 succumb to loss of blood and ex- 
 tensive irritation and excoriation 
 of the skin. 
 
 Pediculosis of the Dog 
 
 Dogs have one sucking louse, 
 Linognathus piliferus and one biting 
 louse, Trichodectes latus. 
 
 1. Linognathus piliferus (Haema- 
 topinus piliferus). Pediculidae 
 (p. 70). — Head thick, about as wide 
 as long, rounded 
 in front. The 
 thorax anteri- 
 orly is but slightly wider than the head; abdomen 
 
 elongate oval in outline, the margins of the segments 
 
 appearing somewhat rounded ; stigmata marginal and 
 
 distinct. The general color is yellowish white. The 
 
 female is 2 mm. ; the male L5 mm. in length (Fig. 46). 
 2. Trichodectes latus. Philopteridae (p. 71). — 
 
 Entire insect broad and short; more than half as 
 
 broad as long. The head large, slightly rounded in 
 
 front, and broader than long. The abdomen of the 
 
 female is broad and somewhat globular in outline. 
 
 The median abdominal bands or spots are absent. 
 
 The general color is bright yellow (Fig. 47). 
 
 Dogs do not seem to be as seriously affected as Bureau of Entomoi- 
 
 other animals by the presence of lice. The sucking °^^' ^- ^- ^^p*' °^ 
 
 louse is the more tormenting, and is usually found 
 
 about the chin, under part of the neck, and breast, though, with the 
 
 biting louse, it may be found on any part of the body. The biting 
 
 species is most often found upon puppies. 
 
 The biting louse infesting dogs is particularly of medical interest in 
 
 Fig. 45. — Haematopinus suis (from 
 jDhotograph of mounted specimen, bv 
 Hoedt). 
 
 Fig. 46. — Haemato- 
 pinus piliferus (after 
 Osborn, Bui. No. 5, 
 
THE LICE 
 
 79 
 
 being a larval host of the common tapeworm of the dog, Dipylidium 
 cajiinum, as is also the dog flea, Ctenoceyhalus canis. Infection of the 
 louse by the larva {Cysticercus trichodedes) is readily brought about 
 through ingestion of the eggs of the tapeworm which may have col- 
 lected about the anus or in the litter of the kennel. 
 This tapeworm is occasionally found to be present in 
 the intestines of human beings, particularly children. 
 It is quite conceivable how such infestation might 
 occur in the fondling of lousy or flea-infested dogs, 
 especially if the person's food be about at the same 
 time to act as a vehicle for the insects containing the 
 larva. 
 
 Pediculosis of the Cat 
 
 Trichodectes subrostratus, the only louse harbored Fig. 47. — Tri- 
 by the cat, is about the same length as the biting louse ^'\°^f°^t1- ^^^^^ 
 of the dog (1 to 1.3 mm.), but is not so 
 broad, and is distinguished by its pointed 
 head, which is slightly longer than broad. 
 The abdomen is oval, with median bands. 
 The head and thorax are bright yellow in color, the abdo- 
 men whitish (Fig. 48). 
 
 Lousiness is not often met with in the cat; when it does 
 occur it is usually the accompaniment to a debilitated 
 condition in young animals. 
 
 (after Osborn, from 
 Denny, Bui. No. 5, 
 Bureau of Ento- 
 mology, U. S. Dept. 
 of Agr.). 
 
 Fig. 48.— 
 Trichodectes 
 subrostratus 
 (after Os- 
 born, Bui. 
 No. 5, Bu- 
 reau of En- 
 tomology, 
 U. S. Dept. 
 of Agr.). 
 
 Pediculosis of Man 
 
 Three species of pediculi infest man, Pediculus humanus 
 {P. capitis), the head louse, P. corporis (P. vestimenti), the 
 body louse, and Phtkirius pubis (P. inguinalis) the pubic 
 or so-called "crab-louse." 
 
 1. Pediculus humanis. Pedicuhdae (p. 70). — The head 
 is somewhat diamond-shaped, short, and about as broad 
 as long. The abdomen has seven distinct segments, each 
 
 bearing stigmata laterally placed. Color gray with darkened margins. 
 
 The color is said to vary from light to dark according to the color of 
 
 the skin or hair of the host. The female is 2.5 to 3 mm. ; the male about 
 
 2mm. in length. 
 
 2. Pediculus corporis. Pedicuhdae (p. 70). — Resembles preceding 
 species, of which it is regarded by some authorities as merely a variety. 
 It is slightly larger. The color is grayish-white. It lives upon the 
 clothing of its host, crawhng upon the body to feed. 
 
 3. Phthirius pubis. Pediculidae (p. 70). — Distinctly differs in ap- 
 pearance from the two preceding. The head is short and thick, fitting 
 
80 PARASITES OF THE DOMESTIC ANIMALS 
 
 into a broad concavity in the thorax. The thorax is broad and appar- 
 ently fused with the abdomen, the two forming a somewhat heart- 
 shaped body with base anterior. The first pair of legs is much more 
 slender than the second and third which are stout and terminated by 
 powerful claws fitted for clasping the hairs. The female measures about 
 1.5 mm.; the male about 1 mm. in length. It infests the hairs of the 
 pubic region and of the armpits, rarely passing to other parts. 
 
 Of these three species Pediculus humanus is the most widely dis- 
 tributed. 
 
 Pediculosis, Control and Treatment 
 
 Contagion in pediculosis is due to the rapid succession of generations 
 of lice, their passage from host to host being facilitated by close associa- 
 tion, grooming utensils, blankets, harness, bedding, etc. It is possible 
 for domestic animals of different species to infect each other. Such 
 migrations, however, are usually of an accidental nature, and the 
 parasites will not as a rule remain to multiply upon a host foreign to 
 them. 
 
 Long hair, especially if combined with unclean conditions, predis- 
 poses to lousiness. If in addition there is debihty, the etiologic factors 
 become ideal. Plenty of nutritive food and a thorough cleaning up of 
 animals and their surroundings are, therefore, essential to success, what- 
 ever measures of eradication may be appHed. 
 
 After the removal and burning of litter the stables, kennels, etc., may 
 be treated with boiling water and afterward whitewashed or washed with 
 a three to five per cent, creolin solution. For spraying interiors an 
 emulsion of kerosene (formuhie, page 48), or the lime-sulphur prepara- 
 tion (page 125) may be used. 
 
 Clipping of long-haired animals, which may include the horse and 
 ox, greatly simplifies their treatment. The Melophagus infesting sheep 
 is removed with the fleece at time of shearing, the anunal soon ridding 
 itself of any which may have remained upon the skin. 
 
 Among the considerable number of insecticide agents used upon the 
 bodies of infested animals but one or two of those most effectual and 
 most commonl}^ emploj^ed need be mentioned here. A decoction of 
 tobacco, one ounce to the quart of water, as a local application answers 
 well for all animals. In using this preparation the possibihty of nicotine 
 poisoning should be kept in mind. Large areas of the body should not 
 be dressed at the same time. 
 
 Horses may be treated with creolin two to three per cent., or kerosene 
 emulsion. Brushes and combs, after having been disinfected by scald- 
 ing, may have a Httle kerosene sprinkled upon them as thej^ are used. 
 Preparations of kerosene should not be applied to sweating animals or 
 while they are exposed to hot sunshine. Friction with fatty substances, 
 
THE LICE 81 
 
 as linseed oil, will kill by asphyxia lice with which it comes in contact. 
 This treatment is more effectual if kerosene be shaken up with the oil 
 in the proportion of one of the former to two of the latter. A mixture of 
 kerosene, sulphur, and lard, equal parts, is also quite useful for this pur- 
 pose. 
 
 These treatments will apply to cattle as well as to horses. Where 
 large numbers of cattle are affected resort must be had to spraying with 
 kerosene emulsion or dipping. For the latter purpose ordinary sheep 
 dip or a lime-and-sulphur preparation may be used. 
 
 The large sucking louse of the hog is found principally inside, behind, 
 and in front of the ears, on the breast, and on the inner side of the el- 
 bows. For this animal the stronger preparations of the insecticides 
 should be used, as creolin five per cent, or kerosene and oil equal parts. 
 The kerosene, sulphur, and lard mixture is quite a suitable one for these 
 animals. It is well also to treat their wallows with a three to five per 
 cent, solution of creolin. 
 
 For dogs creolin in two per cent, strength is quite satisfactory. Long- 
 haired dogs, especially if heavily infested, should be clipped before 
 treatment. For small house animals, as toj^ dogs and cats, pyrethrum 
 powder, apphed to the moistened skin as for fleas, is most suitable. 
 
 Whatever insecticide is used it is well to apply vinegar in conjunction 
 with it. This may be added to the fluid preparations in the proportion of 
 about ten ounces to the quart, or it may be applied separately diluted 
 with twice its quantity of water. The vinegar has a destructive action 
 upon the eggs which may survive the ordinary remedies used to destroy 
 the insects. 
 
 Sodium fluoride, which is recommended in the treatment of lice of 
 poultry, all of which are biting lice, should also be effective for the biting 
 lice of mammals, though experience with it up to the present time is not 
 sufficient to have established its value in such cases. In its application 
 it should be rubl)ed into the hair over all parts of the body. The treat- 
 ment is only applicaljle to biting lice. 
 
 All measures used for the eradication of lice, whether in the quarters 
 or upon the bodies of their hosts, should be repeated at least three times 
 at intervals of eight to ten days. This is necessary to destroy the hce 
 which may emerge from remaining eggs. 
 
CHAPTER IX 
 
 LICE OF POULTRY. THE BEDBUG 
 
 Birds under the usual conditions of domestication are especially- 
 prone to lousiness; there are, in fact, few fowls entirely free from them. 
 Though, relative to their numbers, lice upon poultry probably do less 
 harm than the blood-sucking ticks, their rapid multiplication, and the 
 fact that they pass their entire cycle upon the bodies of their hosts, 
 make it probable that any degree of infestation will become a destruc- 
 tive nuisance. The constant annoyance due to their crawling upon 
 the skin and among the feathers, with the energy expended in the efforts 
 to be rid of them, causes fowl to droop and become ready victims to other 
 diseases commonly affecting poultry. Flesh and egg production, under 
 such conditions, must essentially be retarded to a degree commensurate 
 to the infestation. 
 
 Young chicks are especially apt to succumb. The}^ give evidence of 
 the presence of lice by drowsiness, refusal to eat, and an emaciated 
 body. The symptoms are generally accompanied by a loss of feathers, 
 especially about the head and lower part of the neck. Chickens hatched 
 in an incubator should be free from them, and they will remain so unless 
 placed with a lousy hen or put in infested quarters. 
 
 The head and upper part of the neck afford a protective location for 
 the lice, as they cannot here be reached by the beak. They may, how- 
 ever, especially in older birds, be found upon all parts of the body. 
 
 The biting species with which birds are infested belong with either the 
 Philopteridse or Liotheidse, the former containing species harbored by 
 both mammals and birds, the latter lice of birds only. 
 
 Lice of Chickens 
 
 The Philopteridse of chickens are Goniocotes gallince, G. gigas, Lipeurus 
 caponis, and L. heterographus. 
 
 \. Goniocotes gallince {G. hologaster). — Head broad as long; anterior 
 border rounded; angular at temples. Abdomen sac-like in outline, hav- 
 ing curved bands upon lateral l^orders of segments; transverse patches 
 in double row. General color dirty yellow. Female about 1 mm. in 
 length. 
 
 A common species. 
 
 2. Goniocotes gigas (G. abdominalis) . — Head rounded, circular in 
 front. Thorax narrow. Abdomen large and but slightly longer than 
 
LICE OF POULTRY. THE BEDBUG 
 
 83 
 
 broad; each segment marked laterally by long tongue-shaped spots. 
 The general color is yellowish. The female is 3 to 3.5 mm. in length, a 
 size exceptional in this genus (Fig. 49). 
 
 About as common as the preceding species. 
 
 3. Lipeurus caponis (L. variabilis). — In all members of this genus the 
 body is elongated and narrow. Head longer than broad and rounded in 
 front. Abdomen long and slender with black margins. Color yellowish 
 white. Female about 2 mm. in length (Fig. 50). 
 
 By its long and slender appearance this species can easily be dis- 
 tinguished from others mfesting the chicken. It is not very common. 
 
 4, Lipeurus heterographus. — Head more narrow in front and body 
 much stouter than in preceding species. Abdomen elongated oval in 
 
 Fig. 49. — Gonio- 
 cotes abdominalis 
 (after Osborn, from 
 Denny, Bui. No. 5, 
 Bureau of Entomol- 
 ogy, U. S. Dept. of 
 Agr.). 
 
 Fig. 50. — Lipeu- 
 rus variabilis (after 
 Osborn, from 
 Denny, Bui. No. .5, 
 Bureau of Entomol- 
 ogy, U. S. Dept. of 
 Agr.). 
 
 Fig. 51. — Menopon 
 pallidum (after Os- 
 born, from Denny, 
 Bui. No. 5, Bureau 
 of Entomology, U. 
 S. Dept. of Agr.). 
 
 outline with median spots on each ring. General color pale yellow. 
 Female 2 nun. in length. 
 
 This species has not been often observed in this country. It is said 
 to also occur upon certain species of pheasants. 
 
 Of the Liotheidffi chickens are hosts to two species, Menopum trig- 
 onocephalum and M. biseriaium. 
 
 5. Menopum trigonocephalum (M. pallidum; Menopon pallidum). — 
 Head somewhat triangular, rounded in front and at the temples. Abdo- 
 men of female elongated oval in outline, in male longer and narrower. 
 Legs stout and hairy. Color light yellow. Female about 1.5 mm. in 
 length (Fig. 51). 
 
 This is the most prevalent of all of the hen lice. It is an active runner 
 and passes readily to other species of birds. 
 
 6. Menopum biseriatum (Menopon biseriatum). — Head somewhat 
 crescent-shaped. Legs stout. Abdomen elongate. Has the same gen- 
 
84 PARASITES OF THE DOMESTIC ANIMALS 
 
 eral color as M. trigonocephalum, but is larger. Female about 2.5 mm. in 
 length (Fig. 54). 
 
 Less common than preceding species. It attacks young chicks, espe- 
 cially about the head and anus. It may also be found upon turkeys and 
 peafowl. 
 
 Lice of Turkeys 
 
 The Philopteridse of turkeys are Goniodes stylifer and Lipeurus 
 meleagridis. 
 
 1. Goniodes stylifer. — Head broad as long, well rounded in front, with 
 posterior angles projected backward into pomts which are terminated bj^ 
 strong bristles. Thorax angular and narrowed anteriorly. Legs slender 
 and hairy. Abdomen broad, with tongue-shaped bands on the sides. 
 Hairs are numerous and long on both surfaces. Color yellowish white. 
 Female about 3 mm. in length (Fig. 52). 
 
 This is a large species common upon turkeys everywhere. 
 
 2. Lipeurus meleagridis (L. polytrapezius) . — Head longer than broad, 
 romided in front and at the temples. Thorax and abdomen narrow and 
 elongate; last abdominal segment in female deeply notched. Color pale 
 yellow. Female about 2.8 mm. in length (Fig. 53). 
 
 Also quite common. 
 
 The Menopum of the turkey is M. hiseriatum (Fig. 54), referred to 
 under the Liotheidae of chickens. 
 
 Lice of Ducks and Geese 
 
 Of the Philopteridse ducks and geese harbor two species, Philopterus 
 icterodes and Lipeurus anatis. 
 
 1. Philopterus icterodes {Docophorus icterodes). — Head longer than 
 broad, rounded m front; lower portion expanded and rounded. Abdo- 
 men oval in outline, white in center, and with dark lateral bands. Color 
 brownish red. Female 1 mm. in length. 
 
 Of common occurrence. 
 
 2. Lipeurus anatis (L. squalidus). — Head longer than broad, cone- 
 shaped, rounded in front. Thorax and abdomen elongate with dark 
 borders. On the abdomen the border is broken into patches correspond- 
 ing with the segments. General color light yellow. Female about 4 mm. 
 in length (Fig. 55). 
 
 Frequently found upon both domestic and wild ducks. 
 The Liotheidae of ducks and geese are Trinotwn luridum and T. 
 lituratum. 
 
 3. Trinotwn luridum (Trinoton luridum). — Head as wide as long, 
 somewhat triangular m shape, with rounded corners. Thorax longer 
 than head. Abdomen long and narrow, with dark bands upon the 
 
LICE OF POULTRY. THE BEDBUG 
 
 85 
 
 Fig. 52. — Goniodes stylifer 
 (after Osborn, Bui. No. 5, Bu- 
 reau of Entomology, U. ^S 
 Dept. of Agr.). 
 
 Fig. 53. — Lipeurus polytrapezius 
 (after Osborn, from Piaget, Bui. No. 5, 
 Bureau of Entomologv, U. S. Dept .'of 
 Agr.). 
 
 Fig. 54. — Menopon biseriatum (after 
 Osborn, Bui. No. 5, Bureau of Entomol- 
 ogy, U. S. Dept. of Agr.). 
 
 Fig. 55. — Lipeu- 
 rus squalidus (after 
 Osborn, Bui. No. 5, 
 Bureau of Entomol- 
 ogy, U. S. Dept. of 
 Agr.). 
 
86 PARASITES OF THE DOMESTIC ANIISIALS 
 
 segments. Entire insect long and narrow. General color grayish. 
 Female 4 mm. in length (Fig. 56). 
 
 A common species. 
 
 4. Trinotum lituratum (Trinoton lituratum). — Shorter and smaller 
 than the preceding species, with head, thorax, and abdomen relatively 
 broader. Legs broad and stout. Abdommal segments bordered by 
 darkened spots. Color white. 
 
 This species occurs upon domestic geese. 
 
 Lice of Swan 
 
 Philopterus cygni and Ornitlionomus cygni are species of Philopteridse 
 harbored by swan. 
 
 1. Philopterus cygni (Docophorus cygni). — Head about as broad as 
 long, rounded in front. Thorax short and narrow. Abdomen sacular, 
 white in center, darkened at sides. Head, thorax, and legs reddish 
 brown. Female 1 mm. in length (Fig. 57). 
 
 This is the "Little Red Swan Louse." It is quite common. 
 
 2. Ornithonomus cygni {Ornithobiiis bucephalus; 0. cygni). — Head 
 massive and nearly as broad as long. Thorax about the same length as 
 head. Abdomen narrow oval, tapering toward apex; black points on 
 outer margins of four of the abdominal segments. The bodj' is trans- 
 parent and much flattened. General color white. Female 4 mm. in 
 length (Fig. 58). 
 
 Occurs in great abundance on all species of swan. 
 
 Lice of Pigeons 
 
 The more common Philopteridse of pigeons are Goniocotes compar, 
 Goniodes damicornis, and Lipewus columbce. 
 
 1. Goniocotes compar. — Head large, nearlj' as broad as long, rounded 
 in front. Thorax narrow. Abdomen broad oval. Color dirty yellow. 
 Female about 1.3 mm. in length (Fig. 59). 
 
 Found quite frequenth'. 
 
 2. Goniodes damicornis. — Head about as broad as long, rounded in 
 front, angular behind. Legs stout. Abdomen broad and short. Color 
 t)rown. Female 2 mm. in length (Fig. 60). 
 
 Not as common as preceding species. 
 
 3. Lipeurus columbce (L. baculus). — Characterized by its extreme 
 slenderness. Head long and narrow, as is also the thorax and abdomen. 
 Upon the abdominal segments are brownish patches. Head and thorax 
 brownish red in color; abdomen dusky. The female is 2 mm. in length. 
 
 Occurs abundantlv. 
 
LICE OF POULTRY. THE BEDBUG 
 
 
 Fig. 56.— Trino- 
 ton luridum (after 
 Osborn, Bui. No. 5, 
 Bureau of Entomol- 
 ogy, U. S. Dept. of 
 Agr.). 
 
 Fig. 57. — Docophorus 
 cygni (after Osborn, Bui. 
 No. 5, Bureau of Ento- 
 mology, U. S. Dept. of 
 Agr.). 
 
 M 
 
 w 
 
 Fig. 5)S. — Ornithobius cygni 
 (after Osborn, Bui. No. 5, Bureau 
 of Entomology, U. S. Dept. of 
 Agr.). 
 
 ^^try^ 
 
 
 ,M 
 
 3 ' 
 
 
 
 
 1 
 
 
 T~~- — ^— 
 
 
 Fig. 59. — Goniocotes corn- 
 par (after Osborn, Bui. No. 5, 
 Bureau of Entomology, U. S. 
 Dept. of Agr.). 
 
 Fig. 60. — Goniodes dani- 
 icornis (after Osborn, Bui. 
 No. 5, Bureau of Entomol- 
 ogy, U. S. Dept. of Agr.). 
 
88 PARASITES OFfcTHE DOMESTIC ANIMALS 
 
 CONTROL^AND TREATMENT 
 
 In dealing with lice of poultry we should first discriminate between 
 the lice and the ticks, bearing in mind that the latter do not breed upon 
 their hosts. According to whether they be one or the other the treatment 
 will be modified somewhat, though certain measures of eradication may 
 be suitable for either. All species of lice, without a known exception, 
 passing their transformation upon the host, there may be confidence in 
 attacking them that there are no eggs and young developing in some 
 out-of-the-way retreat, as in the case of ticks or bedbugs. 
 
 As a means of controlling bird lice the dust bath should receive first 
 attention. The fine dust particles enter the spiracles of the insects, 
 killing them by suffocation, therefore, of whatever material it may con- 
 sist, the dust will be most effectual when fine and penetrating. Road 
 dust is usually quite suitable; it will be the more efficient if powdered 
 tobacco be added in the proportion of about one of tobacco to five of 
 dust. Fine ashes, in which powdered sulphur is mixed, make an ex- 
 cellent dust wallow. A mixture of road and lime dust, with the addition 
 of a cupful or two of sulphur, may be used with as good results. The 
 dust baths should be in deep and roomy boxes placed where they will be 
 sheltered from the rain. 
 
 As an insecticide for the individual treatment of badly infested birds, 
 any oleaginous substance is effectual. As with dust, the principle upon 
 which its use is based is that of suffocation, the unctuous agent serving 
 to plug the breathing pores of the insect. A mixture of lard and sulphur 
 answers well for all birds. It should especially be applied at the throat, 
 upper neck, bases of the wings, and at the base of the tail feathers. If a 
 powder is used, as pyrethrum, the skin should be first moistened with 
 soapy water or equal parts of glycerin and water and the powder then 
 blown well under and through the feathers. 
 
 Investigations by the United States Bureau of Entomology with 
 sodium fluoride have demonstrated that lice infesting poultry may be 
 readily destroj-ed by the application of a small quantity of this powder. 
 It may be used in the powdered form or as a dip. Applied by the former 
 method, it should be sprinkled under the feathers of the neck, breast, 
 back, tail, below the vent, and upon the under side of each wing as these 
 are spread. If used as a dip, this may be prepared by adding one ounce 
 of commercial sodium fluoride to the gallon of water. The solution 
 should be made tepid and the entire body of the fowl, excepting the 
 head, immersed in it. For the treatment of one hundred fowl, about one 
 pound of the powder will be required. 
 
 As the lice are likely to be dislodged from their hosts to be harbored 
 for a time about nests, roosts, etc., it is essential that the eradicative 
 measures be also applied to the quarters of infested birds. The louse 
 
LICE OF POULTRY. THE BEDBUG 89 
 
 most commonly fomid upon the hen, Menopum trigonocephalum, is an 
 especially active runner, readily passing to other species of birds or to 
 any object with which the infested animal is in contact. It is said that 
 horses kept in the vicinity of chicken houses harboring this louse are 
 often seriously troubled by it. 
 
 In this connection the measures recommended for the eradication of 
 the lice of mammals and poultrj'-infesting bedbugs will in general 
 apply here. All nesting material and litter must, of course, be cleared 
 out and burned or buried. A washing down with five per cent, creolin 
 or carbolic acid solution should follow, the usual whitewashing in such 
 cases adding to the probability of a complete destruction of the lice. 
 The lime and sulphur mixture (page 125), apphed as a spray to all parts 
 of the interior, is penetrating and gives satisfactory results. 
 
 As a simple agent for the killing of lice or mites in the hen house and 
 dovecot the cloud of lime dust is said to be of much value. In the appli- 
 cation of this method the birds should be absent and the quarters closed. 
 A few handfuls of finely powdered lime are then thrown against the roof 
 and walls, producing a cloud of dust. This will settle upon the roosts, 
 nest compartments, and floor, and into the crevices, destroying many of 
 the exposed vermin. Afterward the place should be swept out and the 
 sweepings buried, burned, or otherwise destroyed. 
 
 Fumigation is commonly resorted to, and may have value as a con- 
 tributory measure. The sulphur fumigation, applied as recommended in 
 the eradication of bedbugs, will serve here as well. 
 
 Observations made as to the length of time required for the hatching 
 of the eggs, while not complete, indicate that for species of bird lice in 
 general, five to six days are necessary at least. Therefore, in repeating 
 treatments intended to kill individuals hatched from remaining eggs, 
 there should be an intervening period of about ten days. 
 
 Order V. Hemiptera 
 
 Insecta (p. 15). — This group includes the cicadas, plant lice, and true 
 bugs. The mouth parts are suctorial, the mandibles and maxillae being 
 modified into bristle-Hke structures for puncturing and extracting the 
 juices of plants or the blood of animals. The labium is usually jointed 
 and forms a sheath for the piercing bristles. There are usually four 
 wings, some fomis having the first pair thickened and leathery at the 
 base, while only the tips are membranous and elastic. It is from this 
 " half-winged " structure that the order derives its name. In some of the 
 lower forms (bedbugs) wings are absent. A characteristic of the order is 
 the presence of stink glands, which in the adult open ventrally on the 
 metathorax. The secretion from these glands has a disgusting odor, 
 probably originally of defensive service to the insect though in parasitic 
 forms rather serving to reveal their presence and location. The meta- 
 
90 PARASITES OF THE DOMESTIC ANIMALS 
 
 morphosis is incomplete, the immature insect resembling the adult ex- 
 cept in the absence of wings. 
 
 Family Cimicid^ 
 
 Hemiptera (p. 89). Bedbug and allies. — The body is much flat- 
 tened and is ovate in outline. The adults are reddish brown in color ; 
 young yellowish white. AVhen full grown they are from one-sixth to one- 
 fifth of an inch in length. The mouth parts inclose long slender stylets 
 (Fig. 61, d). Ocelli are absent. Wing-covers rudimentary (Fig. 61, c). 
 
 CiMEx Lectularius 
 
 Acanthia lectularia. The common bedbug. (Fig. 61). — Cimicidse 
 (p. 90). The body is covered with short hairs; rostrum short; third 
 and fourth joints of antennae much thinner than first and second; second 
 segment of antennae shorter than third. 
 
 The eggs are oval, pearly-white, and about a millimeter in length. 
 The young leave the egg by a small operculum at the end. The female 
 deposits from one hundred to two hundred eggs in cracks, crevices, and 
 seams of beds and bedding, beneath loose portions of wall-paper, base- 
 boards, floor spaces, and similar retreats. 
 
 Hatching occurs in about one week. Development from the nymphal 
 to the adult stage will, under favorable conditions, occupy about six 
 weeks. The time required for the development of adults from deposited 
 eggs under such conditions may, therefore, be approximated at from 
 seven to eight weeks. 
 
 Habits and Effect of Bite. — In their feeding habits bedbugs are 
 nocturnal, hiding in their darkened retreats during the day and coming 
 forth at night to crawl upon the legs, arms, neck, or other unprotected 
 parts of their victims, where they will feed to repletion. After this en- 
 gorgment the insects will retreat to their usual haunts to remain for 
 several days, during which time the meal is digested. 
 
 The effect of the bite of the bedbug varies, depending upon the sus- 
 ceptibihty of the one attacked. In some it produces marked irritation 
 with more or less sweUing; others may not be made aware of its presence. 
 The inflammation experienced by sensitive persons seems to result 
 mainly from the puncture of the skin. The biting organ is like that of 
 other hempiterous insects; there are four piercing filaments within the 
 labium which is closely applied to the point of puncture as the blood is 
 drawn up. 
 
 The degree to which the insect may injure other animals than man is 
 somewhat obscure. Probably the same or closely allied species to those 
 attacking man attack animals in the same manner. Chickens are es- 
 
LICE OF POULTRY. THE BEDBUG 
 
 91 
 
92 PARASITES OF THE DOMESTIC ANIMALS 
 
 pecially likely to be their hosts, the usual quarters of poultry affording 
 an ideal harbor for such pests. 
 
 Control. — Bedbugs may be easily carried upon clothing, therefore 
 puljlic conveyances and places where people of all sorts and conditions 
 of living may congregate, afford a common means for their dissemina- 
 tion. They are highly prolific, and the introduction of a single egg- 
 bearing female may be sufficient to start a colony of bedbugs within a 
 few months. 
 
 Eradication is made somewhat difficult by the parasite's habit of 
 seeking hiding places during the day, therefore anything used for this 
 purpose must be of such a nature that it will penetrate into cracks, 
 crevices, joints of bedsteads, mattress seams, and all such places where 
 the gregarious insects are in the habit of assembling and depositing 
 their eggs. Powders, such as pyrethum, are of practically no value as 
 they are not sufficiently penetrating. One of the best remedies is kero- 
 sene, applied with a feather, or, better, with an ordinary machine oiler. 
 Benzene is as effectual and will volatilize more readily, but must be 
 used with great caution against ignition. A solution of corrosive sub- 
 limate in alcohol may also be used with good results. Fumigation is of 
 doubtful value, though flowers of sulphur, two pounds to each one 
 thousand cubic feet of room space, has been recommended for this pur- 
 pose. The sulphur should be placed in a heap in a pan, a depression 
 made in the top, and a small quantity of alcohol poured into this to 
 facilitate burning. The container should be placed in a larger pan and 
 surrounded by water as a precaution against fire. During fumigation 
 the room should, of course, be tightly closed. Fumigating with 
 formaldehyde gas is as useless against bedbugs as it is against other 
 insects. 
 
 Whatever remedy may be applied, thoroughness is essential to success. 
 Beds and bedding should be inspected daily, and all places where the 
 bugs may have found a hiding place repeatedly treated. There will be 
 less difficulty if brass and iron bedsteads are used, the old-fashioned 
 wooden bedsteads furnishing many retreats into which the bugs can 
 force their flat, thin bodies. 
 
 In infested chicken houses the parasites usually secrete themselves 
 around the ends of the roosts and in the nests. Their attack upon the 
 chickens at night results in a loss of flesh with reduced egg production. 
 In heavy infestation chickens will often die from emaciation and loss 
 of blood. If the propagation of the bugs in the chicken houses is not 
 checked, they may spread to nearby buildings to become a source of 
 annoyance to other live stock. 
 
 Control measures in such cases consist in thoroughly renovating the 
 chicken house. Roosts in wooden fittings should be taken down, and 
 all loose lumber, useless boxes, straw, or other material affording hiding 
 
LICE OF POULTRY. THE BEDBUG 93 
 
 places removed and burned. Possible breeding places remaining should 
 be sprayed with kerosene or kerosene emulsion (page 48). Scalding 
 hot water or whitewash will destro}- both the insects and the eggs. The 
 kerosene application should be repeated at frequent intervals to insure 
 the eradication of followmg generations. 
 
 ^ 
 
 ^OJuy^ 
 
CHAPTER X 
 
 THE MITES 
 
 Class II. Arachaida. Arthropoda (p. 13). — The arachnids may at 
 once be distinguished from the insects by the relationship of the body 
 parts and the number of ambulatory appendages, as to be described. 
 
 The regions of the body are more or less fused, the head being com- 
 monly fused with the thorax to form the cephalothorax (Fig. 62) , 
 
 The abdomen is in some forms segmented (scorpions), in others un- 
 segmented and separated from the thorax by a deep construction (true 
 spiders). 
 
 Sometimes the cephalothorax and abdomen are fused into one un- 
 segmented body (ticks and mites) . 
 
 In the adult there are four pairs of locomotor appendages, usually 
 seven-jointed, attached to the cephalothorax. There are no wings. 
 
 Antennae are absent. 
 
 The mouth parts are paired chelicerse and pedipalpi, the first in front 
 of the mouth, the second to the side. 
 
 The chelicerse are short, consisting of two or three joints. The last 
 joint may have a claw-like termination for piercing and introducing 
 poison into prey (spiders), or it may be in the form of small chelae (scor- 
 pions). 
 
 The pedipalpi are longer and more like the appendages for locomo- 
 tion. The terminal segment may be strongly chelate (scorpions). 
 
 The eyes are located anteriorly upon the cephalothorax and consist 
 of a varying number of ocelli. The eyes are never compound. 
 
 The skin is of a leathery consistency and is not so hard as in insects. 
 
 Respiration is either by tracheae or by so-called book-lungs, the latter 
 consistmg of a series of invaginations of the skin closely applied like the 
 leaves of a book. Either one or both of these forms of respiratory organ 
 may occur in a single individual. 
 
 Most arachnids are oviparous. In aberrant forms, as Linguatulida and 
 Acarina, certain adult appendages are acquired after a molt. 
 
 The class Arachnida includes the scorpions, spiders, ticks, and mites. 
 
 The two parasitic orders are Acarina, which includes the ticks and 
 mites, and Linguatulida, containing the species Linguatula rhinaria. 
 
 Order I. Acarina. Ticks and Mites. — Arachnida (p. 94). These are 
 small, freciuently microscopic, arachnids iii which there is generally no 
 distinct demarcation l^etween the cephalothorax and abdomen, the body 
 regions being massed into one. 
 
THE MITES 95 
 
 Due to parasitism, the mites have undergone considerable modifica- 
 tion, the scab mites are without ej-es or organs of respiration, and gener- 
 ally the tips of the feet are terminated by suckers or bristles. 
 
 In the larval stage, the Acarina have but three pairs of legs, the fourth 
 pair appearing behind the third after a molt. 
 
 The mouth parts are modified into a beak-like structure for piercing 
 and sucking. 
 
 The sexes are separate and reproduction is by eggs which are extruded 
 from the genital pore situated, as in other Arachnida, anteriorly on the 
 ventral surface of the abdomen. In the scab mites (Sarcoptidse) the fe- 
 males are provided with a second genital opening, the copulating vagina, 
 
 G J M 
 
 Fig. 62. — Diagram of the anatomy of a spider: a, anus; b, cecum of 
 mesenteron; b', its anterior end; b", branches of cecum extending into 
 legs; c, cerebral ganglion connected with ventral ganglionic mass; d, 
 mesenteron; e, poison glands; g, heart; h, chelicerae; i, pedipalpi; j, liver; 
 k, hepatic duct; 1, lung sac; m, Malpighian tubules; n, dilation of rectum 
 into which Malpighian tubules open; o, eyes; ov, ovaries; p, female 
 genital pore; q, large and small silk glands; r, opening of tracheal system; 
 s, spinnerettes (after Boas by Kirkaldy & Pollard). 
 
 which is located posteriorly just in front of the anus. It is at this open- 
 ing that spermatozoa are received during copulation, the anterior open- 
 ing serving as the pore of the oviduct. 
 
 In their development the Acarina undergo a succession of stages. The 
 larvae are usually provided with but three pairs of legs (hexapodal), and 
 have no definite sexual characters. After molting a fourth pair of legs 
 appears, and the acarus enters upon its njanphal stage. Following 
 further molting the genital organs are acquired, and it has then reached 
 the pubescent stage, or stage of sexual maturity. After copulation the 
 female undergoes a further transformation, l^ecoming an egg-bearing, 
 or ovigerous female. 
 
 Parasitism. — The majority' of the Acarina are parasitic, though, as 
 to this habit, there is much diversity, some being semiparasitic, others 
 essentially so and restricted to definite hosts. 
 
 The order contains a number of families of which the following are 
 here considered: 
 
96 PARASITES OF THE DOMESTIC ANIMALS 
 
 Famil}^ I. Gamasidae. — Poultry mites. 
 
 Family II. Trombidiidae. — Harvest mites or chiggers. 
 
 Family III. Sarcoptidse. — Mange and scab mites. 
 
 Family IV. Demodecidae. — Follicle mites. 
 
 Family V. Cytoleichidse. — Deep seated mites of birds. 
 
 Superfamily Ixodoidea. — The ticks. 
 
 Family I. Argasidce. — The fowl tick and ear tick. 
 
 Family II. Ixodidge. — The cattle tick and other ticks. 
 
 Each of these contains species parasitic upon mammals or birds with 
 the exception of the Demodecidae, which, so far as known, have only 
 been found upon mammals. 
 
 The condition produced upon the host by the presence of parasitic 
 Acarina is designated medically as acariasis. Differing in their grade 
 of parasitism, the numerous species bring about a varying degree of 
 disturbance to the skin which they inhabit. Accordingly there is dis- 
 tinguished sarcoptic and psoroptic acariasis, the former produced by 
 species which burrow and form subepidermic galleries in which they 
 deposit their eggs, the latter by species living upon the skin's surface. 
 The term mange is limited by most writers to acarises caused by species 
 of the genus Sarcoptes and its near alKes, or by Demodex, both living 
 beneath the skin's surface, the last named in the hair follicles and se- 
 baceous glands. The psoroptic form, in which there is deep scab for- 
 mation, constitutes true scabies or scab, although these latter terms are 
 frequently used in a general sense relative to the condition produced 
 by the mange and scab mites. Acari belonging with the families Ga- 
 masidae, Trombidiidae, and the superfamily Ixodoidea do not cause 
 mange or scab. 
 
 Classification of Parasites of the Class Arachnida 
 
 Class B. Arachnida. P. 94. 
 Order I. Acarina. P. 94. 
 Family (a) Gamasidae. P. 98. 
 Genus and Species: 
 
 Dermanyssus gallinae. Host, poultry. P. 98. 
 Family (b) Trombidiidae. P. 99. 
 Genus and Species: 
 
 Trombidium holosericeum. Larvae attack man and lower 
 animals. P. 100. 
 Family (c) Sarcoptidae. Mange and scab mites. P. lOL 
 Genus and species: 
 
 Sarcoptes scabiei var. Equi. Host, equines. P. 104. 
 S. scabiei var. 'Ovis. Host, sheep. P. 112. 
 S. scabiei var. Bovis. Host, cattle. P. 114. 
 S. scabiei var. Suis. Host, hog. P. 114. 
 
THE MITES 97 
 
 S. scabiei var. Canis. Host, dog. P. 115. 
 Notoedres cat! var. Cati. Host, cat. P. 118. 
 N. cati var. Cuniculi. Host, rabbit. P. 118. 
 Psoroptes communis var. Equi. Host, equiiies. P. 108. 
 P. communis var. Ovis. Host, sheep. P. 109. 
 P. communis var. Bovis. Host, cattle. P. 113. 
 P. comnmnis var. Cuniculi. Host, rabbit. P. 118. 
 Chorioptes commimis var. Equi. Host, equines. P. 108. 
 C. communis var. Ovis. Host, sheep. P. 112. 
 
 C. communis var. Bovis. Host, cattle. P. 113. 
 Otodectes cynotis var. Canis. Host, dog. P. 117. 
 
 0. cynotis var. Cati. Host, cat. P. 117. 
 Cnemidocoptes mutans. Host, poultr}-. P. 132. 
 Cn. gallinae. Host, poultry. P. 133. 
 
 Family (d) Demodecidae. Folhcular mange mites. P. 103. 
 Genus and Species: 
 
 Demodex folliculorum var. Ovis. Host, sheep. P. 112. 
 
 D. folhculorum var. Suis. Host, hog. P. 115. 
 D. folliculorum var. Canis. Host, dog. P. 116. 
 
 Family (e) Cytoleichidae. P. 134. 
 Genus and Species: 
 
 Cj'toleichus nudus. Host, poultry. P. 134. 
 Laminosioptes cysticola. Host, poultry. P. 134. 
 Superfamily Ixodoidea. Ticks. P. 139. 
 Family (a) Argasidse. P. 139. 
 Genus and Species: 
 
 Argas miniatus. Host, poultry. P. 139. 
 Otobius megnini. Hosts, equines, cattle, etc. P. 140. 
 Family (b) Ixodidse. P. 141. 
 Genus and Species: 
 
 Ixodes ricinus. Hosts, cattle, equines, dog, etc. P. 143. 
 
 1. hexagonus. Hosts, cattle, dog, etc. P. 143. 
 Dermacentor variabilis. Hosts, cattle, dog, equines, etc. 
 
 P. 143. 
 D. reticulatus. Hosts, cattle, equines, etc. P. 143. 
 Margaropus annulatus. Hosts, cattle, equines. P. 144. 
 Amblvomma americanum. Hosts, cattle, dogs, equines, etc. 
 P. i45. 
 Order 2. Linguatulida. P. 153. 
 Family (a) Linguatulidse. P. 153. 
 Genus and Species: 
 
 Linguatula rhinaria. Host, dog. P. 153. 
 
98 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Family I. Gamasid^e 
 
 Acaiiiia (p. 94). — The gamasid mites. The mouth parts are] ar- 
 ranged for piercmg and sucking, maxillae fused into a tube, maxillary 
 palps five-segmented and provided inwardly with secondary palps. 
 The legs have six segments, the tarsi terminating b,y two booklets. 
 There are two stigmata located near the insertion of the posterior legs. 
 The cephalothorax and abdomen are fused into one body. The integu- 
 ment is of a leatherv texture. Eves are absent. 
 
 Dermanyssus Gallin.e 
 
 Poultry mite; chicken "tick" (Fig. 63). Gamasidse (p. 98). — Body 
 somewhat egg-shaped with larger end posterior, slightly flattened from 
 above to below. The lower half of the body is provided with short, 
 
 Fig. 63. — Dermanyssus gallinae: a, adult; b, tarsus; c, mouth- 
 parts; d and e, young — all enlarged (after Osborn, Bull. No. 5, Bureau 
 of Entomology, U. S. Dept. of Agr.). 
 
 well-separated bristles. The color is Hght gray with dark patches 
 showing through the skin; when engorged with blood the color is a 
 distinct red. The ovigerous female is rather less than 1 mm. in length. 
 
 Occurrence and Habits. — The little poultry mite, found everywhere 
 where chickens are kept, is one of the most persistent and injurious pests 
 that the poultry raiser has to contend with. Remaining in darkened 
 retreats about the henhouse during the daytime, these acari come forth 
 at night to swarm upon the fowls and suck their blood. Their attack, 
 however, is not confined entirely to the night, and hens may be driven 
 
THE MITES 99 
 
 from their nests by the activity of the pests which the warmth of their 
 bodies creates. 
 
 The Demianyssiis does not hmit itself to birds, but may attack 
 mammals, including man, though these animals, being accidental hosts, 
 the invasion is usually limited in its extent and duration. Horses kept 
 in the vicinity of infested henhouses are likely to be tormented by the 
 mites, the litter about stables so located affording a harbor to which 
 they readily migrate. 
 
 The eggs are deposited in vast numbers in the daytime retreats. 
 Under ordinary conditions about five days are required for the hatching 
 of the hexapodal larvae which do not wait for maturity to attack the 
 chickens. They may, however, remain for months without a host upon 
 which to satisfy their appetite for blood. Extremely prolific, they 
 especially thrive upon filth, and large colonies may be found wherever 
 such material has collected. 
 
 Effect. — ^Fowls suffer not only from the extreme irritation and an- 
 noyance of the attack, but additionally from the extraction of a consider- 
 able amount of blood. Prolonged infestation must essentially brine; 
 about a progressive emaciation and weakening which may end in death, 
 young chicks especially being likely to succumb. In any event egg 
 production is retarded, and the chickens, in their unthrifty condition, 
 are unprofitable for marketing. 
 
 Control. — Cleanliness and plenty of sunlight are especially antago- 
 istic to the Dermanyssus. The cleaning up measures set forth elsewhere 
 for the eradication of the parasites of the henhouse need not be repeated 
 here. Kerosene emulsion (page 48) is serviceable, but should only be 
 applied after the entire interior has been stripped to the boards of every- 
 thing movable and all crevices, joints, and roost insertions exposed. 
 It is well to drench cracks and the ends of roosts with pure kerosene or 
 scalding water. The ends of roosts, before being replaced, should be 
 dipped in coal tar, and this spread along the roosts for about six or eight 
 inches from their supports in such manner that the mites will be obliged 
 to cross the tar before reaching the fowls. Pyrethrum powder, alone or 
 mixed with lime dust, should be shaken through the fresh nesting mate- 
 rial. The dust bath, as recommended in the treatment for lice, should 
 always be accessible. 
 
 In order to insure continued freedom from the vermin it is necessary 
 that the control measures be repeated at least three times at intervals 
 of about ten days. 
 
 Family II. Trombidiid^ 
 
 Harvest mites; chiggers, or red bugs. Acarina (p. 94). — The body is 
 red in color and covered with bristles or fine hairs. The mandibles are 
 chelate; palpi prominent. The legs have six to seven segments pro- 
 
100 PARASITES OF THE DOMESTIC ANIMALS 
 
 vided with bristles or fine hairs, the tarsi terminating in two hooklets. 
 Respiration is by tracheae. There are two eyes, one located upon each 
 side of the cephalothorax. 
 
 Trombidium Holosericeum 
 
 Trombidiidse (p. 99). — Body red and nearly square; slightly narrower 
 posteriorly where the terminal border is slightly concaved; body and 
 legs covered with bristly hairs. Eyes pedunculated. About 1 mm. in 
 length. 
 
 Habits and Effect. — In the adult stage the Trombidium is free- 
 living, feeding upon the juices of plants and small insects. It is only 
 parasitic in its larval condition, in which stage it will inhabit insects 
 and attack warm-blooded animals as well. Living in the tall grass and 
 upon the under side of the leaves of weeds, they are brushed off upon 
 the hands or clothing of people and upon the bodies of animals as they 
 pass through the vegetation. They then proceed to burrow into the 
 skin, setting up a most exasperating itching with the formation of 
 reddened patches often covering considerable areas. This phase of 
 the mite's parasitism is pecuhar in that it invariably perishes in the act 
 of entering the skin. It is likely to be most troublesome during the late 
 summer and autumn, the name Leptus autumnalis, under which the 
 larval stage of the mite has been described, being derived from this fact. 
 
 Man is most often attacked about the lower parts of the legs and upon 
 the hands. Among domestic animals, those which frequent locations 
 densely covered with vegetation are the most likely to suffer. Hunting 
 dogs especially are exposed, and on returning from the field will often 
 exhibit symptoms of great itching about the face, paws, inner thighs, 
 and belly, the parts most often attacked. Horses will be affected prin- 
 cipally below the knees and hocks. 
 
 Treatment. — As the larval mites die upon entering the skin, the 
 source of the irritation is soon eliminated and the intense itching will 
 usually rapidly subside, leaving areas of epithelial exfoliation over the 
 parts affected. Recently exposed animals will be relieved somewhat by 
 frictions with a cloth sprinkled with benzene, or by the application of a 
 mixture of equal parts of hme-water and hnseed oil, or sulphur ointment 
 may be used. Sponging with a solution of carbolic acid at about three 
 per cent, strength in water to which a little glycerin has been added, 
 will do much toward reheving the itching. Ammonia-water, or a solu- 
 tion of bicarbonate of soda are both of value for this purpose. 
 
 Persons working or passing through infested districts will, in con- 
 siderable degree at least, be protected from attack by applying a mix- 
 ture of kerosene and glycerin to the hands and ankles. 
 
THE MITES 101 
 
 Family III. Sarcoptid^ 
 
 Mange, scab, or itch mites. Acarina (p. 94). — The body has the 
 cephalothorax and abdomen fused ; it is white or reddish in color. The 
 ciiticular surface is transversely striated and provided with bristles, 
 sometimes with short dorsal spines. The mouth parts are beak-like, 
 extending forward, and covered by the protruding labrum; chelicerae 
 scissors-hke; maxillary palpi small and three-segmented. The legs are 
 short and stout, have five segments, and are disposed in two groups of 
 two pairs each, the anterior pairs, usually the larger and near the mouth 
 parts, the posterior pairs near the abdomen. The tarsi commonly ter- 
 minate in one or two booklets; they may temiinate in a long bristle or 
 an ambulator}^ sucker, often upon a stalk which may be segmented. 
 Respiratory organs are absent; respiration cutaneous. There are no 
 eyes. All are scarcely visible without the aid of magnification. 
 
 There are frequently well-marked sexual differences. ]Males are con- 
 siderably smaller than the females. In some males the fourth pair of 
 legs is very small, and there may be plate-like copulatory suckers at 
 the base of the abdomen with abdominal prolongations. As to the 
 presence or absence of bristles or stalked suckers, the tarsi ma}^ ter- 
 minate differently in the two sexes. 
 
 Development. — As already stated in the general reference to the 
 Acarina, the Sarcoptidae have three distinct stages in the development of 
 the male, four in the female. After sexual maturity and fertihzation of 
 the female, the male usually dies. Following fertilization the female 
 molts and enters upon her fourth or ovigerous stage, — the egg-bearing 
 stage, recognizable by the presence of the genital pore upon the anterior 
 ventral surface of the abdomen, through which the eggs are extruded. 
 
 The rapidit\' with which these acari breed is very great. It has been 
 estimated that one female sarcopt will produce in a subepidermic gallery 
 about fifteen individuals, from which, after ninety days, there may be 
 1,500,000 descendants constituting the sixth generation. 
 
 The family includes a number of genera differing in their mode of 
 attack and location upon the host. All are permanently parasitic. Of 
 these, sLx, nameh" Sarcoptes, Psoroptes, Chorioptes, Notoedres, Cnem- 
 idocoptes, and Otodectes are considered here. The characteristics and 
 habits of the principal genera met with follow. 
 
 Sarcoptes (Fig. 64). Sarcoptidae (p. 101). — The body is rounded or 
 slighth' oval; the mouth parts short and about as broad as long. Upon 
 the dorsal surface of the body are a number of cone-like prominences 
 and twenty spines, the latter short, thick, and grouped as follows: four- 
 teen upon the abdomen, seven to the right and seven to the left side; 
 six upon the cephalothorax, three to the right and three to the left. 
 The legs are thick and conical, the posterior pair being nearly or quite 
 
102 PARASITES OF THE DOMESTIC ANIMALS 
 
 concealed beneath the abdominal margin when the acarus is in dorsal 
 view. In the female the first two pairs of legs are terminated by stalked 
 ambulatory suckers; the posterior pairs by bristles. In the male all 
 of the legs are provided with stalked suckers but the third pair which 
 terminates in bristles. The anus is located upon the posterior dorsal 
 margin of the abdomen. Just anterior to this in the female is the copu- 
 lating vagina (receptaculum seminis). Upon the ventral side at the 
 median anterior border of the abdomen of the ovigerous female is the 
 genital pore. The males have no copulatory suckers or abdominal ex- 
 tensions. 
 
 The Sarcoptes live upon man and practically all of the domestic 
 mammals. In the latter animals they seek the parts of the body where 
 the hair is short, while in man their preference is for places where the 
 skin is thin, as about the kimckles, between the fingers, and in the bend 
 of the elbows and knees. A peculiarity of their attack is the habit in 
 the female of cutting tunnels beneath the epidermis, in the bottom of 
 which she deposits her eggs (Fig. 65), a circumstance that renders this 
 form of acariasis relatively difficult to cure. 
 
 The Sarcoptes inhabiting the skin of various animals cannot be said 
 t o exhibit differences of specific importance. They may, therefore, be 
 placed in a single species — Sarcoptes scahiei — which may give rise to 
 varieties according to host, as Sarcoptes scahiei, var. homi7iis of man, var. 
 equi of the horse, and var. suis of swine, etc. The slight difference in 
 these, as in other Sarcoptidae, is mainly one of size. 
 
 Psoroptes (Figs. 68 and 69). Sarcoptida (p. 101).— The body is 
 oval, the mouth parts elongated and in the form of a cone. The legs 
 of the anterior pairs are thick, the posterior pairs more slender; all four 
 pairs extend beyond the margin of the body. In the female the first 
 two pairs of legs and the fourth pair are terminated by ambulatory 
 suckers carried on long, three-segmented stalks, the third pair being 
 terminated by bristles. The male has copulatory suckers serving for 
 fixation to the female, and short posterior al^dominal prolongations 
 terminated by bristles. The first three pairs of legs are terminated by 
 stalked suckers; the fourth pair is stunted. 
 
 Psoroptic scabies, the form produced by the members of this genus, 
 is the most common and has been longest known. Unlike Sarcoptes, 
 Psoroptes seek the parts of the body where the hair is long; they do not 
 burrow beneath the epidermis, but attack the skin upon its surface, 
 their punctures being followed by the formation of thick crusts. Under 
 these they live in colonies which may coalesce and eventually cover 
 areas of the bod}-- more or less circumscribed. Psoroptic scabies is most 
 often observed upon animals with bodies covered wholly or in part by 
 long hair, as the sheep, ox, and horse. 
 
 As with Sarcoptes, the difference in host inhabited by Psoroptes 
 
THE MITES 103 
 
 coincides with varieties which have unimportant and scarcely dis- 
 tinguishable differences. There is, therefore, but one species, Psoroptes 
 communis, designated according to host as variety ovis of the sheep, 
 var. bovis of the ox, var. equi of the horse, var. cuniculi of the rabbit, 
 etc. 
 
 Chorioptes (Symbiotes; Dermatophagus) (Fig. 67). Sarcoptidae 
 (p. 101). — The body is oval. The mouth parts are about as broad as 
 long and somewhat dome-shaped. The legs are long and visible beyond 
 the sides of the body. The ambulatory suckers are large and carried on 
 short, unsegmented stalks. In the female all of the legs are terminated 
 by suckers excepting the third pair, these are terminated by bristles. 
 The male has copulatory suckers and abdominal prolongations ter- 
 minated by leaf-like processes. The fourth pair of legs is stunted; all of 
 the legs are provided with suckers. 
 
 Chorioptic mites live, as do psoroptic, in colonies upon the skin where 
 the hair is long and among the crusts which they form. There is one 
 species, Chorioptes communis (Symbiotes communis, Chorioptes symbiotes, 
 Dermatophagus communis). This infests the lower parts of the legs, 
 especially of horses with long hairs upon the fetlocks, though in the ox 
 this form of scabies generally has its seat at the base of the tail. 
 
 Cnemidocoptes (Sarcoptes). SarcoptidiP (p. 101). — The body is 
 rounded in outline. The mouth parts are short, broader than long, and 
 rounded. In the female the legs are conical and very short; they are 
 without suckers or bristles, terminating in two unequal booklets. In 
 the male the legs are somewhat longer and all four pairs are terminated 
 by stalked suckers and bristles. 
 
 This genus contains a burrowing mite, Cnemidocoptes mutans (Fig. 74), 
 which produces "scaly leg" in fowls; also a species known as the de- 
 pluming mite, Cnemidocoptes gallince, which attacks the skin of fowls 
 near the insertion of the feathers. 
 
 Of the genera Notoedres (Fig. 71) and Otodectes, the former infests 
 small mammals, and the latter lives in the external ear of the dog and 
 cat. 
 
 Family IV. Demodecid.e 
 
 Acarina (p. 94). Follicular mange mites (Fig. 70). These are verj' 
 minute and worm-like. The body is distinctly divided into cephalo- 
 thorax and abdomen, the latter elongated and transversely striated. 
 The anus is on the anterior ventral border of the abdomen, probably 
 serving in the female for both, copulation and ovulation. The legs are 
 three-segmented, short and stumpy. The mouth parts are suctorial. 
 Respiration is cutaneous. There are no e.yes. The length is about 
 0.3 mm. 
 
 They undergo the same stages of development as other acari. 
 
104 
 
 PARASITES OF THE DOMESTIC ANIIVIALS 
 
 There is but one species, Demodex follicidorum (Fig. 70), which in- 
 habits the hair folhcles and sebaceous glands of several manunalian 
 species. Its size differs somewhat with its habitat, the difference in 
 dimensions authorizing a division into varieties according to host. 
 
 Scabies of the Horse 
 Horses, asses, and mules are affected with 'one form of mange and two 
 of true scabies, as follows : 
 
 1. Sarcoptic mange, due to Sar copies scabiei var. equi. 
 
 2. Psoroptic scabies, due to Psoroptes communis var. equi. 
 
 3. Chorioptic scabies, due to Chorioptes communis var. equi. 
 Sarcoptic Mange of the Horse. — In the majority of cases acariasis of 
 
 the horse is caused by Sarcoptes (Fig. 64). It begins most frequently 
 
 Fig. 64. — Sarcoptes scabiei var. equi, female; dorsal (left) and ventral 
 (right) surface. 
 
 about the head, sides of the neck, or at the withers, extending, if neg- 
 lected, over large areas of the body, involving in some cases even the 
 lower parts of the legs. In its initial stage sarcoptic mange is somewhat 
 slow in development, the small number of acari at the beginning not 
 giving rise to s\miptoms readily observable. In from three to six weeks, 
 however, the multiplication of the parasites has sufficiently progressed 
 to clearlj' reveal the affection. 
 
 Symptoms. — The first sjanptom is itching, more or less intense, 
 which the animal seeks to relieve by rubbing itself against anything 
 available, or by biting affected parts of the body which it can reach. 
 
THE MITES 
 
 105 
 
 When groomed with the brush or currycomb it will manifest its pleasure 
 by protrusion and movements of the upper lip, at the same time leaning 
 toward the brush. This action is not peculiar to mange, however, as it 
 may be observed in any itching skm affection of the horse. The pruritus 
 seems to be greater at night and is always intensified by an increase in 
 the warmth of the body, as hy a warm stable or warm clothing. This is 
 probably due to the greater activity of the parasites under such condi- 
 tions. 
 
 Lesions.^ — The first changes in the skin will be the formation of 
 small nodules, which ma}'- be felt by the hand as it is passed over the 
 skin's surface. At these locations small crusts are formed about the 
 tufts of 2natted hairs, which are easily removed, leaving a moist and 
 reddened surface. From the nodules small papules develop, the epider- 
 mis being raised by the subepidermic serous effusion. These rupture, 
 and the desquamated surface gradually dries, leaving a scaly formation 
 upon the skin. With the extension of these lesions the hair falls out in 
 patches, the affected areas becoming confluent and covered by dry 
 
 Fig. 65. — Burrow of sarcopt in human skin, with eggs and mite (after 
 Osborn, from Furstenburg and Murry; Bureau of Entomology, U. S. Dept. 
 of Agr.). 
 
 epidermic scales and thin crusts. Soon following upon this stage the 
 skin thickens and forms into folds, especially over the parts where it is 
 freely movable, as about the throat, neck and breast. When these 
 folds are separated the skin between them is found to be in a raw and 
 purulent condition, bleeding at the slight touch of an instrument or 
 of the finger nail. In neglected cases the body may become almost 
 entirely denuded of hair and the thickened skin covered everywhere with 
 crusts, bleeding fissures, and ulcers, the animal presenting a most 
 miserable appearance (Fig. 66). The alterations m the skin are not all 
 directly brought about bj' the parasites, being contributed to by the 
 violent rubbing of the animal in its efforts to relieve the itchmg. Excoria- 
 tions with the formation of hemorrhagic exudations and ulcers are often 
 an accompaniment from this cause. 
 
 Diagnosis and Development. — AVith these symptoms in their early 
 
106 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 or late stages, the diagnosis of sarcoptic mange may be made positive 
 by the recovery of the Sarcoptes. This should be looked for as soon as 
 the presence of mange is suspected, as it is important to know with what 
 form of the disease we have to deal. The nymphte and pubescent males 
 and females live upon the body surface and among the crusts over all 
 affected parts. Innnediately after they become impregnated the oviger- 
 ous females burrow galleries beneath the epidermis in which they deposit 
 their eggs and live for a time with the young larva? (Fig. 65) . In man the 
 course of the galleries is marked by fine red lines from 8 to 15 mm. or 
 more in length, but in the horse these cannot be seen owing to the 
 thickness and pigmentation of the epidermis. The sarcopt is usually 
 lodged at the extreme end of the channel in the course of which her eggs 
 
 Fig. 66. — Colts affected with advanced sarcoptic mange (from author's i)hotograph) 
 
 are distributed. It has been estimated that approximately fifteen in- 
 dividuals will be produced in each of these subepidermic burrows, and 
 that about fifteen days are required, under average conditions, for their 
 full development and the appea^rance of the next succeeding generation. 
 The larvae issuing from the eggs live in the gallery for some time before 
 finally making their exit along its course, while the parent female soon 
 dies after ovulation is completed. Copulation takes place upon the 
 skin beneath the crusts, the males dying after the performance of this 
 function. As the males are also relativeh^ less in number, it is the fe- 
 males which are more often met with. 
 
 To secure the parasite for examination the crusts should be removed 
 and skin scrapings taken in such a manner as to include a portion of 
 serous exudate with the epidermic scales. The material should be taken 
 from a part showing evidences of recent attack, the mites being more 
 hkely to be found there than in the older lesions. This material, to- 
 
THE MITES 107 
 
 gether with a few flakes from the deeper portion of the crust, may then 
 be placed upon a gkiss and teased in glycerin. After having been 
 sufficiently divided and spread by the needles, it is ready for examination 
 under the low power of the microscope, or by a strong hand lens. It is 
 often necessary to thoroughly search several preparations before finding 
 the acarus. The material can be more easily teased and cleaned up if 
 submitted for an hour or two to the action of a five to ten per cent, 
 solution of caustic soda. 
 
 A method commonly used in the Laboratory of the Pennsylvania 
 State Bureau of Animal Industry for the detection of scab acari is as 
 follows: Cover the material with a ten per cent, solution of sodium 
 hydrate and set aside for one or two hours. Heat to boiling and cen- 
 trifuge for twenty minutes. The liquid is then carefully drawn off, 
 water added, and the sediment shaken up. This is agam centrifuged, 
 water drawn off, and fresh water added in which the sediment is again 
 washed and centrifuged. The sediment is then thinly spread upon 
 slides and examined under low power. By this treatment the scabs and 
 crusts are thoroughly disintegrated. Some of the mites may also be 
 fragmental, but not to such an extent as to prevent recognition of the 
 species. 
 
 Prognosis. — Owing to its great contagiousness and the difficulty in 
 reaching the parasites, sarcoptic acariasis is the most serious of the 
 three forms which may affect the horse. Early in its course the con- 
 stantly tortured and unpresentable animal becomes unfit for work, and, 
 when the disease is advanced, the skin lesions are accompanied bj^ 
 anaemia, emaciation, and a general debility that may terminate in death. 
 As in other parasitic skin diseases, vigorous animals in good condition 
 are more resistant and are more easily cured than those unthrifty or old 
 and emaciated. 
 
 Transmission. — The transmission of mange from horse to horse or 
 to asses and mules takes place by contact of individuals and by numerous 
 ways in which the parasite can be transported, as by litter, grooming 
 utensils, harness, clothing, or any object upon which the affected animal 
 has rubbed. Its contagion is modified considerably in relation to the 
 stage of the disease. Early in its course the acari have little tendenc}^ 
 to leave their host, but after one or two generations, with the formation 
 of the typical skin lesions, they emigrate readily, either directly or in- 
 directly, from one animal to another. 
 
 Mange of the horse can be transmitted to man and, reciprocally, 
 that of man to the horse, though such cases are rare. In either event the 
 parasite does not find a favorable soil for its multiplication, and the 
 invasion is but transient, such affection as it produces usually yielding 
 promptly to treatment or spontaneously disappearing in a few weeks. 
 It is doubtful whether this mange can be commimicated to other animals; 
 
108 PARASITES OF THE DOMESTIC ANIMALS 
 
 varieties of the sarcopt accidentally conveyed from their natural to a 
 foreign species of host meet with an unfavorable habitat and, if cutaneous 
 manifestations follow, it may be assumed that they must in any case be 
 slight and of relatively short duration. 
 
 Psoroptic Scabies of the Horse. — Psoroptic scabies generally appears 
 about the regions of the longest hair, as at the base of the forelock, mane, 
 and tail. It at once gives rise to pruritus, which is accompanied by 
 rubbing and matting of the hairs as in mange, with which form it is 
 somewhat similar as to its course and alterations. It spreads much 
 more slowly, however, and rarely involves the whole surface of the 
 body. 
 
 The psoropt does not burrow beneath the skin's surface as does the 
 sarcopt, therefore it can be more easily found. The methods recom- 
 mended for securing the Sarcoptes will apply to the Psoroptes as well, 
 though to obtain the latter it is not necessary to go quite as deeply for 
 the material. In this connection it should be borne in mind that two 
 or all three forms of scabies may coexist on the horse. It is advisable, 
 therefore, in certain cases to look for the mite in material obtained from 
 various affected regions of the body, as from the base of the mane, fore- 
 lock, or tail, from the cheeks and breast, and from the lower parts of the 
 legs. 
 
 Lesions. — While the local alterations in psoroptic scabies are severe, 
 the pruritus intense, and the scabs generally thicker than in the sarcop- 
 tic form, it is a less serious affection in that the mites do not burrow, 
 and the lesions remain much longer localized. More easily and promptly 
 cured, it is not so frequently epizootic, and it is not as likely to spread to 
 other horses upon the same premises. 
 
 Transmission. — As to its transmissibility from the equine species to 
 other animals, what has been said relative to this of the Sarcoptes 
 applies also to the Psoroptes. 
 
 Chorioptic Scabies of the Horse. — This form of scabies begins on 
 the extremities, most often the hind feet about the fetlocks and pasterns. 
 From here it spreads to the hocks, or to the knees if from the fore feet, 
 sometimes extending further, but rarely as far as the bod}^ Like the 
 psoroptes, these mites seek the parts covered by long hair, therefore 
 horses with long fetlocks are predisposed to attack. 
 
 Symptoms. — The first symptom of the invasion is itching, which 
 the hoi'se manifests by stamping, kicking the side of the stall, efforts to 
 bite the legs, or rubbing them one against the other. This irritation 
 is especially noticeable upon the animal's return from work and at night 
 in a warm stable. Its true caiise is frequently overlooked in considering 
 it a vicious habit. 
 
 Chorioptic scabies is slow in development, and is most troublesome in 
 winter. This is probably due to the fact that the feet of horses at this 
 
THE MITES 
 
 109 
 
 time of the year are more exposed to mud and slush, bringing about a 
 macerated and inflammator}^ condition of the skin that favors the 
 multipHcation of the mites. 
 
 Lesions. — Shortly after the invasion an abundant epidermic des- 
 quamation is noticed among the hairs and over the skin. Tufts of 
 hair are easily pulled out, and patches appear where the skin is bare and 
 smooth. Later crusts form over a thickened and exudmg skin, which 
 in the hollow of the pastern becomes fissured and bleeding. 
 
 Diagnosis. — In view of the special seat of chorioptic scabies, other 
 parts not bemg involved, it is scarcely nec- 
 essary to confirm its differentiation from 
 other forms by the recovery of the mite. It 
 is important, however, to know whether 
 the case is truly one of scabies, and this 
 diagnosis can only be established with cer- 
 tainty by findmg the parasite. If present 
 it will be easih' found among the deeper 
 parts of the crusts and epidermic scales. 
 
 Prognosis and Transmission. — Foot 
 scab is less infectious and is accompanied 
 by less itching than the other forms. The 
 prognosis is also more favorable, since, ex- 
 ceptmg in rare cases, the disease is confined 
 to the lower parts of the legs and usually 
 to the hind legs onl}'. Again, unlike other 
 scabies, it has little if any general effect 
 upon the animal. It yields readily to suit- 
 able treatment, and it is not hkely that 
 horses recei\'ing proper care as to cleanli- 
 ness of the hair and skin will be attacked, 
 even though exposed to the infection. Its 
 transmission from animal to animal in the 
 same stable is usually bv bedding and 
 grooming utensils in the hands of careless 
 attendants. 
 
 Fig. 67. — Chorioptes communis 
 var. equi, female; ventral view. 
 
 Scabies of the Sheep 
 
 Sheep may be affected with the following forms of scabies, the first 
 mentioned being by far the most important in this animal : 
 
 1. Psoroptic scabies, due to Psoroptes communis, var. ovis. 
 
 2. Sarcoptic mange, due to Sarcoptes scabiei, var. ovis. 
 
 3. Chorioptic scabies, due to Chorioptes communis, var. ovis. 
 
 4. Folhcular mange due to Demodex follicidorum, var. ovis. 
 Psoroptic Scabies of Sheep. — Through its exten.sive prevalence 
 
no PARASITES OF THE DOMESTIC ANIMALS 
 
 among sheep, psoroptic scabies may be regarded, from an economic 
 standpoint, as the most important of all scabies affecting live stock. 
 That the disease has been known for many centuries is evident through 
 references to it in early writings, including the Bible. The relationship 
 of the mite to the disease, however, was not determined with certainty 
 until the nineteenth century, during the first half of which the complete 
 life cycle of the parasite was demonstrated. It was shown that mites, 
 like larger animals^ are the offspring of ancestors and are not of sponta- 
 neous origin or accidental occurrence. It was further proven by animal 
 experimentation that the mites were not present as a result of the scab, 
 as had been supposed by some, but that the scab resulted from the 
 presence of the mites and could be produced in no other way. 
 
 The psoropt of sheep scab (Figs. 68 and 69) lives upon the surface of 
 the body where it is most thickly covered with wool, as the back, sides, 
 and shoulders. From their seat of invasion the colonies will spread and 
 these areas may coalesce, involving large patches, though the regions of 
 short wool, as the belly and front of the chest, are rarely attacked. 
 
 Symptoms and Lesions. — The first indications of the disease are 
 rubbing and gnawing at the wool and general unrest caused by the itch- 
 ing. As the changes in the skin progress loosened tufts become raised 
 over the surface of the fleece. These tags are soon rubbed or pulled 
 away by the sheep, and the fleece over the affected parts becomes ragged 
 and matted, the skin finally becoming more or less bare and showing 
 at this stage a thickened, furrowed, and bleeding condition. 
 
 If the skin is examined before the shedding of the wool there will be 
 seen small yellowish nodules and papular elevations of the epidermis. 
 The latter with their serous exudate dry up, forming an accumulation 
 of fatty yellowish scales upon the skin and among the deeper parts of 
 the hairs. The papules are closer together as the punctures of the psoropt 
 become more numerous. As they become confluent the skin thickens, 
 and the drying exudate and papular debris form a massive yellowish 
 crust. This, as it increases layer by layer, envelopes and mats the 
 wool, lifting the fibers from their follicles and raising large bunches 
 above the surface of the fleece. These detached patches will soon fall 
 away, the denuded skin showing a variation of lesions common to 
 scabies. It will be thickened, cracked, and scabby, and there may be 
 here and there excoriations, with perhaps sloughing and ulcerated areas. 
 The acari forsake the more central and older lesions for the periphery 
 of the denuded patch where they may be found in large numbers at 
 the roots of the incrusted wool which in its turn will fall away. Due to 
 direct exposure to the atmosphere, old denuded or sheared areas dry 
 out and become uniformly covered with a dry parchment-like crust 
 beneath which the skin is thickened and fissured. 
 
 Course and Prognosis. — The course and termination of the disease 
 
THE :mites 
 
 111 
 
 will be influenced by age, condition, character of fleece, and the con- 
 ditions under which the sheep are kept. Animals debilitated from age, 
 
 Fig. 68.— PsoroiJt 
 (right) surface. 
 
 fpmalo; dorsal (left) and ventral 
 
 or other cause, offer little resistance, while lambs, due to the tenderness 
 of their skin and their dense fleece, are apt to be attacked more severely. 
 Sheep with a close wool, as the pure or grade merino, afford an ideal 
 habitation for the rapid multiplication of the parasites. The contagion 
 
 Fig. 69. — Psoroptes communis var. ovis, male; dorsal (left) and 
 ventral (right) surface. 
 
 of any form of acariases in sheep is facilitated by their habit of living 
 in flocks. The disease is, therefore, much more serious in winter when 
 the animals are huddled together, especially making rapid progress if 
 
112 PARASITES OF THE DOMESTIC ANIMALS 
 
 the quarters in which they are collected are damp and hot. In summer, 
 after shearing and turning upon pasture, it rapidly subsides, in some 
 cases even seeming to disappear. 
 
 Psoroptic scabies in sheep, if unchecked, will have a fatal termination. 
 Death is preceded by denudation of the greater part of the body, emacia- 
 tion, anaemia, and a progressive weakness. The course is often rapid 
 in stabled sheep and those predisposed; within one or two months it 
 may have spread over the greater part of the body, while, on the other 
 hand, the disease may last in a more or less severe form for a year or 
 more. 
 
 Transmission. — Sheep scab cannot be transmitted to other animals, 
 nor can psoroptic scabies of other animals be transmitted to sheep. 
 
 Sarcoptic Mange of Sheep. — Sheep are rarely affected with this 
 form. When it occurs it can at once be distinguished from psoroptic 
 scab by its location, which is exclusively upon parts of the body covered 
 with short hair. It usually has its beginning about the upper lip or 
 nostrils, extending from here to other parts of the face and to the eye- 
 lids and ears. In cases of long standing it may spread to the belly and 
 inner sides of the front and hind legs. 
 
 Prognosis. — The course of the disease with its typical skin altera- 
 tions has already been described under Sarcoptic Mange of the horse. 
 It is much less serious in sheep than in the horse, however, and if taken 
 before it has spread extensively, yields easily to treatment. 
 
 Transmission. — Sheep and goats transmit sarcoptic mange recipro- 
 cally. It has been reported as having been conveyed from these animals 
 to man, but such cases, if ever occurring authentically, should be ex- 
 tremely rare. 
 
 Chorioptic Scabies of Sheep. — As in the horse, chorioptic scabies of 
 the sheep begins in the hind fetlocks and pasterns where it is charac- 
 terized by a redness of the skin and the presence of fine epidermic scales. 
 There is considerable itching, causing the animals to stamp their feet 
 and bite at the infected parts. Later yellowish crusts appear which 
 thicken, and the skin becomes cracked and bleeding, especially about 
 the folds of the pastern. Only rarely does the affection pass to the fore 
 legs or upward to the udder in the ewe, or to the scrotum in the ram. 
 
 Prognosis and Transmission. — Again, as in the horse, the Chorioptes 
 are not inclined to migrate, and the scabies they produce is but sHghtly 
 contagious. It yields promptly to cleanliness and proper treatment, 
 subsiding almost entirely when the flock is turned upon grass in the 
 spring. 
 
 Follicular Mange of Sheep. — -The follicular mite occasionally in- 
 vades the eyelids of sheep. Few such cases have been recorded, however, 
 and, in this country at least, follicular mange is of little importance to 
 flock owners. 
 
THE MITES 113 
 
 Scabies of the Goat 
 
 Goats may l^e affected by three forms of scabies, — sarcoptic, psoroptic, 
 and chorioptic. The first mentioned is the most frequenth' met with in 
 these animals, having its seat, as in sheep, mainly about the face. The 
 other forms are rarely met with in goats. Psoroptic scabies attacks the 
 external ear, forming dark-colored, fungus-Uke scabs. Chorioptic scabies 
 is said to have its beginning on the sides of the neck and withers and 
 along the back. 
 
 Scabies of Cattle 
 
 Three forms of scabies affect cattle. These are as follows: 
 
 1. Psoroptic scabies, due to Psoroptes communis, var. botis. 
 
 2. Chorioptic scabies, due to Chorioptes communis, var. boms. 
 
 3. Sarcoptic mange, due to Sarcoptes scabiei, var. boiis. 
 
 Scabies is less frequent in cattle than in horses and sheep, in North 
 America being most often met with in the range herds of the West and 
 Northwest. In this country the psoroptic is probably the most fre- 
 cjuent form. 
 
 Psoroptic Scabies of Cattle. — This usually has its l)eginning upon 
 the sides of the neck and shoulders, at the base of the horns, or it ma\' 
 be at the root of the tail. From these points it usually advances along 
 the back, passing to the sides, and in severe cases eventually involving 
 the greater part of the body. In its s^^nptoms, course, and skin altera- 
 tions it is in all essential respects analogous to the same form of scabies 
 in the horse. The pruritus is intense, the animal rubbing and scratching 
 itself in every way possible, often causing Ijloody excoriations of the 
 skin. As the disease advances an extreme cachexia sets in, and the 
 anaemic and much weakened animal may die in a most miserable con- 
 dition. 
 
 Such cases are most likely to occur al^out the close of the winter 
 months, especially in cattle stabled or herded together in wami quarters. 
 While upon grass, though the infection may remain, its symptoms sub- 
 side, and in the falling away of the scabs with renewal of the coat, may 
 even seem to have entirely disappeared. 
 
 Calves, yearlings, and two-year-olds suffer most, and it is among 
 these that there is more likely to be a fatal termination. 
 
 Chorioptic Scabies of Cattle, — This form in cattle is commonh- 
 known as tail mange. It generally appears in the depressions at the 
 base of the tail where as a rule it remains localized. If neglected it may 
 spread to the loins, perineum, and inner surface of the thighs, or even 
 over a considerable surface of the body, though such cases are rare. It 
 is exceptional for mange to appear in the feet of cattle. 
 
 Its course is the usual one of chorioptic scabies. The itching is mod- 
 
114 PARASITES OF THE DOMESTIC ANIMALS 
 
 erate, and the skin becomes covered with fine, dry scales, later becoming 
 denuded, fissured, and scabby. 
 
 It is but slightly contagious and, except in cases of extreme neglect, 
 has little tendency to spread upon the body. Where it seems to progress 
 beyond the limits usual to the choriopt, it should be determined whether 
 or not psoroptic scabies is coexisting with it — a condition which is 
 quite possible. If this is suspected, material from several affected 
 locations should be examined for recognition of the infecting species. 
 
 Sarcoptic Mange of Cattle. — Mange of the ox due to Sarcoptes need 
 be no more than mentioned here. Probably in every case where it has 
 occurred it has been by transmission from animals more likely to har- 
 bor this species, as the horse or goat. In bovine animals the disease is 
 usually of short duration, showing less tendency to spread and yielding 
 more promptly to treatment than in the horse. It affects chiefly the 
 skin about the eyes and cheeks and may extend to the sides of the 
 neck. 
 
 Mange of the Hog 
 
 Two kinds of mange affect the hog. These are as follows : 
 
 1. Sarcoptic mange, due to Sarcoptes scabiei var. suis. 
 
 2. Follicular mange, due to Demodex folliculorum var. suis. 
 Sarcoptic Mange of the Hog. — Sarcoptic mange is considered to be 
 
 the most common form in these animals. The infecting sarcopt is the 
 largest variety of the species and may be seen with the unaided eye as a 
 minute moving speck among the removed cutaneous debris. 
 
 Symptoms. — The presence of the disease is first shown upon the 
 skin about the eyes and ears, from which points it spreads to the back 
 of the neck, withers, shoulders, and back, later, if unchecked, invading 
 the greater surface of the body. The pruritus is extremely severe and is 
 especially aggravated in animals subjected to the body heat of crowded 
 pens. With the extension of the itching nodules the bristles fall out, 
 and the skin becomes wrinkled and covered with brownish or dark 
 gray crusts. Within the folds the skin presents the morbid changes 
 usual to sarcoptic mange; it is fissured and bleeding and there may be 
 ulcerations. 
 
 Young pigs and those with a thick curly growth of hair suffer the 
 most. The condition j-etards development and fattening, and severe 
 cases may lead to general debility and death. 
 
 Transmission. — Contagion is by contact of the animals with each 
 other, essentially facilitated when crowded together in pens or lots. 
 Because of the habit these animals have of rubbing their bodies, ob- 
 jects upon which infected hogs have scratched are especially a source of 
 transmission. 
 
 This mange of the hog may be transmitted to man and to the dog and 
 
THE MITES 115 
 
 possibly also to the horse, but the eruption produced iu such cases dis- 
 appears spontaneously in a few days. 
 
 Follicular Mange of the Hog. — Demodex being more difficult to 
 recognize, its j^resence in the skin of pigs probably occurs more often 
 than is generally supposed. The skin alterations which the follicular 
 mites bring about in these animals is comparativeh' slight and, as a rule, 
 are not such as to perceptibly interfere with general health or growth. 
 The primary seat of invasion is usually the skin about the snout. The 
 lesions may extend to the cheeks and even to the neck and chest, though 
 such spreading of follicular mange in the pig is not often observed. 
 
 Maxge of the Dog 
 
 There are three forms of canine mange, as follows: 
 
 1. Sarcoptic mange, due to Sarcoptes scahiei var. canis. 
 
 2. Follicular mange, due to Demodex folliculorum var. canis. 
 
 3. Auricular mange, due to Otodectes cynotis. 
 
 Sarcoptic Mange of the Dog. — Sarcoptic is considered the most 
 conmion mange affecting the dog. Though it may first appear upon 
 any part of the body, it generally begins about the nmzzle, especially 
 upon the bridge of the nose or, not infrequently, around the eyes, at the 
 base of the ears, or upon the breast. As it spreads the ventral surface, 
 axilla, and thighs become involved, the morbid process extending with 
 such rapidity that by the end of a month it may cover the greater part 
 of the body. 
 
 Symptoms, Course, and Lesions. — In its symptoms, course, and 
 alterations sarcoptic mange of the dog is shnilar to that of the horse. 
 It is first manifested upon thin and unpigmented skin by little red points 
 which are soon converted into papules. These rapidly increase in num- 
 ber and, as they rupture and exude their serous contents, deposit a 
 scaly accumulation upon the skin followed by the formation of yellowish 
 gray crusts. As the disease progresses the denuded skin becomes 
 thickened, wrinkled, and excoriated, the cheeks, neck, and breast 
 especially exhibiting deep folds. The itching, always intense, is much 
 aggravated by an increase in the ])ody tempei-ature, as may be brought 
 about b}' running or warm quarters. 
 
 Where large areas of the body are involved in the disease, emaciation 
 and genei-al debility set in, the animal at times giving off an offensive, 
 mouse-like odor. Finally, if the animal is neglected or treatment is 
 unsuccessful, death will ensue by the end of two or three months from 
 the beginning of the invasion. 
 
 Transmission. — The facts of contagion pertaining to sarcoptic mange 
 of other animals apply to this disease of the dog as well. Young dogs 
 and those debilitated are predisposed to infection, though dogs of any 
 age or condition will supj^ort the sarcopt and readily develop the disease. 
 
116 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Follicular Mange of the Dog. — Demodectio mange, or the so-called 
 red mange of dogs, is of frequent and world-wide occurrence. The 
 lanciform mites enter the orifice of the hair follicle where they multiply 
 and occupy the follicle and sebaceous gland in large numbers, lying 
 closely pressed together and almost invariably with the mouth parts 
 directed toward the bottom of the folHcle (Fig. 70). In this location 
 they may be found in all stages of development, from eggs to sexually 
 mature individuals and ovigerous females. As a result of this con- 
 stant increase there is a dilation of the hair follicle and gland, the pres- 
 sure and irritation producing degenerative 
 changes in the lining epithelium of the 
 follicle and hair papilla which causes the 
 hair bulb to become loosened from its 
 attachment. 
 
 Symptoms and Course. — The degree of 
 irritation and extension of the -inflamma- 
 tory process to the surrounding tissue will 
 be influenced by the number and activity 
 of the mites. There may be no more man- 
 ifestation of their presence than a hyper- 
 secretion of sebaceous material. Where, on 
 the other hand, these causative factors are 
 sufficient to produce an acute inflammation 
 involving the surrounding derma, there 
 will be a dilation of the contained blood 
 vessels with increased formation of epi- 
 dermic cells. Increased desquamation of 
 the surface cells follows, and later there is 
 an invasion of pyogenic organisms into the 
 inflamed and dilated follicles, resulting in 
 the formation of pustules and in some cases large abscesses. 
 
 Though follicular mange, owing to its resistance to treatment and 
 general septic intoxication, frequently terminates in death, its course 
 at the commencement is very slow. In its early manifestations there are 
 merely somewhat reddened areas, usually of the skin about the eyes, 
 breast, elbows, or it may be at the toes. As the hairs fall away small 
 papules are observed, and the affected patches become covered with 
 fine, powder-like scales. The infection is extended by the mites aban- 
 doning the originally invaded follicles and entering the surrounding 
 healthy ones, the spreading being aided somewhat by the rubbing and 
 licking of the animal. As new parts are invaded the skin becomes de- 
 cidedly red and, especially about the cheeks and breast, thickened, 
 wrinkled, and crusty; the eyelids are swollen and covered at their borders 
 by a purulent discharge. 
 
 m 
 
 Fig. 70. — Demodex folliculo- 
 rum: a, mite greatly enlarged; b, 
 mites in hair follicle and seba- 
 ceous gland — enlarged (after Os- 
 born, from Murry, Bui. No. 5, 
 Bureau of Entomology, U. S. 
 Dept. of Agr.). 
 
THE MITES 117 
 
 The disease finally becomes generalized, the skin everywhere ex- 
 hibiting the lesions in their various stages, and, with it all, exhaling a 
 disgusting odor. The pruritus increases, though it remains somewhat 
 intermittent, and at no time is as severe as in sarcoptic mange. With 
 the generalization of the malady its effect upon the whole animal or- 
 ganism is well estal)lished. The appetite is lost and emaciation ad- 
 vances, the subsequent marasmus leading to a fatal termination. 
 
 Transmission. — Due to the intra-cutaneous location of the parasites, 
 follicular mange is not as contagious as other forms; furthermore a pre- 
 disposition is necessary for its development, and this is fomid in young 
 and short-haired animals. Adult dogs with healthy skins are rarely 
 attacked. 
 
 Whether the dermatitis in follicular mange is primarily due to the 
 presence of the Demodex may be questioned. The assumption that this 
 mite is present in the hair follicles of all dogs needs the support of 
 further investigation. Accepting it from clinical observation as a proba- 
 bility — and with the predisposing factors of other forms of acariasis in 
 mind — there seems good reason to suppose that the mites, living, we 
 may say, as commensals, find in erythematous and eczematous skins 
 surroundings favoring their nutrition and more rapid multiplication, 
 thus bringing about the secondary severe dermatitis of follicular mange, 
 the pyodermatitis resulting from subsequent intra-follicular invasion 
 by pyogenic organisms. 
 
 Auricular Mange of the Dog. — Otacariasis is of comparatively fre- 
 quent occurrence in dogs, by reason of its contagiousness, being most 
 often met with in hounds kept in packs. Symptoms of the presence of 
 the mites are frequent scratching and flapping of the ears, which may 
 be accompanied by whining and howling. Epileptiform seizures are 
 not infrequently an accompaniment, these especially likelj' to occur 
 when the animal is running. On examination the auditory canal is 
 found to contain an adherent, soot-colored powder and a fetid wax 
 which may be in sufficient abundance to produce deafness by obstruc- 
 tion of the canal and pressure upon the t^nnpanum. An examination of 
 this material mider magnification will reveal the Otodectes in large 
 numbers. 
 
 Prognosis. — Otacariasis yields readily to treatment, but if neglected 
 may have serious consequences. The animal may die during an attack 
 of con\'T.i]sions or, if it survive, be rendered useless as a hunter. 
 
 Mange of the Cat 
 
 The cat may be affected with the two following forms of mange : 
 
 1. Notoedric mange, due to Notoedres cati var. cali. 
 
 2. Auricular mange, due to Otodectes cynotis. 
 
118 
 
 PARASITES OF THE DOMESTIC ANI]\L\LS 
 
 Notoedres cati, var. cati (Sarcoptes minor var. cati, Fig. 71), the 
 
 dwarf sarcopt, is a small species having the body nearly spherical. The 
 
 dorsal folds of the integument are circular. The anus is dorsal. There 
 
 are six anterior dorsal spinules and but twelve 
 
 ^ r 1 posterior. The arrangement of the stalked 
 
 u \ j^ suckers is the same as in Sarcoptes scabiei. 
 
 ^ «|b^^ A<^ Course and Diagnosis. — Notoedric mange 
 
 /^d^^^Hkfi^ of the cat usuall}^ begins about the ears and 
 
 ^^^^^^^^^ upper part of the neck, extending over the 
 
 ^^^^^^^^H forehead and then over the head generally. 
 
 ^^^^^^^^H As a rule it remains limited to these regions, 
 
 ^^^^^^^^^V"^ rarely passing to the body. The disease fol- 
 
 y^^^H^^^^ lows the usual course and alterations of sar- 
 
 f^^Ktl^^ \ Coptic mange, the cat giving evidence of the 
 
 I / \ \ intense itching by frequently shaking the head 
 
 / \ \ and wiping it with its paws. In neglected 
 
 I cases animals may become much emaciated 
 
 Fig. 71.— Genus Notoedres. and may die in a few months. 
 
 Due to the wrinkled, papular, and crusty 
 skin and its persistency of location upon the head, the diagnosis of 
 this mange on the cat is not difficult. Its differentiation from other 
 itching skm diseases may be made certam by the discovery of the para- 
 site, which is readily obtained in 
 material scraped from beneath the 
 crusts. 
 
 Auricular Mange of the Cat. — 
 Auricular mange seldom occurs in 
 the cat. It is caused by the same 
 species of mite causing auricular 
 mange of the dog and is similar in 
 its symptoms and course. 
 
 Scabies of the Rabbit 
 
 Two species of scab mites afflict 
 
 the rabbit, — Notoedres cati var. cuni- fig. 72.— Psoroptes communis var. 
 
 ■culi and Psoroptes communis var. cunicuii (from photomicrograph of 
 
 .CUnicidi (Fig. 72), the latter CaUS- counted specimen, by Hoedt). 
 
 ing auricular scabies or psoroptic otacariasis. 
 
 In the rabbit notoedric mange most often has its beginning about the 
 nose, from which it extends to the upper part and sides of the head where 
 it remains localized. Its location, symptoms, and course are similar to 
 those of the same form of mange in the cat. 
 
 Auricular scabies of the rabbit commences deep in the concha, grad- 
 ualty involving the skin of the entire inner side. Its presence is first 
 
THE MITES 119 
 
 indicated by the pruritus which the animal indicates by tossing its head 
 and scratching the ears with the hind feet. If the deeper parts of the 
 ear are examined early in thfe disease there will be found a yellowish, 
 fetid matter in which many of the mites may be seen with the aid of a 
 hand lens. At the end of a few months the greater part of the inner 
 side of the ear becomes covered with a thick layer of scabs in which the 
 Psoroptes are literally swarming. Usually they remain localized to the 
 ear, rarely invading surrounding parts. 
 
 In prolonged cases of auricular scabies rabbits lose their appetites 
 and become emaciated, diarrhea sets in, and the animals finally die in 
 an advanced state of cachexia. 
 
CHAPTER XI 
 
 TREATMENT OF MANGE AND SCABIES 
 
 General Considerations. — Methods of treatment of scabies will vary 
 according to the form of the disease to be dealt with and also according 
 to the kind and number of animals to be treated. As a general rule the 
 application of acaricides should be preceded by clipping the hair from 
 either a part or the whole of the body, dependmg upon whether the 
 affection is localized or general. The crusts should then be softened and 
 removed by washing with warm soapsuds and a stiff brush, after which 
 the remedy chosen may be applied. 
 
 The whole process is to be repeated in ten to fourteen days in order to 
 destroy mites from eggs which escaped the first treatment. It is im- 
 portant that there should be clean surroundings and, especially where 
 emaciation is an accompaniment, an abundance of nutritious food. 
 Sarcoptic mange will require more energetic remedies than other 
 forms where the mites live upon the surface and among the crusts of 
 the skin. 
 
 Internal medication is of little or no value. A cure can only be reached 
 by the destruction of the acari, accomplished by the local application of a 
 suitable acaricide. In the use of such agents their irritant or possible 
 toxic effects upon the animal treated are to be borne in mmd. To avoid 
 a sudden and general checking of the cutaneous functions, oiatments 
 and oleaginous materials are not to be spread over the entire body at 
 one application, nor should the body be dressed over more than one- 
 fourth to one-half of its area with preparations containing carbolic acid, 
 creosote, cresol, tobacco, or other such ingredients. Those containing 
 mercury or arsenic, in addition to these limitations, should never be 
 used upon animals such as cattle, dogs, and cats as these animals will 
 lick the dressed parts. 
 
 Where large numbers of animals are affected in a flock or herd, in- 
 dividual treatment involvmg clipping, scrubbing, and the application 
 of remedies by hand, is not practicable. In such cases a method of 
 dippmg must be resorted to. It is essential to the success of the treat- 
 ment that thorough disinfection measures be applied to surroundings 
 and to such portable paraphernalia as may serve as a means of reinfec- 
 tion. In this connection it should be borne in mind that the mites may 
 live from two weeks to a month or more ofT a host, the longer periods 
 usually amid favorable conditions, such as warm stables and blankets. 
 
TREATMENT OF MANGE AND SCABIES 121 
 
 The treatments given l^elow deal successiveh' with the chfferent forms 
 of the disease and embody such modifications as may be required for 
 the various domestic mammals. 
 
 Treatment of Sarcoptic ^Iaxge 
 
 Treatment of Sarcoptic Mange of the Horse. — Affected animals 
 should be isolated in quarters where they will not be in contact with 
 each other. Unless the disease is distinctly localized it is better to clip 
 the hair from the entire body; its removal will often reveal the lesions 
 over areas otherwise unsuspected. The clipping is not to be done in 
 the stable or in a wind that will scatter the hairs about. All of the 
 hairs should be carefully collected and burned. 
 
 The next procedure is the removal of the crusts in order that the 
 remedy- used may be applied directly to the skin. This is best accom- 
 plished by the use of soft soap well rubbed upon the scabby surface. A 
 thick lather is then formed by the application of a limited quantity of 
 warm water. This should be well worked into the crusts with a brush 
 and allowed to remain for an hour. The softened crusts may then be 
 removed with a brush or, better, a wooden scraper and warm soapy 
 water, and the body finally rinsed with clear tepid water applied with a 
 sponge. The scraping process should be done gently and in a manner 
 that will add as little irritation as possible to an already inflamed 
 skin. After the skin has Ijecome perfectly dry it is ready for the remedy 
 which is to be applied with a view to the destruction of the parasites. 
 
 There are a number of such remedies in the use of which practitioners 
 have had a varied experience. Creosote is among the most effectual. 
 It may be used in any of the following combinations: (1) Creosote one 
 part, oil sixteen to twenty parts; (2) creosote one part, oil of tar and soft 
 soap of each ten parts; (3) creosote five parts, alcohol five parts, water 
 twenty parts. With either of these not more than half of the body 
 should be dressed at alternate periods of six days until the entire body 
 has had two or three applications. It should be applied by rubbing. 
 
 Other remedies which have given satisfactory results are: (1) Lime 
 and sulphur dip (Formula No. 1, page 125), two or three applications at 
 intervals of one week; (2) creolin and soft soap, of each one part, alcohol 
 eight parts. Rub upon one side of the body on alternate days; after the 
 body has had three applications rest three days and repeat ; (3) decoction 
 of tobacco five per cent. Apply over one-fourth to one-third of the body 
 each da^-; repeat three or four times at intervals of one week. 
 
 Unctuous and oily preparations are to be preferred to the more fluid 
 ones as they are more penetrating and, adhering to the skin, their action 
 is prolonged. For this reason they are especially better suited for the 
 treatment of sarcoptic mange. The lime and sulphur preparation is, 
 
122 PARASITES OF THE DOMESTIC ANIMALS 
 
 however, much used and is said to give excellent results. Cure will 
 not be complete until all of the mites have been destroyed. Animals 
 should therefore be kept under careful observation for some time after 
 treatment for the detection of suspicious sjanptoms, such as itching. 
 Such cases may be checked at their inception by less drastic measures 
 than at first employed. Often a few applications of mercurial ointment, 
 or equal parts of oil and oil of tar containing ten per cent, of carbolic 
 acid, rubbed over the limited area, will be sufficient. 
 
 To prevent the reappearance of the disease it is obviously essential 
 that harness, clothing, groommg utensils, and all other articles which 
 may act as vehicles for reinfection, be disinfected. This is best done 
 with boiling water. Articles which might be injured by this treatment 
 may be washed with a strong solution (ten per cent.) of lysol or creolin. 
 
 Treatment for mange given at the close of the winter months should 
 be repeated in the fall, even though the disease has been apparently 
 cured. This is a precautionary measure to destroy the few mites which 
 may have survived upon the animal during the summer, and which 
 may again produce the disease under the more favorable conditions for 
 their reproduction which prevail during the fall and winter months. 
 
 Treatment of Sarcoptic Mange of the Hog. — Where but few animals 
 are to be treated they should first be thoroughly cleaned by scrubbing 
 with soap and warm water and the skin rinsed and dried. 
 
 The following ointments have been recommended for application 
 to the skin after it has been thus prepared: (1) Sublimed sulphur two 
 parts, potassium carbonate one part, lard eight parts (Helmerich's 
 pomade); (2) creosote one part, lard twenty-five parts; (3) sulphur ten 
 parts, lard thirty parts. These applications are to be repeated three 
 times at intervals of about five days. 
 
 Such methods, however, are out of the question where a large number 
 of animals is involved. In such cases dipping in a liquid preparation 
 is the only practical form of treatment. For this purpose the following 
 lime and sulphur formula is recommended by the United States Bureau 
 of Animal Industry: 
 
 Flowers of sulphur 24 lbs. 
 
 Unslaked hme 10 lbs. 
 
 Water 100 gals. 
 
 Prepare as under lime and sulphur formulae for scab in sheep (page 
 125). 
 
 The hogs should be kept away from wallows for several days before 
 and after dipping. Each animal should be kept in the dip long enough 
 for the liquid to be well rubbed into the skin with a stiff brush, care being 
 taken that all parts of the body, including the head and ears, are reached 
 by the remedy. Animals should not be dipped in cold weather. 
 
TREATMENT OF MANGE AND SCABIES 123 
 
 Essentially, pens and yards must be cleaned up and all litter burned. 
 
 Treatment of Sarcoptic Mange of the Dog. — Dogs should be clipped 
 and the skin covered with a thick lather. A good apphcation for this 
 purpose is green soap dissolved in an equal quantity of alcohol. Let 
 this remain two to four hours, then remove the crusts with a brush and 
 warm soapy water. Rinse and allow the skin to become dry. One of 
 the following remedies may then be applied: (1) Creosote one part, oil 
 fifteen to twenty parts; (2) creosote one part, green soap and alcohol of 
 each eight parts; (3) subhmed sulphur two parts, potassium carbonate 
 one part, lard eight parts (Helmerich's pomade); (4) creolm one part, 
 alcohol fifteen parts; (5) Peruvian balsam two parts, creolin one part, 
 alcohol twenty parts; (6) naphthalin two parts, vaseline eight parts, 
 oil of th\ane and oil of lavender of each one part. 
 
 The last named mixture is soothmg to the skin, agreeable, and quite 
 suitable for small house dogs. It is not to be depended upon, however, 
 in old and generalized cases. To avoid a too generally irritant or toxic 
 effect the acaricide should be applied to not more than one-fourth to 
 one-third of the bodj^ each da^^ It should be applied freely and energet- 
 ically and left on for three or four days. It may then be washed off 
 with tepid soapy water. At the end of three or four days the application 
 is to be repeated m the same manner, and again repeated until there is 
 no further itching or formation of scabs. The animal should be pre- 
 vented from licking by fitting it with a broad collar or by binding the 
 mouth with tape. 
 
 Preparations of tar had better not be used upon dogs. Remedies con- 
 taining carbolic acid, mercurj", tobacco, and other poisons are also to be 
 avoided, as any measure adopted to prevent licking is liable to be de- 
 feated by the dog and a serious poisoning result. 
 
 The usual precautions as to cleaning up of surroundings should of 
 course be adopted here. 
 
 Treatment of Notoedric Mange of the Cat. — Cats rebel against and 
 actually suffer from washmg, therefore treatment of these animals is 
 limited to the use of ointments. The hair should be clipped from the 
 affected parts and a small amount of vaseline applied which may be 
 removed in an hour or two by rubbing with dry bran and a cloth, re- 
 moving in this operation as many of the crusts as possible. 
 
 The acaricide ointment best adapted to the cat is that of Helmerich, 
 consisting of sublimed sulphur two parts, potassium carbonate one part, 
 lard eight parts. The application of this is to be repeated at intervals 
 of four to six days until scab formation and itching have ceased. It 
 may be removed by rubbing in the manner already stated. Peruvian 
 balsam is perhaps more effective, but in cats may cause severe cerebral 
 disturbance followed by stupor and even death. If used at all it should 
 be with extreme caution. 
 
124 PARASITES OF THE DOMESTIC ANIMALS 
 
 Due to the usual location of notoedric mange of the cat upon the 
 head, the dressing is inaccessible to licking, though the pads of the feet 
 are likely to be applied to it and afterward licked. It is scarcely neces- 
 sary to say that preparations containing tobacco, carbolic acid, and 
 other poisons should be strictly avoided in the treatment of cats. 
 
 Treatment of Notoedric Mange of the Rabbit. — Remove the hair 
 from the affected area and for a considerable margin around it, apply a 
 lather of soft or green soap, allow to remain an hour or two, wash off, 
 and repeat as necessary to remove scabs. When the parts have be- 
 come dry, treat with the ointment of Helmerich as for mange of 
 the cat. 
 
 Treatment of Sarcoptic Mange of the Goat. — Clip the hair and 
 prepare the parts with soapy lather as directed for other animals. Treat 
 with a sulphur ointment or a preparation of creosote, as creosote one 
 part, oil fifteen parts. Repeat as previously directed. 
 
 Owing to the intractability of goats, dipping is attended with difficul- 
 ties and, furthermore, is badly borne b}^ these animals. 
 
 Treatment of Sarcoptic Mange of Sheep. — Remove crusts after 
 softening with a lather of soft or green soap, dry, and apply (1) creosote 
 one part, oil of tar and soft soap of each twenty parts; (2) sublimed sul- 
 phur one part, lard four parts, or (3) the ointment of Helmerich may be 
 used. Repeat as directed for other animals. 
 
 Treatment of Sarcoptic Mange of Cattle. — After clipping and prep- 
 paration of the skin by removal of the crusts as has been repeatedly 
 stated, apply the lime and sulphur mixture as given and prepared under 
 scab of sheep, repeating three or four times at intervals of five days. 
 Good results may also be obtained by the use of sulphur in the form of 
 an ointment, as one part of sulphur to four parts of hog's lard. Prepara- 
 tions containing such agents as creosote, lysol, or creolin are best limited 
 to cases confined to the head and upper parts of the neck, regions in- 
 accessible to the tongue. They may be used in the following combina- 
 tions: (1) Creosote one part, oil fifteen parts; (2) creosote one part, 
 oil of tar and soft soap of each fifteen to twenty parts; (3) creolin and 
 soft soap of each one part, alcohol eight parts; (4) lysol in five per cent, 
 solution. 
 
 All of these are to be washed off with soapy water after three days 
 and the treatment repeated as necessary. 
 
 Treatment of Psoroptic Scabies 
 
 Treatment of Psoroptic Scabies of the Sheep. — Proper hygienic 
 conditions and an abundance of substantial nourishment will do much 
 to protect sheep from the contagion of scab, but where it has made its 
 appearance in a flock such measures are only to be relied upon as con- 
 
TREATMENT OF MANGE AND SCABIES 125 
 
 tributing to a rational treatment designed to rid the sheep of the disease 
 by killing the parasites. The application l)y hand of either ointments, 
 fluid preparations, or powders for this purpose is practically useless. 
 The acaricide chosen for the treatment of psoroptic scabies of sheep 
 should be applied by dipping. It is better not to consume time, energy, 
 and patience upon remedies which are not or cannot be used by this 
 method. 
 
 Lime and Sulphur Dip. — Many formulae for dips have been pub- 
 lished, most of them containing lime, sulphur, tobacco, or arsenic as 
 their base. The term "lime-and-sulphur dip" does not refer to an 
 exact formula but includes a large number of formulae containing the 
 lime and sulphur in different proportions. While the ingrediants of a 
 dip should be in such proportion as to make it a reliable parasiticide, it 
 is essential that it should cause little or no harm to the sheep or fleece. 
 The subject of dips has been carefully gone into by the United States 
 Bureau of Animal Industry and the conclusion reached that probably 
 the most effective dips are those containing sulphur and tobacco, and 
 sulphur and lime of such strength that they are not injinious to the sheep 
 and of minimum damage to the fleece. Among the formulse for lime and 
 sulphur dips mentioned bv the Bureau are the following (Farmer's 
 Bull. No. 159) : 
 
 No. 1 
 
 Flowers of sulphur 24 lbs. 
 
 Unslaked lime 8 lbs. 
 
 Water 100 gals.. 
 
 No. 2 
 
 Flowers of sulphur 33 lbs. 
 
 Unslaked lime 11 lbs. 
 
 Water 100 gals. 
 
 For fresh scab, formula No. 1 will act as well as those with a greater 
 amount of lime. In old cases with parchment-like scab a stronger dip, 
 as formula No. 2, is to be preferred. 
 
 The following method of preparing the mixture is recommended l)y 
 the Bureau: 
 
 "A. Take eight to eleven pounds of unslaked lime, place it in a mortor 
 box, kettle, or pail of some kind, and add enough water to slake the lime 
 and form a 'lime paste' or 'lime putty.' 
 
 "Many persons prefer to slake the lime to a powder, which is to l)e 
 sifted and mixed with sifted sulphur. One pint of water will slake three 
 pounds of lime, if the slaking is performed slowly and carefully. As a 
 rule, however, it is necessary to use more water. This method takes 
 more time and requires more work than the one given above, and does 
 
126 PARASITES OF THE DOMESTIC ANIMALS 
 
 not give any better results. If the boiled solution is allowed to settle, the 
 ooze will be equally as safe. 
 
 "B. Sift into the lime paste three times as many pounds of Flowers 
 of sulphur as used of lime, and stir the mixture well. 
 
 "Be sure to weigh both the lime and sulphur. Do not trust to measur- 
 ing them in a bucket or guessing at the weight. 
 
 "C. Place the sulphur-lime paste in a kettle or boiler with about 
 twenty-five to thirty gallons of boiling water, and boil the mixture for 
 two hours at least, stirring the liquid and sediment. The boiling should 
 be continued until the sulphur disappears, or almost disappears, from 
 the surface, the solution is then of a chocolate or liver color. The longer 
 the solution boils the more the sulphur is dissolved, and the less caustic 
 the ooze becomes. Most writers advise boiling from thirty to forty 
 minutes, but the Bureau obtains a much better ooze by boiling from 
 two to three hours, adding water when necessary. 
 
 "D. Pour the mixture and sediment into a tub or barrel placed 
 near the dipping vat and provided with a bung hole about four inches 
 from the bottom, and allow ample time (two to three hours, or more if 
 necessary) to settle. 
 
 "The use of some sort of a settling tank provided with a bung hole 
 is an absolute necessity, unless the boiler is so arranged that it may be 
 used both for boiling and settling. An ordinary kerosene oil barrel 
 will answer very well as a small settling tank. . To insert a spigot about 
 three to four inches from the bottom is an easy matter. Draining off 
 the liquid through a spigot has the great advantage over dipping it out, 
 in that less commotion occurs in the liquid, which therefore remains 
 freer from sediment. 
 
 "E. When fully settled, draw off the clear liquid into the dipping 
 vat and add enough water to make 100 gallons. The sediment in the 
 barrel may then be mixed with water and used as a disinfectant, but 
 under no drcumstances should it be used for dipping purposes." 
 
 There are a number of good proprietary dips upon the market which 
 will l)e found convenient and effectual. No dip should be used, however, 
 unless the ingredients and their exact proportion are known to the user. 
 Secret formulse put out by irresponsible parties should be avoided. 
 
 Dipping Vats. — Where but few sheep are to be treated the dipping 
 arrangements may be quite simple. A tub or trough to which a draining 
 platform is attached will serve the purpose. A small vat, suitable for 
 dipping small flocks, may be constructed of wood or concrete. It should 
 be about nine inches wide at the bottom, four feet deep, and two feet 
 six inches wide at the top. Its length will depend upon the number of 
 sheep to be treated. A convenient length is nine feet at the top, the 
 floor having a length of four feet. From one foot above one end of the 
 floor an incline with cross cleats rises to the top end of the vat. From 
 
TREATMENT OF MANGE AND SCABIES 127 
 
 here the incHne may lead to a drippmg platform which maj' easily be 
 improvised for the purpose. This should be so constructed and applied 
 that the drip will flow back into the vat. 
 
 Plans for more elaborate dipping plants, suitable for large flocks, may 
 be obtained from bulletins issued by the Bureau of Animal Industr}', 
 United States Department of Agriculture. 
 
 To obtain the best results sheep should be sheared before dipping, 
 and the dip used at a temperature of 100° to 110° F. Keep each sheep 
 submerged two minutes by the watch, forcing the head under at least 
 once just before the animal comes out. The dips should be freshly 
 
 Fig. 73. — .\ small portable dipping vat for .small flock.s (from Bull. No. 21, 
 Bureau of .\n. Ind., Dept. of Agr.). 
 
 prepared for each dipping; if permitted to stand for repeated treatment 
 failures and possibly injurious effects may result. 
 
 Other Dips. — Tobacco dips, used either with or without sulphur, 
 are now nnich in use and give excellent results. Owing to the poisonous 
 character of nicotine, the active principle of tobacco upon which these 
 dips depend for their action, the exact nicotine content of the dip should 
 be known before it is used. This, according to the Bureau of Animal 
 Industry, should not exceed 0.07 of one per cent. Owing to the variation 
 of the percentage of nicotine in different kinds of tobacco and the added 
 reason that tobacco dips are somewhat tedious and disagreeable to 
 make, it is better to use a reliable tobacco extract, which may be ob- 
 tained upon the market, and exactly follow the instructions given for 
 the making of the dip. 
 
 Tobacco dip is not injurious to the wool, therefore it has an advantage 
 foi- use upon sheep which nuiy require treatment at a time when they 
 
128 PARASITES OF THE DOMESTIC ANIMALS 
 
 cannot be safely or profitably sheared. Its disadvantages are that it 
 sometimes causes a setback in the sheep by sickening them, and that it 
 also occasionally sickens persons who work with it, especially if they are 
 not tobacco users. 
 
 Dips containing carbolic acid are easily made and rapid in their action, 
 but soon evaporate from the body, leaving the sheep unprotected from 
 reinfection. Furthermore, in the strength at which it must be used as a 
 reliable acaricide, it causes the sheep to receive a greater setback than 
 they do with either the tobacco or lime and sulphur preparation. 
 
 After Treatment. — The dipping is to be repeated upon the entire 
 flock in twelve to fourteen days. Where it is necessary to place the 
 sheep in the same pasture which they occupied before being dipped, 
 sulphur should always be an ingredient of the dip. This remains upon 
 the skin and wool and protects from reinfection during the period that 
 the acari may remain infective. In any case it is better to place the 
 flock after the second dipping in a pasture which they have not been 
 upon for at least five weeks previous to their treatment. 
 
 Treatment of Psoroptic Scabies of Cattle. — As psoroptic scabies of 
 the ox may become generalized or remain localized upon parts of the 
 body easily reached by the tongue, mercurial preparations or those 
 containing other poisons which may be licked off should not be em- 
 ployed. Where one or two animals are affected upon limited areas of 
 the body, ointments of sulphur, such as flowers of sulphur one part, 
 lard four parts, may be used with good results. The remedy should 
 be preceded by the usual preparation of the skin. After three days it 
 can be washed ofT with soap and tepid water and the application re- 
 peated. 
 
 As a convenient, safe, and effective remedy probably the lime and 
 sulphur dip will give better satisfaction than any other for the treat- 
 ment of this form of scab in the ox. It should be prepared with the 
 proportion between lime and sulphur somewhat reduced, as by the 
 following formula: 
 
 Flowers of sulphur 24 lbs. 
 
 Unslaked lime 12 lbs. 
 
 Water 100 gals. 
 
 Mix according to directions given under lime and sulphur formulae 
 for scab in sheep (page 125). 
 
 Where a small number of animals are to be treated the dip may be 
 applied as a spray or with a brush, working it at the same time well 
 into the scabs. In larger herds this method is not practical, and the 
 animals must be treated by dipping. Even though few in the herd 
 give evidence of the disease, it is safer to dip all, as it is probable that a 
 number of the apparently healthy have become infected. 
 
TREATMENT OF MANGE AND SCABIES 129 
 
 Plants for dipping cattle range from the simple to the elaborate after 
 various plans. Directions and estimates for the construction of such 
 plants, together with much other valuable detail as to dipping, ma}' be 
 obtained from the Bureau of Animal Industry, United States Depart- 
 ment of Agriculture, upon application for bulletins relating to the sub- 
 ject (Bull. No. 152). 
 
 The temperature of the dip when used should be from 102° to 108° F. 
 Each animal should be kept m it two minutes and be completely sub- 
 merged before coming out. The treatment is to be repeated in twelve 
 to fourteen days. 
 
 After dipping the precautions against reinfection, already referred to 
 in connection with sheep scab, are to be observed. 
 
 Treatment of Psoroptic Scabies of the Horse. — The treatment of 
 this scabies of the horse does iiot differ materiall}^ from that given for 
 mange in the same animal. From the fact that the mites do not burrow 
 and thus obtain a degree of protection from the acaricide, it is easier to 
 control than the latter form. 
 
 The preliminary application of soap and water, as directed in the 
 treatment of mange, should be followed here, after which the same 
 general acaricide treatment may be employed. The lime and sulphur 
 preparation is probably of more use for this form of scab in the horse 
 than for the sarcoptic. It is prepared according to the formulae given 
 for scab in sheep (page 125), either formula No. 1 or formula No. 2 being 
 used, according to the age and extent of the lesions. It can be applied 
 as a spray or with a brush, being at the same time well worked into 
 the scabs. The treatment should be repeated at intervals of eight to 
 ten days until all indications of the presence of the mites have disap- 
 peared. 
 
 The precautions against reinfection, mvolving disinfection of harness, 
 clothing, stalls, etc., as given under equine mange, are to be observed. 
 
 Treatment of Chorioptic Scabies 
 
 Treatment of Chorioptic Scabies of the Horse. — Clip the hair from 
 over the affected parts, usually from the hocks down. It is well in any 
 case to treat the fore legs m the same manner as these may have been 
 infected. A portion of the scales and crusts may be removed with a 
 brush, after which the parts are to be rubbed with a lather of soft or 
 green soap. Let this remain for an hour, then rinse with tepid water, 
 scrape, and allow to dry. 
 
 The acaricides mentioned for the treatment of other forms of scabies 
 ui the horse will apply here as well. The fact that the affected area in 
 chorioptic scabies is usually limited to the lower parts of the legs per- 
 mits of the use of remedies which would not be safe for application over 
 
130 PARASITES OF THE DOMESTIC ANIMALS 
 
 lai'ger surfaces of the body. Strong tobacco decoctions, benzene, or oil 
 of turpentine may be used, the latter shaken up in an equal quantity 
 of linseed oil. Equal parts of kerosene and linseed oil also give good 
 results. Two or three applications of the remedy applied several days 
 apart usually suffices to bring about a complete cure. 
 
 The usual precautions against reinfection should be observed. The 
 bedding is to be burned and utensils disinfected. Animals should have 
 their legs regularly and carefully groomed, and attendants should 
 be on the lookout for sjanptoms of a return of the affection. 
 
 Treatment of Chorioptic Scabies of Cattle. — The curative procedure 
 for this scabies does not materially differ from that for bovine mange. 
 As chorioptic scabies appears upon parts which may be reached by 
 the tongue, preparations containing active poisons should be avoidecl. 
 Probably an ointment of sulphur, as sulphur one part, lard four parts, 
 or sulphur two parts, potassium carbonate one part, lard eight parts, 
 is most suitable for such cases. 
 
 Treatment of Follicular Mange 
 
 Treatment of Follicular Mange of the Dog. — Owing to the intra- 
 cutaneous location of the parasites, successful treatment of this mange 
 is made very difficult. The prospects for eventual success will depend 
 much upon patience and perseverance. It is important that the general 
 condition of the animal be built up as much as possible by nutritious 
 food and thoroughly sanitary surroundings. Such treatment as may 
 be adopted must be prolonged and often repeated if carried out to 
 effectiveness. The remedies given below for the destruction of the 
 mites are among those which have been tried. The best that can be 
 said for them is that they have sometimes given good results. 
 
 (1) Peruvian balsam 2 parts, creolin 1 part, alcohol 20 parts. An 
 objection to this remedy is its expense in view of the prolonged treat- 
 ment required. (2) Creosote 1 part, olive oil 15 to 20 parts; (3) benzine 
 1 part, olive oil 4 parts; (4) creolin 1 part, green soap and alcohol of 
 each 3 parts; (5) repeated applications over limited areas of tincture of 
 iodine. (6) In the clinic for small animals at the School of Veterinary 
 Medicine, University of Pennsylvania, some encouraging results have 
 been obtained from the use of ichthyol, prepared with lard or lanolin 
 in the proportion of one to seven. 
 
 Fleming advises that the topical treatment be accompanied by the 
 internal administration of sulphur in frequent and large doses; the sul- 
 phur being excreted to some extent by the skin. 
 
 Treatment of Follicular Mange of Swine. — Treatment of this form 
 of mange in the pig is rarely called for. If there are perceptible indica- 
 tions of its presence a treatment as recommended for dogs may be tried, 
 
TREATMENT OF MANGE AND SCABIES 131 
 
 though, due to the intractability and habits of pigs, there is probablj- 
 even less prospect of a complete destruction of the mites. The presence 
 of Demodex, however, is rarely recognized in pigs, and the effects it 
 may produce are far less serious than in dogs. 
 
 Treatment of Otacariasis of the Dog, Cat, and Rabbit 
 
 Clean the ears of dogs and cats thoroughly and deeply with olive oil. 
 It may be applied with a bit of cotton rolled upon a probe which should 
 be rotated as it enters the deeper parts. Nocard's treatment, as stated 
 by Neumann, is as follows: Naphthol 1 part, ether 3 parts, olive oil 
 10 parts. Inject into the external auditory canal each day. After in- 
 jecting close the canal for ten to fifteen minutes with a pledget of cotton. 
 This is to prevent the evaporation of the ether. The ether causes the 
 remedy to penetrate the wax>' Iming of the canal which contains the 
 parasites. 
 
 In the treatment of ra))bits the scabs are first to be softened by a 
 thick lather of soft or green soap which should be allowed to remain for 
 an hour, rinsed, and repeated as ma}' be necessary for deep crust forma- 
 tion. The deeper parts of the ear ma}' then be cleaned with olive oil 
 and cotton as directed for dogs and cats. 
 
 As an acaricide, the same treatment may be employed as recommended 
 for otacariasis in dogs and cats, applying the remedy with a pledget 
 of cotton over the whole inner surface of the concha as well as injecting 
 it into the auditory canal. An ointment of sulphur, or a liniment com- 
 posed of benzene and olive oil equal parts may also be used, either to 
 be applied with a pledget of cotton rolled upon the end of a probe or 
 stick. 
 
 It is a good precautionary measure to treat the ears of all rabbits 
 which have been exposed, as there ma}^ be infections of a latent char- 
 acter which will later bring about another outbreak of the disease. 
 
CHAPTER XII 
 
 MANGE OF POULTRY 
 
 The acari-prodiicing mange of fowls belong with the genus Cnemi- 
 docoptes, the characteristics of which are described on page 103. There 
 are two species, — Cn. mutans (formerly Sarcoptes mutans), which pro- 
 duces the condition known as scaly leg, and Cn. gallince {Cn. Icevis) 
 which attacks the skin at the attachment of the feathers. 
 
 Mange of the Legs (" Scaly Leg "). — The burrowing mite of leg 
 mange most often attacks the feet and legs of chickens of the heavier 
 breeds, as the Brahma, Dorking, and Cochin China, less frequently 
 turkeys, pheasants, and pigeons. 
 
 The mites live under the epidermic scales from the tarsal joint down- 
 ward, including the upper part of the toes. In this location iYiey deposit 
 their eggs and multiply, the irritation of their presence soon being 
 manifested by the formation of a white powdery matter which elevates 
 the scales. Due to the exuded serum, this matter assumes a lardaceous 
 nature, adhering to and soon covering the foot. Gradually rough crusts 
 are formed in the lower layers of which numerous mites may be found. 
 The scabs adhere closely to the skin, and, when removed, reveal an 
 irritated and bleeding surface (Fig. 75). 
 
 The course of the disease is slow, running several months to a 3'ear. 
 There is a moderate pi-uritus which the fowl indicates by restlessness 
 and picking at the scabs with the beak. As the crusts increase there 
 is a mechanical interference with flexion of the joints which makes 
 either moving about or standing difficult. As a consequence the animal 
 often squats down with the legs extended and remains in this position 
 with infrequent efforts to rise. In such severe cases arthritis is likely to 
 appear, and one or even all of the toes may drop off. When the disease 
 has advanced over several months we have the usual systemic accom- 
 paniment of prolonged mange; there is loss of appetite, cachexia, and 
 stupor which is usually followed by death. 
 
 Treatment. — Treatment must begin with softening of the scabs with 
 soft soap, appHed by hand or by soaking in warm soapj^ water. They 
 may then be removed by manipulation with the hands or with a brush, 
 care bemg taken in this operation to cause as little'injury to the skin as 
 possible. When the parts are dr,y, apply Peruvian balsam, either alone 
 or made up in the proportions of balsam 2 parts, creolin 1 part, alcohol 
 20 parts. The ointment of Helmerich, as recommended for scabies in 
 
IMANGE OF POULTRY 
 
 133 
 
 other animals, is one of the best remedies for this scab. Others perhaps 
 as effectual are (1) creosote 1 part, lard 20 parts; (2) benzene 1 part, 
 olive oil 10 parts; (3) carbolized vaseline (5%), or (4) an ointment of 
 carbolic acid 1 part, lard 20 parts. The stronger acaricides should not 
 be used upon young chicks. For these the ointment of Helmerich or 
 Balsam of Peru are quite suitable. The application may be washed off 
 and repeated as necessary'. 
 
 To prevent contagion and reinfection, diseased fowls should be re- 
 moved from the healthy and the quarters subjected to cleaning up and 
 disinfection, especial attention bemg given to roosts and other places 
 where the fowls are in the habit of perching. 
 
 Fig. 74. — Cnemidocoptes mutans, male and female (after 
 Osborn, Bull. No. 5, Bureau of Entomology, U. S. Dept. of Agr.). 
 
 Mange of the Body, or Depluming Mange. — The depluming mite, 
 Cnemidocoptes gallince, is closely related to the mite of foot mange and 
 it may easily be mistaken for the same species where the two forms of 
 mange coexist. The Ijody form usually has its begmning on the back, 
 near the msertion of the tail-feathers. More rarely the head and upper 
 part of the neck are first attacked. From these regions it spreads to 
 adjacent parts of the body. 
 
 The disease is accompanied by the production of an abundance of 
 epidermic scales, irritation, and itching which impels the fowl to pluck 
 at the feathers. These easily drop out or are broken off, leaving a bald 
 or partly denuded skin which is but little thickened and remams normally 
 smooth and elastic. 
 
 The acaricide treatment employed may be the same as for foot mange. 
 AVhere a numljcr of birds are affected they may be treated by dipping 
 for several successive days m a sulphur bath. The same precautions 
 against contagion and remfection are to be observed as for the leg form. 
 In this connection it is well to repeatedly disinfect the feet of roosters. 
 
134 
 
 PARASITES OF THE DOMESTIC ANIIMALS 
 
 Cytoleichus nudus. 
 
 as the disease is readily conveA^ed from the l^ack of one hen to another 
 in treading. 
 
 Family V. Cytoleichid^ 
 
 Acarina (p. 94). — This family contains two genera, Cytoleichus and 
 Laminosioptes, each with one species causmg a deep-seated acariasis m 
 birds. 
 
 C3^toleichidse (p. 134). — The body is rounded, 
 almost bald, and whitish in color. The 
 mouth parts are conical. The legs have five 
 articles and are strong and elongated; all 
 terminate by a simple stalked sucker. The 
 ovigerous female is 500 to 600 microns long 
 by 350 to 400 microns broad. She may pro- 
 duce either larvae or eggs. 
 
 Colonies of these parasites live in the air 
 passages and air sacs of fowl. 
 
 Laminosioptes cysticola. Cytoleichidae 
 (p. 134). — The body is twice as long as 
 broad; color grayish. On the dorsal surface 
 are several pairs of bristles, a long pair ex- 
 tending from the posterior extremity. The 
 mouth parts and the two first pairs of legs 
 are carried upon the anterior third of the 
 body which is separated from the posterior 
 portion by a transverse furrow. The legs 
 are short, smooth, and provided with 
 suckers, which are not permanent upon the 
 anterior pair. The ovigerous female is 250 
 to 260 microns long b^' 100 to 110 microns 
 broad. 
 
 Parasitic in subcutaneous connective tis- 
 sue of fowl. 
 
 The C3'toleichus species enter the respir- 
 atory passages and pass to the deeper air 
 channels, even to the air canals in the bones. 
 From their relatively large size and whitish 
 color they may be readily seen with the naked eye, usually in colonies 
 of more or less number. Ordinarily these parasites do not cause suf- 
 ficient disturbance to betraj' their presence during the life of their host. 
 If in exceptionally large numbers they maj' cause attacks of coughing 
 by irritation of the bronchial mucosa. 
 
 Laminosioptes cyUicola lives m the subcutaneous connective tissue, 
 especially in regions where this is loose, as the neck, breast, sides, and 
 
 Fig. 75. — Foot of fowl affected 
 with scaly leg. 
 
IMANGE OF POULTRY 135 
 
 thigh. Where nian}^ are present they cause irritation with the forma- 
 tion of yellowish, oval nodules. These are about 0.5 mm. by 1 mm. 
 in dimensions, and a large number of them may cover a small area. They 
 are soft, granular or calcareous, and may contam the dead parasites. 
 The health of the host does not appear to l)e affected by the lesions 
 which these parasites produce. 
 
CHAPTER XIII 
 
 THE TICKS 
 
 There has been considerable difference of opinion among various 
 authors as to the S3'stematic arrangement of the ticks. They have 
 been brought into one family, — Ixodidae, in which two subfamilies are 
 distinguished. — Argasinse and Ixodmse, and, again, these two subgroups 
 have been considered as distinct families. The arrangement adopted 
 here, which raises the ticks to the rank of a superfamily, is that of Banks 
 (1894) and as followed by Salmon and Stiles (1901). 
 
 Structure of Ticks in General. — The proper study and differentiation 
 of the ticks requires some knowledge of the external parts and an under- 
 standing of the teclmical terms which are used m reference to them. 
 Conformmg to the general characteristics of the order Acarma to which 
 they belong, the ticks have a body in which the cephalothorax and 
 abdomen are not demarcated and this bears certain structures possessing 
 variations as to location and form which serve as defining characters 
 for the various subgroups and species. The parts more commonly 
 referred to with their technical names follow : 
 
 1. The Capitulum (Fig. 76) is the "head," ''false head," or rostrum, as 
 it is variously termed. It projects from the anterior extremity in the 
 Ixodidae. In the Argasidae, except in the larval stage, it is upon the 
 under surface of the anterior extremity. The structure consists of a 
 number of parts, as follows : 
 
 (a) The Basis Capitidi (Fig. 76, b) is the hard base of the capitulum; 
 the basal ring or mouth shield. 
 
 (b) The Hijpostome (Fig. 76, h) or "labium" or "radula" of various 
 authors is a median ventral structure rising from the basis capituli and 
 bearing recurved teeth. 
 
 (c) The Chelicerce (Fig. 76, c), "mandibles," or "jaws" are paired 
 elongate structures, one on each side of the median line, lying dorsal 
 to the hypostome. Dorsal to these is the hood or sheath of the chelicerse. 
 
 The hypostome, chelicerse, and hood constitute the haustellum, or, as 
 it is commonly called, the "beak," and it is these structures which pen- 
 etrate the skin of the animal upon which the tick attaches. 
 
 (d) The Palpi (Fig. 76, p) are articulated structures, one on each 
 side of the haustellum, and inserted antero-laterally upon the basis 
 capituh. 
 
 2. The Scutum (Fig. 77), or dorsal shield — present in the Ixodidae, 
 
THE TICKS 
 
 137 
 
 Fig. 76. — Capitulum (rostrum), 
 of an argasid tick: h, hypostome; 
 c, chelicerae; p, palpi; b, basis 
 capituli. 
 
 absent in the Argasidae — is a hard, plate-Hke structure located inmie- 
 diately posterior to the capituhim. In the male it usually covers the 
 entire, or almost the entire, dorsal surface, 
 in n\nnphs it covers the anterior portion; 
 while in the adult female it is much smaller 
 and confined to the anterior portion of the 
 liody. 
 
 3. Dorsum. — This term refers to the 
 whole dorsal surface of the body. 
 
 4. Festoons (Fig. 82) are uniform rect- 
 angular areas into which the posterior mar- 
 gin of the body is divided up. Usually 
 eleven may be more or less distinctly rec- 
 ognized. They are most distinct in unfed 
 specimens, but almost or entirely disap- 
 pear in distended females. They are not 
 present m all forms. 
 
 5. Punctations are circular depressions 
 upon the integument from which fre- 
 quently issue hairs. 
 
 6. Ornamentation refers to enamel-like coloration which may be pres- 
 ent on the scutum, capitulum, or other parts. Ticks upon which this 
 coloration occurs are re- 
 ferred to as ornate. 
 
 7. Venter. — This term 
 refers to the whole ventral 
 surface of the body. 
 
 8. The Spiracles (Figs. 
 78 and 78, a) — also called 
 stigmata, stigmal plates, 
 and peritremes — are two 
 respiratory organs sit- 
 uated ventro-laterally. In 
 the Ixodidse they are sit- 
 uated posterior to the 
 attachment of the fourth 
 pair of legs; in the Arg- 
 asidae they are ))etween 
 the third and fourth pairs. 
 The entire structure may 
 be considered as the 
 stigmal plate or peritreme 
 with an opening known as 
 the spiracle or stigmal aperture. The stigmal plates vary in form and 
 
 Fii;. 77. — Capitulum (head), .•scutum (.shield), and 
 foreleg of Margaropus annulatu.s (from photomicro- 
 graph of mounted specimen, by Hoedt). 
 
138 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 structure in different species; they may be circular, oval, or comma- 
 shaped. 
 
 9. The Genital Pore is a transverse ventro-median slit, situated ante- 
 riorly between the at- 
 tachments of the first 
 three pairs of legs. 
 
 10. The Anus is in the 
 ventro-median line, pos- 
 terior to the attachment 
 of the last pair of legs. 
 
 11. The Anal Shields 
 are four elongate struc- 
 tures lateral to the anus. 
 
 They are present only in males of certain genera. 
 
 12. Legs. — There are four pairs of legs in the adult males and females 
 and in the nymphs (octopod). In the larvae there are three pairs (hex- 
 
 FiG. 78. — Stigmal plates of ticks: 1, Margaropus 
 Ixodes; 3. Dermacentor. 
 
 Fig. 78A. — Stigmal plate of Margaropus annulatus (photomicro- 
 graph of mounted specimen, by Hoedt). 
 
 apod). The pairs are numbered I to IV from before to behind. They 
 are composed of six articles or segments which are united by articul- 
 ations. 
 
 13. The Coxa or first article is an immovable portion which lies flat 
 upon the body and upon which the first movable article is articulated. 
 
THE TICKS 
 
 139 
 
 14. Bifid Coxce bear two spurs and are deeply incised. When tren- 
 chant they have a knife-hke margin. 
 
 Several stages are passed through in the development of the ticks. 
 From the eggs are hatched the six-legged (hexapod) larvce, often referred 
 to as the "seed ticks" (Plate II, Fig. 6). These are very small but 
 may be seen without the aid of magnification. The legs are relatively 
 much longer than in the adults. 
 
 The nymph stage is reached after molting, when a fourth pair of legs 
 appears posterior to the third pair (octopod). 
 
 The change from the nymphal to the adult stage is marked by another 
 molting, and sexual maturity is reached. 
 
 After fertilization b}^ the male, the female slowly enlarges and be- 
 comes the ovigerous or egg-containing female. Upon repletion she drops 
 to the ground and proceeds to deposit her eggs. 
 
 Superfamily Characteristics. Acarina (p. 94). — The Ixodoidea are 
 all blood-sucking parasites on animals. They have a movable capitulum 
 consisting of a basal portion (basis capituli), protrusi})le serrate chel- 
 icerse, a rigid serrate hypostome, and a pair of palps. The breathing 
 apertures are situated posteriorly. 
 
 The superfamily Ixodoidea is divided into two families, — Argasidae 
 and Ixodidse. 
 
 Family I. Argasid^ 
 
 Ixodoidea (p. 139). — The ticks belonging with this family have little 
 sexual dimorphism as compared with the Ixodid*. The capitulum, 
 instead of being terminal, occupies in adults the ventral face of the 
 
 ■^^^ 
 
 Fig. 79. — Argas miniatus: Fig. 3, dorsal view; 3a, ventral view; 3c, larva (after Os- 
 born, from Marx, Bui. No. 5, Bureau of Entomology, U. S. Dept. of Agr.). 
 
 cephalothorax. The palps are leg-like, the articles very movable on 
 each other. The scutum is absent. The coxa^ are unarmed; tarsi with- 
 out ventral spurs. 
 
 The family has two genera, — Argas and Otobius. 
 
 1. Argas miniatus (A. americanus) (Fig. 79). The Fowl Tick. Ar- 
 gasidae (p. 139). — The lK)dy is ovoid, flattened, with edges very thin. 
 
140 PARASITES OF THE DOMESTIC ANIMALS 
 
 Depending on the stage of engorgment, the color varies from Hght 
 reddish to dark brown. The capitulum has four long hairs, all directed 
 forward. The adult females are about 8.5 mm. (5/16 of an inch) in 
 length. The males are slightly smaller, but are not easily distinguish- 
 able. 
 
 Occurrence and Habits. — Commonly called the "fowl tick" or 
 " adobe tick," this species is widely distributed. It is a parasite of fowl in 
 Europe, Asia, Africa, and Australia, in Mexico and the Southern United 
 States. In its habits it is comparable to the bedbug, commg out to 
 feed upon its host at night and retreating after engorgment to cracks, 
 crevices, or other darkened hiding places to remain during the day. In 
 these retreats the females deposit large, reddish brown eggs, usually 
 several layings, in masses containing up to a hundred or more eggs in 
 each. Herms (1915) gives the further life history as follows: "Hatching 
 takes place in from three to four weeks. The larvee are six-legged and 
 very active, attacking a host apparently as readily by day as by night. 
 Once attached the larvae feed for about five days, occasionally longer, 
 remaining firmly attached during this time. At the end of this feeding 
 period the larvae detach themselves and then crawl away from their 
 host, hiding in some convenient crevice near by. The larvae molt in 
 about a week, when the fourth pair of legs appears and they are now in 
 the first nymphal stage, appearing like miniature adults. Nocturnal 
 feeding now takes place and in ten or twelve days another molt 
 occurs and the second nymphal stage is reached. Again the tick at- 
 taches itself, being now able to engorge itself in about an hour; again 
 after the expiration of something over a week a third molt takes place 
 and the adult stage is reached. The adults are able to engorge them- 
 selves in from twenty to forty-five minutes." 
 
 Effect. — When attacking in large numbers these parasites extract 
 large quantities of blood and, furthermore, cause much irritation and 
 unrest among the flock. As a result the animals become unthrifty, 
 weak, and nonproductive. 
 
 Argas miniatus has been proven to be the carrier of the spirochete 
 (Spirocheta gaUinarum) causing fowl spirochetosis or Brazilian sep- 
 ticemia of fowls (p. 327). 
 
 Control. — For the eradication of this pest the same general methods 
 may be taken as recommended for bedbugs of the hen house (p. 92). 
 The ends of roosts should be repeatedly covered with tar or wrapped in 
 waste soaked Avith crude oil. Nesting and trash should be burned and 
 the interior sprayed with kerosene. All woodwork about the buildings 
 should be free from bark, as this affords a favorable hiding place for the 
 ticks. It is well to repeat the treatment with kerosene at least once a 
 month during the season that the ticks are active, 
 
 2. Otobius megnini (Ornithodorus megnini, Fig. 80). The Spinose 
 
THE TICKS 
 
 141 
 
 Ear Tick, Argasidse (p. 139). — The boch' is oval, broader anteriorly than 
 posteriorly. The female is 5-6 mm. (V4 of an inch) in length and about 
 3 nmi. (Vs of an inch) in breadth. The nymphs are covered with nu- 
 merous spines, a fact which has given to this species the common name 
 ''spinose ear tick." 
 
 Occurrence and Habits. — This tick occurs in the ears of horses of 
 ]\Iexico and the Southwestern States. Its attack is not confined to 
 horses and mules; it also attacks the ears of cattle and occasionally other 
 domestic animals and man. The larval ticks reach the head of the graz- 
 ing host animal from weeds or other vegetation upon which they have 
 crawled immediately after 
 hatching. Having gained en- 
 trance to the ear, they attach 
 deeph' in the folds where the}- 
 feed for about five days. 
 They then molt and, as 
 n\Tnphs with spinose bodies, 
 contmue to infest the ear and 
 feed for several weeks. The 
 minphs then leave the host, 
 again molt, and becoming 
 unspmed adults, the females 
 are fertilized and soon begin 
 depositing their eggs. 
 
 Effect. — In their attach- 
 ment to the lining of the 
 conchse the spinose ticks 
 cause much irritation which 
 the animal indicates by shak- 
 ing its head, or it may be 
 wrought up to a high degree of nervous excitement. The ticks are said 
 to be responsible for much deafness among domestic annuals, and, 
 especially among young animals, they are considered as a cause of se- 
 rious illness and even death. 
 
 Treatment. — Good results have been obtained by flooding the ear 
 with carbolized oil. This closes the breathing apertures of the ticks and 
 causes them to release their attachment, after which they may be re- 
 moved with a cotton swab or forceps and destroyed. 
 
 Fig. 80. — Otobius megnini: dorsal and ventral 
 view of nymphal form, with details (after Osborn, 
 from IVIarx, Bull. Xo. 5, Bureau of Entomology, 
 U. S. Dept. of Agr.). 
 
 Family II. Ixodid.e 
 
 Ixodoidea (p. 139). — The most prominent differential character by 
 which these ticks may be distinguished from those of the family Ar- 
 gasidse is the presence of a scutum, located inunediately posterior to 
 
14-2 PARASITES OF THE DOMESTIC ANIMALS 
 
 the capitiiluin, which is terminal and not upon the ventral face of the 
 cephalothorax as in the Argasidse. Sexual dimorphism is marked, the 
 dorsal surface of the males being almost covered by the scutum. In 
 the distended female the scutum appears as a small shield directly be- 
 hind the capitulum. Only the females are capable of great distension. 
 The spiracles are posterior to the fourth coxae. The eyes, if present, are 
 situated laterally upon the scutum. 
 
 Nine genera have been described under the famity Ixodidae, as fol- 
 lows: Ixodes, Hsemaphysalis, Dermacentor, Rhipicentor, Rhipicephalus-, 
 Margaropus, Boophilus, Hyalomma, and Amblyomma. 
 
 Four of the above, — Ixodes, Dermacentor, Margaropus, and Am- 
 blyomma, — -contain species occurring upon cattle and other animals in 
 the United States. The generic characteristics of these are given by 
 Nuttall and Warburton (A Monograph of the Ixodoidea, 1911) as 
 follows: 
 
 1. Ixodes. — Inornate, without eyes and without festoons; spiracles 
 round or oval; palps and basis capituli of variable form; coxae either un- 
 armed, trenchant, spurred, or bifid; tarsi without spurs. Sexual di- 
 morphism pronounced, especially with regard to the capitulum. In 
 the male the venter is covered by non-salient plates: one pregential, 
 one median, one anal, two adanal and two epimeral plates. Anal groove 
 surrounding anus in front. 
 
 2. Dermacentor. — Usually ornate, with eyes and festoons; with 
 short, broad or moderate palps and basis capituli rectangular dorsally. 
 In some species coxae I to IV of the male increase progressively in size; 
 in all species coxa IV is much the largest ; the male, moreover, shows no 
 ventral plates or shields. Coxa I bifid in both sexes. Anal groove con- 
 touring anus behind. Spiracles suboval or comma-shaped. 
 
 3. Margaropus. — Inornate, with eyes, but without festoons, with 
 short palps and capitulum intermediate between that of Rhipicephalus 
 and Boophilus; highly chitmized; the unfed adults of large size. The 
 female with very small scutum. Coxae conical, unarmed but for a small 
 spine posteriorly on coxa I. The male with a median plate prolonged 
 in two long spines projecting beyond and to either side of the anus; 
 with coxae similar to those of the female; legs increasing progressively 
 in size from pair I to IV, the articles, especially of leg-pair IV, greatly 
 swollen. When replete, the male shows a caudal protrusion. Anal 
 groove obsolete. Spiracles rounded or short oval in both sexes. 
 
 4. Amblyomma. — Generally ornate, with eyes and with festoons. 
 With long palps; of which article II is especially long, basis capituli of 
 variable form. The male without adanal shields, but small ventral 
 plaques are occasionally present close to the festoons. Anal groove 
 contouring anus behmd. Spiracles subtriangular or comma-shaped. 
 
 Six species are found upon cattle and other domestic animals in this 
 
THE TICKS 
 
 143 
 
 countiy, the following brief descriptions of which are taken principally 
 from those given by ^lohler (Bull. No. 78, Bureau of Animal Industr}-, 
 1905; Farmers' Bull. No. 569, 1914). The parts described are those of 
 the adult female. 
 
 1. Ixodes ricinus (Fig. 81). The Castor-bean Tick. Ixodes (p. 
 142). — The body is ovoid in shape, narrower anteriorly than posteriorly; 
 lead colored, with a diversity of 3'ellowish red, brown, or gray. Festoons 
 are absent. The mature female is three-eighths to seven-sixteenths of 
 an inch m length. The legs are thin and dark brown in color. The 
 capitulum and scutum are a shiny dark brown or' chestnut brown; 
 scutum pentagonal with prominent lat- 
 eral borders. The palpi are well de- 
 veloped and extend outward upon each 
 side. 
 
 This tick has been collected from sheei\ 
 goats, cattle, horses, deer, dogs, foxes, 
 cats, rabbits, birds, and man. It i- 
 widely distributed in the United States. 
 
 2. Ixodes hexagonus. The European 
 Dog Tick. Ixodes (p. 142).— The body 
 is oval in shape and of an ashy color; 
 festoons absent. The legs are longer and 
 more robust than those of the cattle tick. 
 The capitulum and scutum are brownish 
 red in color and similar to those of 
 Ixodes ricinus in shape. The palpi are 
 longer and more prominent than in the 
 cattle tick and, like those of Ixodes ridniis, extend outward. 
 
 This species has been collected from dogs, cattle, sheep, foxes, rabbits, 
 squirrels, gophers, cats, birds, man, and other hosts in the Eastern 
 United States, but is less common in this country than the other species 
 here described. 
 
 3. Dermacentor reticulatus (D. occidentalis). The Net Tick. 
 Dermacentor (p. 142). — The body is oblong oval, five-eighths of an inch 
 long, and of a deep brown or slate color. The legs are brown and of 
 moderate length. There are eleven festoons about the posterior margin 
 of the ])ody which in the adult become shallow or effaced. The scutum 
 has a silveiy-white metallic rust extending along the two sides and 
 posterior portion. 
 
 Found on man, cattle, horses, sheep, and deer. In this country it 
 seems to be most common in the West, especially in California, Texas 
 and New^ Mexico. 
 
 4. Dermacentor variabilis (D. electus, Fig. 82). The American 
 Dog Tick or Wood Tick. Dermacentor (p. 142). — This tick resembles 
 
 Fig. cSl. — Ixodes ricinus — enlarged 
 (after Osborn, Bull. No. 5, Bureau 
 of Entomology, U. S. Dept. of Agr.). 
 
144 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 D. reticulatus so closeh^ that a hand lens is necessary to distinguish be- 
 tween them. The body is oblong oval in shape and may measure as 
 much as three-fifths of an inch in length. It can be distinguished from 
 the Texas-fever tick by the capitulum and scutum which are longer and 
 broader. Extendmg anteriorly along each side of the scutum there are 
 lines of yellowish white rust, separated by a central brownish area. 
 There are eleven festoons on the posterior margin of the body, most 
 distmct in the 3'oung female. 
 
 This tick has been found on man, cattle, dogs, horses, and other an- 
 imals, especially in the Eastern United States. 
 
 Fig. 82. — Dermacentor variabilis: male — enlarged (after Os- 
 born, Bull. No. 5, Bureau of Entomology, U. S. Dept. of Agr.). 
 
 5. Margaropus annulatus (Boophilus annulatus, B, bovis). The 
 
 Texas-fever or Cattle Tick. Margaropus (p. 142). — This tick may be 
 distinguished from the other five by the small size and the color of the 
 capitulum and scutum, the lateral borders of which are straighter and 
 more parallel. These parts are short and relatively broad and in color 
 reddish brown or chestnut brown. The body is oblong oval in shape 
 and may reach a length of one-half an inch. The color may be dull 
 yellow or olive brown. Often it is mottled with irregular areas of 
 yellow and brown or streaked with wavy lines of these colors. Festoons 
 are absent. The legs are brown, moderately long, and very slender. 
 
 This tick is found principally on cattle, less frequently on horses, 
 mules, and asses. 
 
THE TICKS 145 
 
 6. Amblyomma atnericanum. The Lone Star Tick. — Amblyomma 
 (p. 142). — The body is oval and in color yellowish gray or brown. 
 When not distended, the body-surface is rough and puckered. Festoons 
 are present. The scutum extends backward a short distance to form a 
 triangle, at the apex of which is a white or yellowish spot, from which 
 the tick derives its name "Lone Star." The mature female may reach 
 a length of one-half an inch. The legs are long and thin. 
 
 This species has been found on cattle, dogs, horses, sheep, goats, hogs, 
 and man. It is very widely distril)uted in the United States. 
 
 All of these ticks show longitudinal grooves ujion the dorsal surface 
 of the body which are most distinct a few days after the tick's repletion 
 and removal from the host. These furrows vary considerably in different 
 members of the same species and, though some authors appear to attach 
 importance to them, they can hardly be considered of much value as an 
 aid in recognition. Color is also unreliable in the identification of 
 genera and species, as this varies with the stages in the tick's develop- 
 ment and may change variously in adult ticks of the same species. 
 
 The Texas-fever Tick. — Kilborne, of the Bureau of Animal Industry, 
 proved conclusively by field experiments conducted in 1889 and 1890 
 that it is only through the bite of this tick that Texas-fever can be 
 naturally transmitted. Economically, therefore, Margaropus annulatus 
 (Plates I and II), the Texas-fever tick, is the most important for con- 
 sideration. Other ticks not concerned in the transmission of Texas- 
 fever have been mentioned here as occiu'ring upon cattle, all having 
 the same successive stages in their development, namely, oval, larval, 
 nymphal, and adult male and female. Before molting and transforming 
 from one stage to the other these ticks fall from their host, after the 
 transformation seeking a new host. That this is not true in the case 
 of the Texas-fever tick was shown by Dr. Cooper Curtice, of the Bureau 
 of Animal Industry, in 1891. He established the fundamental facts 
 in the life history of this tick and showed that it remains upon its host 
 from the time that it attaches as a larva until it drops to the ground 
 replete and ready to deposit its eggs (Tables, p. 151). Careful observa- 
 tions by the Zoological Division of the Bureau have supplied valuable 
 data relative to the biology of this tick, and much detailed information 
 has been published by the Bureau pertaining to this and to tick control 
 and eradication. In this connection, it may be of service to mention 
 here the following titles, any of which can be obtained upon application 
 to the Superintendent of Documents, Government Printing Office, 
 Washington, D. C. 
 
 Texas Fever, Methods for its Prevention, by John R. Mohler. Bull. 
 No. 78 (1905). 
 
 Texas or Tick Fever and its Prevention, l)y John R. Mohler. Farmers' 
 Bull. No. 258 (1906). 
 
Plate I. — Margaropus annulatus: 1, Male, dorsal view; 2, Female, dorsal view; 3, 
 Male, ventral view; 4, Female, ventral view; 5, Claw and pulvillus; 6, Lower surface of 
 first, second, and third segment of leg; 7, Stigmal plate. (After Osborn, from Curtice, 
 Bull. No. 5, Bureau of Entomology, U. S. Dept. of Agr.). 
 
4 4a 
 
 Plate II.— MarRaropus anruilatus: 1, Front foot, showing single spur; la, Supposed 
 sense organs; 2, Hind foot, showing double spur; 3, Head of female; 4, 4a, 4b, 4e, Fcrnale 
 ticks, natural size, shown at different stages of feeding; 5, Egg; G, Larval or "seed" tick; 
 7, Dorsal surface of the mouth parts of female — a, mandible; b, labrum; c, palpus; d, 
 mouth ring; e, spots covered with papilla; S, Labium and mandibles; 8a, Papilla; enlarged; 
 9, Mandible-X-Busk's organ, use unknown; 10, Mouth parts of young tick. (After Osborn, 
 from Curtice; Bull. No. 5, Bureau of Entomology, U. S. Dept. of Agr.). 
 
148 PARASITES OF THE DOMESTIC ANIMALS 
 
 The Cattle Tick in its Relation to Southern Agriculture, b}^ August 
 Mayer. Farmers' Bull. No. 261 (1906). 
 
 Proceedings of a Conference of Federal and State Representatives 
 to Consider Plans for the Eradication of the Cattle Tick. Bull. No. 97 
 (1907). 
 
 Methods of Eradicating Cattle Ticks, by Louis A. Klein. Cir. No. 
 110 (1907). 
 
 Studies on the Biologv of the Texas-fever Tick, bv H. W. Gravbill. 
 Bull. No. 130 (1911). 
 
 Methods of Exterminating the Texas-fever Tick, by H. W. Graybill. 
 Farmers' Bull. No. 498 (1912). 
 
 Progress and Prospects of Tick Eradication, by Cooper Curtice. 
 Cir. No. 187 (1912). 
 
 Texas or Tick Fever, by John R. Mohler. Farmers' Bull. No. 569 
 (1914). 
 
 Life History; the Nonparasitic Development. — The following data 
 as to the life histor}^ of the Texas-fever tick is taken from Graybill 
 (Studies on the Biology of the Texas-fever Tick, 1911). The non- 
 parasitic development is considered bj^ this author under five periods, 
 namely, the preoviposition period, the oviposition period, the incu- 
 bation period, the hatching period, and the longevity period of the 
 larva? . 
 
 The period of preoviposition extends from the time the female tick 
 drops until she begins to deposit her eggs. In a series of investigations 
 carried out at Auburn, Ala., m 1907-8 it was observed that the average 
 duration of this period ranged from three to forty-nine and three-tenths 
 daj^s, depending largely upon temperature, the shorter average period 
 occurring in August, the longer in December. 
 
 The average oviposition or egg-Iaymg period for different months of 
 the year ranged from eight and three-tenths daj^s for June to one hun- 
 dred and twenty-seven and five-tenths daj^s for November. The 
 maximum period noted was one hundred and fift^^-two days, observed 
 in November, and the mmimum three days, observed in June. The 
 maximum number of eggs deposited by a female tick was 5105, minimum 
 357, with an average ranging from 1811 to 4089. 
 
 The incubation period was found to range from nineteen days in the 
 summer to one hundred and eighty days beginning in the fall. The 
 conditions essential to development and hatching are moisture, such as 
 supplied bj^ sufficient atmospheric humidity to prevent eggs losmg 
 moisture by evaporation, and a favorable temperature. 
 
 The hatching period is taken as the time required for all of the eggs to 
 hatch after hatching begins, the eggs deposited by a female hatching 
 approximately in the sequence in which the,y are laid. The average 
 period was found to range from ten and six-tenths days for Jul.v to 
 
THE TICKS 
 
 149 
 
 thirty-six days for Octoljer. The maximum period observed was forty- 
 nine da^'s for October, the minimum four days for July. 
 
 The longevity period is stated to depend on individual vitahty, 
 humidity, and temperature. It was noted, especially in eggs laid during 
 the winter, that some larvse do not have sufficient vitality to disengage 
 themselves from the eggshell and die partly inclosed within it ; also that 
 others die veiy soon after emerging. Cold, it is stated, prolongs longev- 
 ity because of the fact that the tick remains quiescent with resulting 
 conservation of bod.y fluids and nourishment. The fact that the larvae 
 respond negatively to light is an additional factor promoting longevity. 
 In places exposed to the sun they collect on the under side of leaves and 
 other vegetation, thus protecting themselves from loss of bodj^ moisture 
 through the direct heat of the sun. In observations made it was deter- 
 mined that the average maximum longevity for larvae hatched from a 
 number of lots of eggs in July was thirtj'-eight and six-tenths days. 
 From eggs hatched in October the average maximum period was one 
 hundred and sixty-seven and four-tenths days. The shortest period 
 was four days for larvae hatched in July, the longest two hundred and 
 thirty-four daA'S for larvae hatched in October. 
 
 The following summary' is given of the data on the nonparasitic 
 period : 
 
 Total Time from Dropping of Female until all Resulting Larvce are Dead 
 
 Date engorged 
 
 females were 
 
 collected 
 
 Number 
 
 of engorged 
 
 females 
 
 Range of 
 entire- 
 time 
 periods 
 
 Average 
 
 of 
 periods 
 
 Date engorged 
 
 females u-ere 
 
 collected 
 
 Number 
 
 of engorged 
 
 females 
 
 Range of 
 entire- 
 time 
 periods 
 
 Average 
 periods 
 
 June 1, 1907 
 
 7 
 
 Days 
 79-100 
 
 Days 
 
 86.9 
 
 101 
 199.6 
 250.7 
 279.6 
 
 Dec. 29, 1907, 
 
 to 
 Jan. 1, 1908 
 
 3 
 
 Days 
 181-207 
 
 Days 
 196.3 
 
 July 1, 1907 
 
 7 
 
 82-112 
 
 Jan. 29 to 
 Feb. 4, 1908 
 
 7 
 
 156^189 
 
 173.1 
 
 Aug. 1, 1907 
 
 7 
 
 172-221 
 
 Feb. 27 to 28, 
 1908 
 
 2 
 
 143-162 
 
 152.1 
 
 Aug. 31, 1907 
 
 6 
 
 230-272 
 
 Mar. 26 to 
 29, 1908 
 
 9 
 
 144-161 
 
 152.1 
 
 Oct. 1, 1907 
 
 7 
 
 276-288 
 
 April 29, 
 1908 
 
 14 
 
 122-173 
 
 142.8 
 
 Nov. 1, 1907 
 
 7 
 
 200-253 
 
 232.7 
 
 
 
 
 
 Nov. 30, 1907 
 
 3 
 
 187-249 
 
 217 
 
 
 
 
 
 The Parasitic Development. — The parasitic development has three 
 stages, the larval, the nyniphal, and the adult. In the experiments car- 
 
150 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 ried on upon this portion of the tick's life history tick-free animals were 
 infested at nine different times from July, 1907, to May, 1908. It was 
 found that the minimum larval period ranged from five to seven days; 
 the minimum nymphal period of females, nine to eleven days; the adult 
 period, from a minimum of five to a maximum of thirty-three days. 
 The table which follows is given to show the range of the periods ob- 
 served upon larvae which were marked after they had become attached 
 and then kept under observation from day to day. 
 
 Le7igth of Period and Total Duration 
 
 of Parasitic Development 
 
 Date larvce applied 
 
 Sex 
 
 Length 
 
 of larval 
 
 period 
 
 Length 
 
 of nymphal 
 
 period 
 
 Length 
 
 of adult 
 
 period 
 
 Duration 
 
 of parasitic 
 
 period 
 
 1908 
 Feb 29 
 
 Females 
 
 iT 
 
 Days 
 10-15 
 
 Days 
 5-13 
 
 Days 
 25-34 
 
 
 
 Do 
 
 Males 
 
 7-9 
 
 8-10 
 
 - 
 
 
 
 
 Do 
 
 (?) 
 
 7-14 
 
 - 
 
 - 
 
 _ 
 
 
 
 April 4 
 
 Females 
 
 7 
 
 9-14 
 
 4-9 
 
 25-26 
 
 
 
 Do 
 
 Males 
 
 7 
 
 8-12 
 
 - 
 
 — 
 
 May 23 
 
 Females 
 
 6-7 
 
 9-12 
 
 6-9 
 
 22-25 
 
 
 
 Do 
 
 Males 
 
 5-8 
 
 8-13 
 
 — 
 
 _ 
 
 
 
 As to the importance of the foregoing data, Graybill says: ''The dura- 
 tion of each of these stages and the duration of a single infestation upon 
 cattle during different portions of the year are of great practical im- 
 portance. Upon the duration of an infestation depends the time anmials 
 must be kept on tick-free fields in order to become free from the ticks." 
 
THE TICKS 151 
 
 Life Histories of the Dog Tick and Texas-Fever Tick Compared 
 IN Tabular Review (note italics) 
 
 dermacentor variabilis 
 Ovigerous Female. — Engorges upon host, drops to ground, 
 I and deposits eggs. 
 
 Eggs. — Deposited upon ground in mass. 
 
 I 
 Larvae. — Bunched upon grass from which the}^ reach 
 
 I first host. 
 
 First Molt, Larvae to Nymphs. — ?7joon ground, after drop- 
 
 I ping from first host. 
 
 Nymphs. — Crawl from grass upon second host. 
 
 Second Molt, Nymphs to Adults.— ?7?j0/i ground, after 
 I dropping from sec- 
 
 I ond host. 
 
 Males and Females.— C rawl from grass upon third host; 
 I mate. 
 
 Ovigerous Females. — Engorge upon host. 
 
 Ovigerous Females. — Drop to ground and deposit 
 eggs. 
 
 MARGAROPUS ANNULATUS 
 
 Ovigerous Female.— Engorges upon host, drops to ground. 
 I and deposits eggs. 
 
 Eggs. — Deposited upon ground in mass. 
 
 Larvae. — Bunched upon grass from which they reach 
 I host. 
 
 First Molt, Larvae to Nymphs. — Upon host. 
 
 Second Molt, Nymphs to Adults. 
 Males and Females. — Upon host; mate. 
 
 Ovigerous Females. — Engorge upon host, 
 
 Ovigerous Females. — Drop to ground and deposit 
 eggs. 
 
 Loss Occasioned by Cattle Ticks.— According to estimates published 
 in 1914, the main sources of loss occasioned by the cattle tick may be 
 summarized as follows: 
 
1.52 PARASITES OF THE DOMESTIC ANIMALS 
 
 The parasitic life of the ticks, together with the blood-destroying 
 properties of the protozoan parasites with which they inoculate their 
 hosts, causes a loss of flesh and lack of development in southern cattle 
 conservatively estimated at $23,250,000. 
 
 The lower price which southern cattle from infested districts bring 
 in northern stockyards averages at least $1.50 per head. It is estimated 
 that the loss upon animals marketed under these conditions, including 
 stock, beef, and dairy cattle, will sum up to $1,057,500 annually. 
 
 The shrinkage in milk production of cattle infested with many ticks 
 will average about one quart per day. Upon an estimate of 875,000 
 ticky dairy cattle out of more than 4,000,000 dairy cattle below the 
 quarantine line, the loss thus occasioned, reckoned at three cents per 
 quart, would amount to $26,250 per day, or, counting three hundred 
 milking days for each cow to the year, $7,875,000 annually. 
 
 The loss among nonimmune southern cattle in tick-free pastures- 
 through contracting Texas-fever when exposed to the tick has been 
 estimated at $5,812,500 per annum. 
 
 The deaths from Texas-fever of pure-bred or high-grade cattle im- 
 ported from the North for breeding purposes amount to about sixty 
 per cent, among such cattle which have not been immunized by blood 
 inoculations, and to about ten per cent, among those which have had 
 such immunization. Since these are usually expensive animals, the 
 loss in such cases is often excessive. 
 
 Considering additional losses, direct or indirect, as published by the 
 United States Department of Agriculture in 1914, it will be found that 
 the Texas-fever tick is responsible for a loss of about $40,000,000 an- 
 nually, in addition to which it is responsible for lowering the assets of 
 the infested country to the extent of $23,250,000. 
 
 Progress in Eradication. — Methods of dipping and pasture rotation 
 for the control of the cattle tick have been fully set forth in bulletins 
 and circulars published by the United States Department of Agriculture 
 (Farmers' Bull. No. 498). These are freely available to all interested in 
 details of the subject which need not be repeated upon these pages. 
 
 Eradicative measures carried on by the Federal Government in 
 cooperation with the states affected by the cattle tick have seen in 
 progress since 1906. Up to 1911 twenty per cent, of the infested area, 
 mostly along the northern boundary, had been cleaned through this- 
 systematic cooperative work. At the. present time (1918), through the 
 continuation of this work, fifty-two per cent, of the tick-infested area 
 has been released from quarantine, and it is authoritatively predicted 
 that five years hence the cattle tick will be entirely eradicated from the 
 South. 
 
THE TICKS d 
 
 Order II. Lixguatulida 
 
 15S 
 
 Arachnida (p. 94). — The iiiombers of this group are arachnids which 
 have become extremely altered in consequence of their parasitic mode 
 of life. Due to their worm-like body and endoparasitic habits, they were 
 formerly placed with the helminths. 
 
 The body is elongated, annulated, and somewhat flattened. The 
 bodj' regions are not defined from each other. With the exception of 
 two pairs of articulated hooks 
 surromiding the mouth, re- 
 garded by some as vestigial 
 legs, the adult body is entirely 
 without appendages (Fig. 83). 
 
 The mouth is anterior, and 
 the intestine passes directly 
 through the body, opening by 
 the posterior anus. 
 
 There are no circulatory or respiratory organs 
 general surface of the bod.y. 
 
 The nervous system is reduced, consisting of the esophageal ring, 
 which gives off filaments to the cephalothorax region. Eyes are absent. 
 
 The sexes are separate; the male much smaller than the female. From 
 the eggs there hatches an ovoid embr^'o, constricted at its posterior 
 extremity, and provided with two pairs of jointed legs. Anteriorly it 
 has a perforating apparatus by means of which it bores through the 
 intestinal wall of its host and reaches the liver, or other organ, in which 
 it becomes encysted. 
 
 The adult Linguatula (L. rhinaria) infests the nasal cavities of mam- 
 mals, usually the dog. The larvae infest the visceral organs of herbivor- 
 ous animals. 
 
 Fig 83. — Linguatula rhinaria, adult (after 
 Osborn, from Packard; Bull. No. 5, Bureau of 
 Entoniologj-, U. S. Dept. of Agr.). 
 
 Respiration is by the 
 
PART II 
 THE INTERNAL PARASITES 
 
 CHAPTER XIV 
 
 PHYLUM 11. PLATYHELMINTHES. THE FLUKES AND 
 TAPEWORMS 
 
 With but few exceptions all of the metazoan internal parasites come 
 into the old division \>rmes, which brings together animals generally 
 worm-like, though widely differing in many respects. Compared thus 
 as a whole with animals usually rated below them in the zoological 
 scale, .worms are readih' distinguished in possessing differentiated 
 anterior and posterior extremities, the anterior directed toward their 
 forward movement and involving a head which contains a ganglionic 
 mass of nerve cells or, as it ma}' be called, a rudimentary brain. Fur- 
 thermore, the body is bilaterally similar, and there is a dorsal and 
 ventral surface. The annulated worms, which include the higher 
 representatives, differ from the Arthropoda mainly in the absence of 
 articulated appendages to their body-segments, while the lack of a 
 notochord and gill-slits distinguishes them from certain lowly members 
 of the Chordata. Beyond these few points there is little to be said as 
 to the characteristics of the worms considered as a whole. 
 
 The including in a single phylum of all invertebrates generally elongate 
 and without articulated appendages is systematically faulty in that it 
 brings together animals with structural differences of grand division 
 importance, though agreeing in an external form generally worm-like. 
 In most of the present-day systems of classification the worms are dis- 
 tributed into three, or at least two, phyla, the older class division 
 Platyhelminthes, or flat worms, being given grand division distinction. 
 Many authors also place the smooth-bodied Nemathelminthes and the 
 annulated worms in separate phyla, while another division, — the 
 Molluscoidea, has been created to dispose of the more or less related 
 moss-like Pol^'zoa (Bryozoa) and the mollusc-like Brachiopoda. An 
 objection to such arrangement is that groups poor in species, some of 
 them mainh' of parasitic interest, are placed on the same basis as such 
 large and very important divisions as the chordates and arthropods, 
 thus giving them an undue prominence in a general consideration of the 
 animal kingdom. 
 
156 PARASITES OF THE DOMESTIC ANIMALS 
 
 The classification adopted here places the smooth roundworms and 
 the annulated worms together in the phylum Ccelhelminthes, an ar- 
 rangement based upon the presence of a coelom or bod}^ cavity, which 
 is a structural feature clearly defuiing these worms from the Platyhel- 
 minthes and establishing a relationship between the smooth round and 
 annulated forms of primary importance. 
 
 The Platyhelminthes includes worms which are flattened dorsoven- 
 trally, the two surfaces uniting in more or less sharp margins. There is 
 no body cavity, the various organs being embedded in a mass of con- 
 nective tissue and muscle fibers. The aHmentary tract is a simple or 
 bifurcated, sometimes branching, pouch having no anal opening (Fig. 85), 
 the inouth serving as both inlet and vent. In some parasitic 
 forms (t|ipeworms) alimentary organs are entirely wanting. 
 A true circulatory system is absent. There is a series of ex- 
 cretory tubes which ramify throughout the body, usually 
 opening to the outside near the posterior extremity. The 
 nervous system consists of ganglia located above the esoph- 
 agus, where this is present, and the lateral nerves which these 
 give off. Most all are hermaphroditic, the sexual organs 
 being distributed over a large portion of the body. 
 
 As is true of the worms in general, free living forms are 
 found in fresh and salt water. They may often be revealed 
 clinging to the under side of rocks (planaria. Fig. 84) and 
 upon the moist soil, some of these specimens being nearly 
 transparent. The largest members of the division are the tapeworms. 
 ^^'hich may reach a length of thirty feet or more. 
 
 The phylum contains two parasitic classes, as follows: 
 Class I. Trematoda. — The flukes. 
 Class II. Cestoda. — The tapeworms. 
 
 Class I. Trematoda 
 
 Platyhelminthes (p. 156). — All of the members of this group are 
 parasitic, living either as ecto- or entoparasites. The body is usually 
 leaf-like, often much like a pumpkin seed in form (Fig. 87), and is pro- 
 vided anteriorly with suckers by which attachment is made to the host. 
 In most of those entoparasitic (Distomese) two suckers are present, one 
 anterior and surrounding the mouth, and a second larger one just 
 posterior to the mouth on the mid-ventral line. In the ectoparasitic 
 species (Polystomese), which are usually parasitic upon the gills and 
 skin of aquatic animals, the suckers are more numerous. 
 
 The alimentary tract leads by a short gullet to a bifurcation, forming 
 two elongated blind sacs which may or may not give rise to lateral 
 secondary pouches (Fig. 85). Eye spots occur in some of the ectopara- 
 sitic species and in the larvae of the entoparasitic. 
 
PLATYHELMINTHES 
 
 157 
 
 Most of the Trematoda are hermaphroditic. At maturity the sexual 
 organs reach a high degree of development adaptive to the mode of 
 parasitism (Introduction, p. 5). The male sexual organs consist of 
 tube-like testes, from which spermatic ducts take origin. These unite 
 in a large seminal vesicle, the terminal portion of 
 which is usually inclosed in a pouch. The ovary 
 is also branching and tube-like. With the oviduct 
 there unite ducts from the vitellaria or yolk-glands, 
 this union being followed bj' the much convoluted 
 uterus which receives the eggs and terminates by 
 the side of the male sexual opening (Fig. 86). 
 
 The entoparasitic trematodes undergo a compli- 
 cated life histor}', invohang alternation of hosts 
 and, within the intermediate host, multiplicative 
 generations. A typical example of this cycle is 
 given further on in reference to the species Fasciola 
 hepatica. 
 
 Most of the trematode parasites of mammals 
 live in the liver, producing the affection known as 
 hepatic fascioliasis (distomiasis), or commonly as 
 liver rot. Others invade the blood, lungs, and 
 stomach, causing, accordingly, vascular, pulmonary, 
 and gastric fascioliasis. The latter forms are rarely 
 met with in the United States. 
 
 The species to be considered come imder three 
 families, as follows: 
 
 Famih' I. Fasciolidae. — The common liver flukes. 
 
 Family II. Amphistomidse. — Of the rumen. 
 
 Familv III. Schistosomidae. — The blood fluke. 
 
 Fig. So.— Sketch of 
 Fasciola hepatica, 
 showing bifurcated and 
 branching alimentary 
 tract: si, mouth and 
 anterior sucker; s2, 
 posterior sucker; t. a., 
 alimentary tract, — en- 
 larged (after Boas, by 
 Kirkaldy and Pollard, 
 from Thomas). 
 
 Classification of Parasites of the Phylum Pl.\tyhelmixthes 
 
 Phylum II. Platyhelminthes. P. 155. 
 Class A. Trematoda. Flukes. P. 156. 
 Order 1. Distomese. P. 156. 
 Family (a) Fasciolidae. P. 160. 
 Genus and Species: 
 
 Fasciola hepatica. Hosts, sheep, cattle, etc. P. 160. 
 Dicroca^lium lanceatum. Hosts, same. P. 160. 
 Fasciola americanus. Hosts, same. P. 160. 
 Family (b) Schistosomidae. P. 168. 
 Genus and Species: 
 
 Schistosoma bovis. Ho.sts, cattle, sheep. P. 168. 
 Family (c) Amphistomidse. P. 167. 
 
1.58 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. 83. — Reproductive organs of liver fluke: f, female aperature; s. v., seminal \'esicle 
 y. g. 1., diffuse yolk glands; sh. g., shell gland; v. d., vas deferens; T., testes; ov, ovary 
 (dark); ut, uterus; c. s., cirrus sac; p, penis; m, mouth; g, anterior lobes of gut (after 
 Thomson, from Sommer). 
 
PLATYHELMINTHES • 159 
 
 Genus an(J Species: 
 
 Ainphistomiim cervi. Hosts, niniinants. P. 167. 
 Class B. Cestoda. Tapeworms. P. 169. 
 Order 1. Polyzoa. 
 
 Family (a) Taeniidae. P. 170. 
 Genus and Species: 
 
 Anoplocephala perfoliata. Host, equines. P. 174. 
 
 A. mamillana. Host, equines. P. 175. 
 
 A. plicata. Host, equines. P. 175. 
 
 Moniezia expansa. Hosts, cattle, sheep, goats. P. 176. 
 
 M. alba. Hosts, same. P. 176. 
 
 M. planissima. Hosts, same. P. 176. 
 
 Thysanosoma actinioides. Host, sheep. P. 176. 
 
 Dipyhdium caninum. Hosts, dog, cat, man. P. 178. 
 
 Larva, Cryptocystis trichodectes. Hosts, flea, louse. 
 P. 178. 
 Taenia hj-datigena. Host, dog. P. 178. 
 
 Larva, Cysticercus tenuicollis. Hosts, ruminants and 
 hogs. P. 179. 
 T. pisiformis. Host, dog. P. 179. 
 
 Larva, Cysticercus pisiformis. Host, ral)])it. P. 179. 
 T. ovis. Host, dog. P. 204. 
 
 Larva, Cysticercus ovis. Host, sheep. P. 203. 
 Multiceps multiceps. Host, dog. P. 179. 
 
 Larva, Multiceps nuilticeps. Host, Herbivora. P. 179. 
 M. serialis. Host, dog. P. 179. 
 
 Larva, Multiceps serialis. Hosts, rabbit and other 
 rodents. P. 180. 
 M. gaigeri. Host, dog. P. 181. 
 
 Larva, Multiceps gaigeri. Host, ruminants. P. 181. 
 Echinococcus granulosus. Hosts, dog, cat. P. 181. 
 
 Larva, Echinococcus granulosus. Hosts, riuninants, hog, 
 etc. P. 181. 
 Taenia taeniaeformis. Host, cat. P. 184. 
 
 Larva, Cysticercus fasciolaris. Hosts, rat, mouse. P. 184. 
 Cittotaenia denticulata. Host, chicken. P. 185. 
 Choanota^nia infundibuliformis. Host, chicken. P. 189. 
 
 Larva, a cysticercoid. Host, house fly. P. 189. 
 HjTiienolepis carioca. Host, chicken. P. 190. 
 Davainea tetragona. Host, chicken. P. 190. 
 D. cesticillus. Host, chicken. P. 190. 
 D. echinobothrida. Host, chicken. P. 191. 
 D. proglottina. Host, chick(>n. P. 191. 
 Larva, a cvsticercoid. Host, snail. P. 191. 
 
160 PARASITES OF THE DOMESTIC ANIMALS 
 
 Taenia saginata. Host, man. P. 195. 
 
 Larva, Cysticercus bovis. Host, ox. P. 195. 
 T. solium. Host, man. P. 199. 
 
 Larva, Cysticercus cellulosse. Host, hog, etc. P. 199. 
 Family (b) Diphyllobothriidse. P. 185. 
 Genus and Species: 
 
 Diphyllobothrium latum. Hosts, man, dog, cat. P. 185. 
 Larva, a plerocercoid. Host, fish. P. 185. 
 
 Family I. Fasciolid^ 
 
 1. Fasciola hepatica (Distomum hepaticum). The Liver Fluke 
 
 (Fig. 87). Trematoda (p. 156). — ^The body is flattened, pale brown in 
 color, oval in shape, and broadest in front, where it is terminated by 
 a conical process bearing at its apex the oral sucker which surrounds 
 the mouth. A larger ventral sucker is situated about 3 mm. behind 
 the oral. The cuticle is studded with minute spines directed back- 
 ward. The bifurcations of the ahmentary tract have ramifying 
 branches. The vulva is situated beside the male opening or a little 
 behind it. 
 
 Length, 20-30 mm. {%-\H inches); width, 10-13 mm. (73-3^ an 
 inch). 
 
 The eggs are brown or greenish-yellow, provided with an operculum 
 a,t one end. They are oval and 130-145 microns in length. 
 
 2. Dicrocoelium lanceatum (Fasciola lanceolata). The Small Liver 
 Fluke (Fig. 87). Trematoda (p. 156).— The body is slender and 
 lancet-shaped, mottled brown by contained ova. The integument is 
 smooth and semi-transparent. The intestine has two nonramifying 
 branches. 
 
 Length, 4-9 mm. (3/16-3/8 of an inch); width, 2.5 mm. (1/8 of an 
 inch) . 
 
 The eggs are oval, brownish in color, 37-40 microns in length, and 
 provided with an operculum. 
 
 3. Fasciola magna (F. americana, Distomum americanum, D. mag- 
 num). The Large American Liver Fluke (Fig. 87). Trematoda 
 (p. 156). — Similar to F. hepatica, but larger, measuring 25-33 mm. 
 (1-13^ inches) in length and 12-17 mm. (J^-^) of an inch in 
 width. 
 
 Life History of Fasciola hepatica. — The eggs leave the uterus be- 
 fore the beginning of embryonic development and pass to the outer 
 world by way of the bile ducts and intestines. In heavy infestation 
 enormous numbers may be passed by a single host animal, one mature 
 fluke producing in the neighborhood of one hundred thousand eggs. 
 
PLATYHELMINTHES 161 
 
 After a period of embryonal development, which will only occur pro- 
 viding the eggs have reached water and suitable conditions of tempera- 
 ture, the larva escapes by the lifting of the operculum of the shell. It 
 is then in the stage of the miracidium (Fig. 88, 2), an infusorian-like 
 organism, cihated, elongated, broader in front, and about 130 microns in 
 length. During its free-swimming period it must meet with a suitable 
 host within a few hours or it will perish. This host is a small snail, 
 usually of the genus Limnjea (L. 
 humilis) into which the larva 
 bores its way by a perforating 
 rostrum at its anterior extremity. 
 If it escapes its aquatic enemies 
 during this free stage and arrives 
 at a suitable location within the 
 snail, usually the pulmonary 
 chamber, the larva loses its cilia 
 and digestive tube and becomes 
 transformed into a sporocyst (Fig. yig. 87.-Left to right, Fascioia hepatica, 
 
 88, 3) — a sort of reproductive sac, F. americanus, Dicroccelium lanccatum; 
 
 ovoid in form and acquiring a l^^^lf ^'^^ ^'^'■''^^^"" ^'""^ ^"*^°'"'^ ^p^"" 
 length of about 0.5-0.7 mm. The 
 
 cyst now becomes filled with germ-cells which are disposed in masses 
 (morula) ordinarih' five to eight in number. 
 
 The masses of germ-cells become transformed into so manj- redice 
 (Fig. 88, 5 and 6) which may be seen in different stages within the cyst. 
 The rediae are cylindrical in form and have a simple intestine and 
 pharynx with lips turned out like a sucker. When they have attained 
 a certain stage of development the rediae become actively motile, finally 
 rupturing the maternal cyst and passing to another organ of the snail, 
 usually the liver, in which location Xhey grow to a length of 1.3-1.6 mm. 
 Within the body of the redia are germ-cells formed into six to ten cellular 
 masses which are to be transformed into so many daughter rediae, or 
 directly into fifteen to twenty cercarice (Fig. 88, 7). Both daughter 
 rediae and cercariae leave the mother redia by a birth-opening located 
 anteriorly. 
 
 The developed cercaria has an oral and ventral sucker, a muscular 
 pharynx, and a bifurcated intestine which is as yet without lateral 
 branches. It has a flat oval body about 0.28 mm. in length, provided 
 with a long actively vibratile tail. The cercariae escape from the snail 
 and swim about energetically ui the water, eventually finding their way 
 to an aquatic plant or grass stalk. Here the tail is lost and the cystoge- 
 nous cells of the body form a mucoid substance which serves both to 
 encyst the cercariae and to attach them to the grass. The cysts may be 
 observed upon the specimens of vegetation as little white points about 
 
162 PARASITES OF THE DOMESTIC ANIMALS 
 
 the size of an ordinary pin-head. An encysted cercaria will remain alive 
 for an extended period as long as the grass upon which it is lodged is 
 
 Fig. 88. — Life history of liver fluke: 1, egg containing de- 
 veloping embryo; 2, free swimming miracidium; 3, sporocyst; 
 3a, snail of the genus Limnaea; 4, division of sporocyst; 
 5, sporocyst containing developing redise; 6, redia with cer- 
 carise or more redise developing within it; 7, cercaria; 8, young 
 fluke (after Thomson, from Thomas). 
 
 supplied with moisture. Drought probably destroys it, though the 
 length of time it may survive such conditions is undetermined. 
 When plants bearing these cysts are eaten by grazing animals the 
 
PLATYHELMINTHES 163 
 
 cysts, upon reaching the stomach, are dissolved, setting free the par- 
 asites which, passing to the intestine, enter the bile ducts and there 
 become mature. After laying their eggs the majority of the flukes pass 
 down the bile ducts to the mtestine where, under the hifluence of the 
 digestive juices, they shrivel and die. 
 
 The period of time occupied ])y the entire cycle is so influenced by 
 climatic conditions that no definite estimate as to it can be given. 
 As a rough approximation, twelve weeks may be given as about the 
 time required under such favorable conditions as usually prevail during 
 the summer season. 
 
 The life histories of Dicrocoelium lanceatum and Fasciola magna are 
 probably essentially similar to that of F. hepatica, but are as yet not 
 definitelv known. 
 
 Tabular Review^ of Life History of Fasciola Hepatica 
 Adult Fluke. — In bile duct of liver of rmninant. 
 
 I 
 Egg.— Free. 
 
 I . 
 ^liracidium. — Free. 
 
 I 
 Sporocyst. — In puhnonarj' chamber of snail. 
 
 I ^1 
 
 Sporocysts 5 to 8 Redise. 
 
 [ I 
 Redise. — In liver or other organ of snail. 
 
 Daughter Rediae 15 to 20 Cercarise 
 
 Cercarise. — Free. 
 
 I 
 Cvsts. — Upon grass stalks or other vegetation. 
 
 Adult Flukes. — In bile duct of Uver of ruminants after 
 ingestion of c^'sts. 
 
 Prevalence. — The loss from hepatic fascioliasis in England was for 
 a time in the neighborhood of three million head of sheep annually. 
 It was principally for this reason that investigations were made by 
 which the life history of the parasite was determined, and by which 
 was revealed the essential alternation between the sheep and snail 
 host. This pointed the way for measures of control consisting mainly 
 in the elimination of snails by the drainage of pastures or in the limiting 
 
164 PARASITES OF THE DOMESTIC ANIMALS 
 
 of the sheep to pastures free from standmg water or overflow. Since 
 the adoption of such preventive measures the loss from this source in 
 England and other European countries has been greatly reduced. 
 
 While fascioKasis has not been as prevalent in the United States as in 
 Europe, there are a sufficient number of cases to demonstrate the pos- 
 sibility of its becoming so unless such precautions are taken as are in- 
 dicated by the life historj^ of the fluke. Probably the freedom from such 
 destructive prevalence has been largely due to the fact that in this 
 countrj', more generally than in Europe, it is the practice to turn sheep 
 upon higher and diyer pasturage. 
 
 The three species of flukes which have been mentioned mfest the 
 liver, therefore the hepatic form of fascioliasis is the most important. 
 As would be concluded from the mode of infection, herbivorous animals 
 are most often affected, those which crop the grass close to the ground, 
 as sheep and goats, being for this reason especially susceptible. Horses, 
 swine, Carnivora, and even man may be invaded incidentally by flukes, 
 though in such cases they are rarely present in such numbers as to produce 
 perceptible disturbance. The giant fluke {Fasciola magna) is most often 
 found in the liver of deer or cattle in the Southwestern portion of the 
 United States. It is supposed to be a species native to wild rummants 
 before the introduction into this country of those in domestication. 
 
 Infection. — While infestation of sheep most frequently occurs from 
 the ingestion of plants upon which the encysted cercarise are attached, 
 water contaminated with detached cercariae may infect directly, or by 
 vegetation over which it has washed. It is probable that many cases 
 in cattle in the United States result from the introduction of the flukes 
 by the latter means. Cattle are not as close grazers as sheep, but the}- 
 drink more frequently, often from shallow collections of water which 
 may contain larvae derived from the excrement of sheep or rabbits. 
 
 As many encj^sted cercariae survive the frosts even of the late fall, 
 the season during which infection may take place is somewhat extended, 
 some investigators claiming that it may occur at any time of the year. 
 However, warmth being highly favorable to the development of the ova, 
 it is essentially during the summer and early autumn that animals are 
 most likely to become invaded. It is obvious that the most numerous 
 and most severe cases would occur in seasons of copious rainfall, more 
 elevated pastures at such times affording by their collections of water 
 and overflow favorable conditions for the development of the parasites. 
 The flukes may be introduced into lands previously free from them 
 by new stock, or by wild herbivorous animals, such as deer and rabbits. 
 After infestation has once taken place, it will, through successive in- 
 fections, mcrease in degree the longer the pasture is used. 
 
 Migrations and Pathogenesis. — It is probable that the migration 
 of the parasites from the small intestine into and along the bile ducts 
 
PLATYHELMINTHES 165 
 
 is accomplished by the extending forward of the parasite's anterior 
 end, with alternate fixing of the oral and ventral sucker.- The majority 
 remain in the bile ducts, though some upon reacliing the smaller ducts 
 break through and pass into the liver tissue where they msiy excavate 
 and destroy large areas. Such migrations may extend through Ghsson's 
 capsule to the serous covering of the organ and thus give rise to per- 
 itonitis in addition to the inflammation of the hepatic parenchj-ma. 
 They do not essentially remain confined to the liver, but may pass 
 through the capsule and serosa into the peritoneal cavity. Others may 
 reach the ramification of the portal vein and set up an endophlebitis 
 with accompanying thrombosis and embolism; or the hepatic veins may 
 be involved and some flukes be carried by the blood current to the 
 thoracic organs. 
 
 The destruction of liver tissue in hepatic fascioliasis is largely the 
 result of direct irritation due to the spiny processes covering the par- 
 asites. During the first few weeks after being taken up by the host the 
 flukes are small and do not cause a serious irritation. Later the}' set 
 up an acute inflammatory condition of the bile ducts and liver tissue, 
 the hepatitis remaining more or less localized or becoming generalized 
 according to the number of parasites present and the extent of their 
 migrations. In certain cases there is abscess formation, or hemorrhages 
 may occur due to the breaking down of the walls of blood vessels. The 
 inflammation running a chronic course is associated with connective 
 tissue prohferation, causing a thickening of the walls of the ducts. Later 
 this process extends to the interlobular connective tissue and brings 
 about cirrhosis of the liver. 
 
 Flukes which have remained in the bile ducts pass back into the 
 duodenum soon after the reproductive function has been accomplished. 
 It is thought by certain investigators that the period of time which 
 the}' remain in the ducts does not exceed nine to twelve months. Within 
 the intestines they are much altered b}' the intestinal juices and pass 
 from the host with the excrement. z 
 
 6 -' 
 
 Fascioll\sis of Sheep ^^---^ 
 
 Symptoms and Course. — An animal harboring but few flukes will 
 give no evidence of functional disturbance. This can be readily dem- 
 onstrated in sheep-slaughtering establishments where moderately in- 
 fested livers have been repeatedly found in sheep in prime condition. 
 In heavier infestations a developing period of about three to six weeks 
 intervenes between the taking up of the flukes and the appearance of 
 s>'mptoms. 
 
 In sheep usually the first s\aiiptom to be noticed is dullness, man- 
 ifested b}' slowness of movement and an inclination to lag behind the 
 
166 PARASITES OF THE DOMESTIC ANIMALS 
 
 flock. On examination of the visible mucosae (conjunctiva) and inner 
 surface of the ears they will be found to be paler than usual, and there 
 ma}' already be edematous swelling of the eyelids and under the brisket. 
 Notwithstanding the anaemia, the general phj'sical condition of the 
 animal may still be good; there is, in fact, a tendenc}^ to fatten, which 
 ma}^ be explained phj'siologicalh' in the increased assimilation of the 
 fat-forming elements of the food, brought about by the stimulationim- 
 parted by the flukes to the flow of bile. 
 
 This stage, however, is soon followed b}- a marked increase in dullness 
 and a disinclination to take food. The animal ruminates slowly and 
 irregularly, the fleece becomes chy and brittle, and in places may loosen 
 and drop out ; the skin and mucosae are whitish-yellow in color, the puffy 
 conjunctiva forming a prominent ring about the cornea. Though the 
 gheep ma}' still be fat, weakness and disinclination to resist handling 
 become moi'e pronounced. With progressiveh' diminished appetite, 
 however, there is loss of flesh, and the edema of the dependent parts 
 increases, involving the lower part of the neck, throat, and cheeks. The 
 presence of ascites is evinced upon percussion of the pendulous abdomen, 
 and the respiration becomes labored and frequent. 
 
 With these s\anptoms, which generalh' appear about the third month 
 after infestation, the disease is at its maximum, usually reached in the 
 early winter inonths. The anaemia, edema, and cachexia have now 
 become more pronounced ; in most of the advanced cases there is diarrhea 
 by which large numbers of eggs may be distributed about. Finally, 
 in a condition of extreme emaciation and weakness, the animal dies. 
 
 Prognosis. — ]\Iost of the losses from fascioliasis of sheep are among 
 the lambs. Older animals and those but moderately infested gradually 
 recover with the passage of the flukes from the liver into the intestine, 
 this usually occurring in the early spring. With the disappearance of 
 the edematous swellings and the return of the appetite, the animal re- 
 sumes a good physical appearance and seems to completely recover. 
 The hver lesions, however, will not entirely heal, and, impairing the 
 function of the organ, will eventually have a deleterious effect upon 
 the animal. 
 
 , Fascioliasis of Cattle 
 
 In cattle fascioliasis presents the same s\'mptoms as in sheep. Due 
 to the greater resistance of these animals, however, the effects are much 
 less severe and maj^ often pass unperceived. If the flukes are numerous 
 there maj^ be digestive disturbances manifested b}- loss of appetite, 
 diarrhea, and t^-mpanites; very rarely there are edematous swellings in 
 the dependent parts of the body. Fatalities from fascioliasis are rare 
 among cattle. When they occur it is usualh' among calves which have 
 reached an advanced emaciation. 
 
PLATYHELMIXTHES 167 
 
 Family II. Amphistomid.e 
 
 Amphistomum cervi {A. conicum) is a species belonging with this 
 family not infrequently found in the rumen of domestic ruminants of 
 this and other coimtries. Specimens collected in the Penns3'lvania State 
 Laboratory measure 6 to 7 mm. (3/16 to 1/4 of an inch) in length. The 
 body is conical m form, thick, attenuated anteriorh', gradually en- 
 larging posteriorly, the posterior end being obtuse and a little curved 
 ventral ly. The mouth is terminal and surrounded by a small sucker. 
 At the thickened posterior extremity there is a second and much larger 
 sucker. The color is white or reddish, darker at the attenuated anterior 
 portion. Hermaphroditic; genital orifices ventral and median, situated 
 in the anterior third of the body. Its development is not known. 
 
 This fluke is a parasite in the rumen of the ox and other domestic 
 and wild ruminants. It fixes itself by means of its posterior sucker 
 between the papillae of the rumen. Being very easily overlooked in its 
 resemblance to the papillae, it is quite probable that it is more prevalent 
 than would appear from our present records. 
 
 The parasite has been considered as inoffensive to the health of the 
 host animal. 
 
 Control of Fascioll\sis 
 
 In sections where fascioliasis has appeared a prophylactic measure 
 of first importance is the avoidance of pastures which are wet or contain 
 collections of water affording habitation for snails. The following direc- 
 tions formulated b}' Thomas — as stated by Neumann — for limiting the 
 ravages of fasciohasis are here quoted m part : 
 
 "a. Destroy the diseased sheep and bury them. 
 
 "b. Only put on dvy pastures affected sheep intended for the butcher, 
 as the fluke ova they evacuate cannot develop in the absence of humidity. 
 
 "c. As hares and rabbits — which are sometimes bearers of distomes — 
 may infest pastures, they should not have access to those on which 
 sheep graze. But this recommendation cannot well be carried out. 
 
 "d. Drain wet pastures, or, if this cannot be accomplished, dress 
 them with salt or lime. The latter in solution — 0.75 per cent. — will 
 destroy fluke embryos as well as the snails. With regard to salt, we are 
 indebted to Perroncito for some precise notions as to its action. Erco- 
 lani had for a long time observed that water slightly impregnated with 
 salt killed the cercariae, and in acting on these and on the encysted 
 larvae of the Limncea palustris. Perroncito found that in a 2 per cent, 
 solution these parasites died in less than five minutes; in a 1 per cent, 
 solution they rolled themselves up at the end of two to seven mmutes, 
 and perished after twenty to thirty-five minutes. The same happened 
 in 0.64 per cent, solutions: and in those of 0.25 per cent, they were still 
 
168 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 alive after more than twenty hours. The period when salt or lime 
 should be spread on the pastures should coincide with the time when 
 the embryos of the distomes and the cercarise abound — that is, June 
 and July for the first, and August for the second." 
 
 If it is impracticable to keep sheep from land upon which conditions 
 are favorable for the development of flukes, they should each be given 
 in the morning daily two drams of salt mixed with feed. When possible, 
 the salt may also be given in their drinking water in the proportion of 
 0.5 per cent. The salt is fatal to the ingested cercarise and tends to 
 fortify the sheep b}' favoring digestion and assimilation. 
 
 Treatment. — No effective therapeutic agent for fascioliasis has as 
 yet been found. Owing to the remote location of the parasites, it is 
 hardly likeh' that anything could be given which would affect them. 
 
 BiLHAKZIOSIS 
 
 This name has been given to a disease of cattle and sheep caused by 
 the blood fluke Schistosoma hovis {Bilharzia bonis; B. crassa) of the family 
 Schistosomidse. 
 
 In this trematode (Fig. 89) there is presented the pecuharity of sep- 
 arate sexes. The female, longer and much nar- 
 rower than the male, is filiform, 18-20 mm. {% 
 of an inch) in length, and has a buccal and ven- 
 tral sucker. The male is cylindrical, about 14 mm. 
 {}/2 an inch) in length, and has two suckers. It 
 carries the female in a ventral furrow formed by 
 the two sides of the body which are broad and 
 reflected inward. Both male and female genital 
 apertures are situated immediately behind the 
 ventral sucker. 
 
 The eggs are elongate, and at one pole termi- 
 nate in a pyriform point. They pass from the 
 host with the feces and urine, and, in the presence 
 of water, set free a ciliated embiyo. 
 
 This parasite has been found in the portal and 
 abdominal veins of cattle of tropical and sub- 
 tropical countries. The parasites themselves 
 seem to do but little injury. The eggs, however, 
 by their accumulation and sharp points, may 
 rupture the capillaries. If these are of the 
 genito-urinary system, the chief s\nnptom is a bloody urine. Where 
 the eggs have accumulated in the capillaries of the bladder, they rup- 
 ture these and, passing through the mucosa, fall into the cavity of the 
 organ. The resulting cystitis is manifested In' the hsematuria and the 
 
 Fig. 89. — Schistosoma 
 bovis, male and female, — 
 enlarged. 
 
PLATYHELMINTHES 169 
 
 pain which accompanies micturation. If the parasites are contained 
 in the veins of the rectum, there are similar lesions in this organ; the 
 feces may be stained with blood, and there is a condition somewhat re- 
 sembling piles. 
 
 Diagnosis is best made by a microscopic examination of the urine 
 to determine the presence of the eggs which may be readily recognized 
 by their characteristic elongate shape and polar termination in a sharp 
 point. 
 
 As the lesions are produced by the eggs, the severity of the symptoms 
 will essentially depend upon the number of parasites present. In the 
 majority of cases the infection is light and may give rise to no more than 
 a slight chronic C3^stitis. In the more rare cases of severe infection death 
 may ensue from rupture of the bladder or from uraemia accompanying 
 an acute nephritis. A heav}^ intestinal infection may bring about an 
 exhausting and fatal dysentery. 
 
 It is probable that infection has its source in contaminated drinking 
 water. Therefore, where bilharziosis has made its appearance, the water 
 should, as a preventive measure, be filtered, or the cattle removed to an 
 un contaminated supply. 
 
 Treatment can only be applied to the relief of sjaiiptoms as they 
 appear. 
 
 Class II. Cestoda 
 
 Platyhelminthes (p. 156). — An important character of the cestodes 
 is that, as a result of their advanced parasitism, they have lost the last 
 trace of an alimentary canal, and obtain their nourishment by absorp- 
 tion through their integument of the partly digested food of the host. 
 Also markedl}^ distinguishing them are the two developmental stages, — 
 the bladder worm (Fig. 112, h and c) and the mature worm (Fig. 107) 
 with its sexuall}^ developed segments, the first living usually in tissues, 
 such as muscular, liver, nervous, and serous, of the intermediate host; 
 the second in the alimentary tract of the definitive host. The adult is, 
 in its general form, band-like, and consists of two parts, — the scolex 
 (Fig. 109), which is generally referred to as the head, and a series of 
 segments which are formed from the scolex asexually by longitudinal 
 growth and transverse segmentation. It is due to this fact that an 
 animal is not rid of its tapeworm so long as the head is retained in the 
 intestine. As the segments are pushed on by the formation of younger 
 segments at the scolex, they become progressively wider and longer, 
 the width of the younger ones usually much exceeding their length, 
 while the oldest, which are those most distant from the scolex, may 
 become longer than wide. Each mature segment is hermaphroditic, 
 the uterus usuall}^ containing a large numl)er of eggs. In the Taeniidae 
 the genital pores (sexual openings) are on the margin or margins of the 
 
170 PARASITES OF THE DOMESTIC ANIMALS 
 
 individual segments. In the Diphj'llobothriidae they are on the flat 
 ventral surface. The number of segments varies from three or four 
 (Echinococcus granulosus) to several thousand (Diphyllobothrium latum), 
 a fact which gives to some species an enormous size. In the head is a 
 cerebral ganglion from which two principal nerves run backward, 
 usualh' near the lateral margins of the segments. An excretory, or so- 
 called water-vascular system, extends through the whole length of the 
 worm by two principal trunks which may be connected by vessels 
 running across the posterior margin of each segment, the system ter- 
 minatmg at the hinder edge of the last. 
 
 Of the Cestoda, two families are to be described as containing species 
 parasitic to domestic animals and man. These are as follows: 
 
 Family I. Taeniidse. 
 
 Family II. DiphyllolDothriidae. 
 
 Family L T.exiid.e 
 
 Cestoda (p. 169). — With rare exception, this family includes all of 
 the tapeworms of domestic animals and man in the United States. Its 
 members have the head furnished with four round or oval cup-like 
 suckers of muscular structure (Fig. 109), which, by their contraction, 
 produce a vacuum affording a close attaclmient to the intestinal mucosa 
 of the host. These suckers may surround a prominence, — the rostellum 
 (Fig. 95), or in other cases a depression more or less marked. The 
 rostellum may or may not be contractile, and may or may not be armed 
 with hooks. 
 
 As a typical, though not constant, arrangement of the reproductive 
 organs, those of the species Tcenia saginata, a tapeworm of man, are here 
 described. Each sexuall}' mature segment (Fig. 90) of this worm has 
 at its margin a protruding genital pore, which, from segment to segment, 
 is irregularh' upon alternate sides. This protuberance contains a 
 cloaca-like cavity into which open the vas deferens and vagina, both of 
 which extend laterally to the middle of the segment. Here the vas 
 deferens divides into a number of seminal ducts which are distributed 
 through the supporting tissue and serve to carry the semen from the 
 small spherical testes which are located almost everywhere in the seg- 
 ment. As it approaches the lateral cloacal sac, the duct becomes con- 
 voluted and much distended with the accmnulated seminal fluid. In the 
 vicinitA' of the cloaca it develops into a cirrus (penis) which is inclosed 
 in a muscular sheath. 
 
 The vagina bends downward as it passes toward the center of the 
 segment where it unites with the paired wing-like ovaries which are 
 rather large organs consisting of branched tubules. In the posterior 
 and middle portion of the segment is a single organ, hkewise of branched 
 
PLATYHELMINTHES 
 
 171 
 
 ° «t 
 "o •: 
 
 tubular structure, — the viteUarium or yolk-gland, the secretion from 
 which surrounds the eggs in the cavity of the shell-gland, the latter a 
 small bod}^ consisting of compacth' arranged gland-cells and located 
 just above the vitelline gland. From the shell-gland the eggs pass 
 through a narrow duct into the uterus, a simple tubular organ ascending 
 directly in the middle of the segment and closed at its distal end. The 
 uterus becomes much dis- 
 
 l 
 
 tended from the accumulation 
 of eggs and develops nu- 
 merous lateral branches to 
 which the other sexual organs 
 gradually give place until lit- 
 tle remains of them but ves- 
 tiges of the vas deferens and 
 vagina. The egg-engorged 
 organ, with its lateral cecal 
 pouches, may rupture, or the 
 integument of the segment, 
 itself may give wa}', permit- 
 ting the eggs to escape directly 
 into the intestinal contents. 
 A§ a rule these terminal or 
 ''ripe" segments are passed 
 to the outside of the body of 
 the host with the feces where, 
 by their disintegration, the 
 eggs are set free. 
 
 The eggs of cestodes are 
 globular or more or less oval 
 
 11 ^/<j^ 
 
 
 
 Fig. ',)0. — SeKineut of TiPnia saginata, with 
 sexual organs matured. Ovaries in lower portion 
 to right and left; yolk gland in extreme lower 
 portion; shell gland between yolk gland and ova- 
 ries; uterus, tubular organ extending upward; 
 vagina, extending from glands to genital pore at 
 left margin; testis, bodies distributed throughout 
 segment; vas deferens, convoluted organ extend- 
 ing laterally to genital pore. Excretory vessel 
 united by transverse commisures. Lateral longi- 
 tudinal nerves shown by heavy lines. 
 
 in shape and are provided with shells of variable thickness (Figs. 96 
 and 110). Beneath the shell is a translucent yolk which surrounds an 
 inner covering containing the onchosphere (hexacanth) or six-hooked 
 embryo (Fig. 112, a). In some forms the eggs as found in the feces 
 often have the outer shell absent. 
 
 Life History. — Species of Taeniidse in which the development is 
 known undergo a complex series of metamorphic changes, involving 
 larval and sexually mature parasitism in hosts of differing species. 
 After the egg, either free or with the segment entire, has been ingested 
 by a proper larval host, the shell and embryonic envelope are digested 
 away by the gastric juices, and the onchosphere is freed (Fig. 112, a). 
 At this stage the embrA'o is provided with three pairs of booklets by 
 which it penetrates the intestinal wall and, probably by blood and 
 l>auph currents, may be carried to certain parts of the body specifically' 
 essential to its further development. Thus passively lodged, it loses 
 
172 PARASITES OF THE DOMESTIC ANIMALS 
 
 its booklets and commonly becomes smTOunded by a capsule formed by 
 proliferation of the connective tissue of the host, though this does not 
 occur in all of the larval forms. 
 
 At this stage the larva, which is now a mere vesicle containing more 
 or less fluid and as yet without a head, is referred to as the acephalocyst 
 (bladder-cyst), from which there may, in certain forms (echinococcus), 
 develop multiple daughter cysts (Fig. 117). By a process of budding 
 from the germinal wall, the acephalocyst now develops a further stage, — 
 the cephalocyst (proscolex. Fig. 112, b and c), containing one (cysticercus, 
 Fig. 107) or more (coenurus. Fig. 114) heads which conform with the 
 scolex of the adult worm except that the larval head is invaginated. 
 
 If the larva while still living at this stage is conveyed to the digestive 
 canal of a suitable host for the adult worm, the head is evaginated from 
 the vesicle (Fig. 112, c), becomes detached from it, and, passing to the 
 intestine, fixes upon the mucosa by means of its suckers, to which attach- 
 ment the crown of hooks contributes if this is present. By a process of 
 budding, the scolex now proliferates a series of segments, each to be- 
 come bisexually complete (Fig. 90) . 
 
 Sexual maturity of the segments marks the stage of the adult worm 
 which, with its entire series, constitutes the chain, or, as it has been 
 called by most writers, the strobila, a term which, with that of proglottid 
 for segment, is discarded in this work. 
 
 Tabular Review of Life History of T^nia Saginata 
 Adult Tapeworm in intestine of man 
 
 I 
 Egg. — Expelled from intestine. 
 
 1 
 Hexacanth. — Freed from egg in digestive tract when 
 
 I ingested by ox. 
 
 Acephalocvst. — ^In striated muscle of ox. 
 
 I 
 Cephalocyst (Cysticercus) .^ Same. 
 
 Scolex. — Attached to mucosa of intestine of man 
 
 I after ingestion of cephalocyst. 
 
 Adult Tapeworm in intestine of man. 
 
 Parasitism. — The tapeworms afford an example of extreme para- 
 sitism. So far as known, their existence is wholly dependent upon 
 alternate cystic and adult hosts, their development exhibiting no free- 
 living stage. So advanced is their degeneracy that there is little of 
 organization remaining excepting the procreative, and this has acquired 
 
PLATYHELMINTHES 173 
 
 a hyperdevelopment adaptive to the hazards encountered in the worm's 
 life history. 
 
 The classification of the tapeworms has been somewhat more artificial 
 than S3'stematic in that it has not sufficiently taken into account mode 
 of development, a factor which should furnish the basis for their true 
 natural affinities. Their larvae may, with reference to method of develop- 
 ment, be placed in the five following forms: 1. Cijsticercus (Fig. 107); 
 2. cotnurus (Fig. 114); 3. echinococcus (Fig. 117); 4. cysticercoid (Fig. 
 96); 5. plerocercoid (Fig. 112,-e). The first three are found in organs 
 or serous cavities of Herbivora and Omnivora, occasionally in Carnivora; 
 the fourth lives mostlj' in invertebrates, and the fifth in the musculature 
 of fishes. The more recent tendency in cestode nomenclature is to con- 
 fine the generic name Taenia to those tapeworms which have a cysticercus 
 stage in their life history. 
 
 The cystic forms enumerated above, with the conditions which cer- 
 tain of them produce in their hosts, are taken up further on in the con- 
 sideration of the cestode larvae. 
 
 The accompanying tabular arrangement of the principal tapeworms 
 considered in this work, with their adult and C3'stic hosts, is inserted 
 for convenient reference. 
 
CHAPTER XV 
 
 T.^NIASIS 
 
 As to the effect of tapeworms upon their hosts, it may be said in gen- 
 eral that serious disturbances are most hkely to be manifest when the 
 worms are numerous, in which case the morbid effect is brought about 
 by the operation of several factors. There may be a reduction or com- 
 plete occlusion of the intestinal lumen with the usual inflammatory and 
 toxic disturbances or displacements following interruption in the move- 
 ment of the intestine's contents. While, as a general statement, in- 
 vasion of the bile duct by tapeworms may be said to be rare, the fringed 
 tapeworm of sheep {Thysanosorna actinioides) frequently enters this 
 organ and therefore constitutes a more serious tseniasis in these animals 
 than that from the Moniezia species. Armed tapeworms, by the irrita- 
 tion from their hooks, will, essentially, set up an inflammation of the 
 mucosa proportionate to their number. Further, where the worms are 
 numerous, their appropriation of nourishment contributes to the mal- 
 nutrition of a catarrhal enteritis. In heavj^ infestations the toxins 
 elaborated by the worms undoubtedly play a considerable part in the 
 general systemic effect. 
 
 The cystic forms of certain tapeworms have an important bearing 
 upon the sanitary control of meat food products. In our own country 
 this is especially true of the cysticerci of the two tapeworms of man, — 
 Tcenia saginata and T. solium, the cysts of the former being harbored 
 in beef, those of the latter in pork. The presence of these cysts in the 
 muscles or other parts of the bod}^ constitutes the disease known as 
 measles, to which affection the terms ''measly beef" and "measly pork" 
 have reference. While observed most frequently in the animals men- 
 tioned, measles may appear in sheep {Cysticercus tenuicollis, C. ovis), 
 and man is occasionally auto-infected by larvae (Cysticercus cellulosce) 
 of Tcenia solium which he harbors. 
 
 Cestodes of the Horse 
 
 Three species of tapeworms occur in the Equidae. In all the cephalic 
 armature and neck are absent, and all have a genital pore on the same 
 side in each segment. Nothing is known of their larval forms. 
 
 1. Anoplocephala perfoliata (Taenia perfoliata). Fig. 91. Tseniidse 
 (p. 170). — The head is large, rounded, and provided with well-developed 
 
.\dult 
 
 Hosts 
 
 Armature 
 
 Anoplocephala perfoliata 
 
 Horse and ass 
 
 Unarmed 
 
 Anoplocephala mamil- 
 lana 
 
 Horse and ass 
 
 Unarmed 
 
 Anoplocephala plicata 
 
 Horse and ass 
 
 Unarmed 
 
 Moniezia expansa 
 
 Cattle, sheep and 
 goats 
 
 Unarmed 
 
 Moniezia alba 
 
 Cattle, sheep and 
 goats 
 
 Unarmed 
 
 Moniezia planissima 
 
 Cattle, sheep and 
 goats 
 
 Unarmed 
 
 Thysanosoma actinioides 
 
 Sheep 
 
 Unarmed 
 
 Dipylidium caninum 
 
 Dog, cat, man 
 
 Armed 
 
 Ta;nia hydatigena 
 
 Dog 
 
 Arnied 
 
 Taenia pisiformis 
 
 Dog 
 
 Armed 
 
 Multiceps multiceps 
 
 Dog 
 
 Armed 
 
 Multiceps serialis . 
 
 Dog 
 
 Armed 
 
 Multiceps gaigeri 
 
 Dog 
 
 Armed 
 
 Echinococcus granulosus 
 
 Dog, cat 
 
 Armed 
 
 Tania taniajformis 
 
 Cat 
 
 Armed 
 
 Cittotaenia denticulata 
 
 Rabbit 
 
 Unarmed 
 
 Choanotsenia infundibu- 
 lit'ormis 
 
 Chicken 
 
 Armed 
 
 Hymenolepis carioca 
 
 Chicken 
 
 Armed 
 
 Davainea tetragona 
 
 Chicken 
 
 Ai-med 
 
 Davainea cesticillus 
 
 Chicken 
 
 Armed 
 
 Davainea echinobothrida 
 
 Chicken 
 
 Ai-med 
 
 Davainea proglottina 
 
 Chicken 
 
 Armed 
 
 Taenia saginata 
 
 Man 
 
 Unarmed 
 
 Taenia solium 
 
 Man 
 
 Armed 
 
 Ciphyllobothrium latum 
 
 Dog, cat, man 
 
 Unarmed 
 
Hosts 
 
 Parts Infested by Larva 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 Flea, louse 
 
 Body-cavity 
 
 Ruminants and hogs 
 
 Peritoneum 
 
 Rabbit 
 
 ^Mesentery and omentum 
 
 Herbivora 
 
 Central nervous system 
 
 Rabbit and other ro- 
 dents 
 
 Connective tissue 
 
 Ruminants 
 
 Central nervous system and 
 connective tissue 
 
 Ruminants and hog 
 
 Liver and lungs 
 
 Rat and mouse 
 
 Liver 
 
 
 
 House fly 
 
 
 
 
 
 
 
 
 
 
 Snail 
 
 
 Ox 
 
 Connective tissue of muscles 
 
 Hog and other animals 
 
 Connective tissue of muscles 
 
 Fish 
 
 Muscles 
 
T.^NIASIS 
 
 175 
 
 suckers; it is prolonged behind by rounded flaps on the upper and lower 
 side. The segments are very short, but wide, the width increasing 
 toward the middle of the length of the body. 
 
 Length, 2.5-3 cm. (1 inch); width, 3-15 mm. (1/8-5/8 of an inch). 
 
 The eggs, by mutual pressure, are polygonal. The shell, as in other 
 Anoplocephalinae, is prolonged by a pyriform point. They are 70-80 
 microns in length. 
 
 It lives in the small intestine and ceemn, more rarely in the colon. 
 
 2. Anoplocephala mamillana (TaBnia mamillana). Fig. 91. 
 Tsniidse (p. 170). — The head is small, somewhat angular, and has a 
 central lineal depression from before to 
 behind. It is provided with oval suckers 
 located upon the side. The segments are 
 nuich wider than long, progressively in- 
 creasing in width from the head. Their 
 length increases toward the posterior ex- 
 tremity, the last segments being about 
 half as long as broad. 
 
 Length, 1-5 cm. (3/8-2 inches); width, 
 4-6 mm. (i<4 of an inch). 
 
 The eggs are elongated and about 88 
 microns in length. 
 
 It infests the small intestine. 
 
 3. Anoplocephala plicata (Taenia 
 plicata). Fig. 91. Ta^niidse (p. 170).— 
 The head is rather large, broader than 
 long, slightly concaved in the center. 
 The four suckers are strong and are di- 
 rected forward. The segments progres- 
 sively increase in breadth and length to 
 the posterior extremity. 
 
 Length, 8-12 cm. (3 1/8-4 ^ inches); 
 width, 8-20 mm. (5/16-^^ of an inch). 
 
 The eggs are polygonal or round and 50-60 microns in length. 
 
 It lives in the small intestine and has been found in the stomach. 
 
 Occurrence. — Horses rarel}' harbor tapeworms. They are said to 
 be most often found in the horses of Russia and to some extent in 
 Germany and other European countries. The most common species is 
 Anoplocephala perfoliata, while of the other two mentioned, Anoplo- 
 cephala plicata is the luore rare. 
 
 Symptoms. — The presence of tapeworms in the intestines of the 
 horse is seldom accompanied by perceivable symptoms. Those general 
 to intestinal helminthiasis, as chronic digestive disturbances, with per- 
 haps anaemia and general unthrift, may accompany the infestation, 
 
 
 Fig. 91. — Tapeworms of the horse. 
 Left to right: Anoplocephala mamil- 
 lana, A. perfoliata, A. plicata, nat- 
 ural size. 
 
176 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 though it can only be assumed that these symptoms are caused by tape- 
 worms, even though the presence of the worms is made certain by the 
 voiding of the segments. 
 
 Cestodes of Cattle, Sheep, and Goats 
 
 Cattle harbor three species of tapeworms. In all the heads are un- 
 armed. Their larval forms are unknown. 
 
 The three species of tapeworms of cattle also occur in sheep and^ 
 goats. 
 
 1. Monieziaexpansa (Taenia expansa). Fig. 92. Tseniidae (p. 170). 
 The head is small, generally pear-shaped. The 
 suckers are slightly salient and slit-like. The an- 
 terior part of the chain is filiform. The first seg- 
 ments are very short, those which follow becoming 
 longer, but always much broader than long. The 
 
 Is = ^ broadest segments may reach a breadth of 2 cm. 
 = = (3<£ of an inch). The genital pores are double 
 M = ^ and located on the lateral margins of the seg- 
 ments. 
 
 The length varies considerably; it msiy be 15-30 
 feet or more. 
 
 The eggs are globular or polygonal and are 50-90 
 microns in diameter. 
 
 2. Monieziaalba (Taenia alba). Tseniidse (p. 170). 
 — The head is larger than that of the preceding 
 species and is provided with large oval suckers. 
 The neck is short and the segments are longer and 
 narrower than in M. expansa; some may be slightly 
 Moniezia longer than broad. The width of the broadest 
 segments is about 1 cm. (3/8 of an inch). There 
 are two genital pores in each segment. 
 Its maximum length is about eight feet. 
 The eggs are cuboidal and 48-58 microns in breadth. 
 3. Moniezia planissima. ' Tseniidse (p. 170). — The head is nearly 
 square and has slightly elongated suckers. The segments are much 
 broader than long, the ripe ones having a width of 12-26 mm. (3^-1 
 inch). These segments are very thin and semitransparent. Each seg- 
 ment has two genital pores. 
 Length, 3-6 feet. 
 
 The eggs are about 63 microns in diameter. 
 
 Thysanosoma actinioides (Taenia fimbriata). Tseniidse (p 170.). — 
 This is a species occurring in sheep, but has not been reported in other 
 domesticated Herbivora. The head is without hooks or rostellum. The 
 
 Fig. 92. 
 expansa, portions of 
 adult, reduced (after 
 Railliet). 
 
T.EXIASIS 177 
 
 segments are broader than long, having the uterus transverse and the 
 genital pores double or irregularly alternate. The segments have long 
 fringes on their posterior borders (Fig. 93). 
 
 Length, six inches or more. 
 
 Its larval form is unknown. 
 
 Occurrence and Symptoms. — All of these worms live in the small 
 intestine. As nothing is yet known of their cystic forms, the mode of 
 infection remains undetermined. Cattle are rarely disturbed in health 
 by the presence of tapeworms. In exceptional cases there may be 
 malnutrition and digestive disturbances accompanied by bloating. 
 Again, it is difficult to with certainty assign these nonspecific condi- 
 tions to the presence of tapeworms. As in all intestinal helminthiases, 
 there is to be borne in mind the possibility of the worms passing to 
 unusual locations, as the bile ducts, and of 
 interference with the movement of the in- 
 testinal contents by massed worms. 
 
 Of the domesticated herbivorous animals, 
 probably sheep most frequently harbor tai^e- 
 worms. A species often found in those of 
 the United States is Thijsanosoma aclinioidcs 
 Avhich, as is true of other species infesting 
 sheep, is most prevalent among the flocks of Fig. 93.— Thysanosoma ac- 
 the Western States. The worms may be tinioides, anterior segments,— 
 found at an}' time of the year, though more ^^ ^'^^^ 
 often during the season of grazing, a fact pointing to the probability 
 that the encysted larvae are taken up with the grass. Thysanosoma 
 actinioides, when brought to certain parts of the Eastern United States, 
 does not multiply. It may be assumed that this is attributable to 
 absence of the proper intermediate host, whatever that may be. In 
 parts of the west it constitutes a form of taeniasis much more severe than 
 that from ]\Ioniezia. This is due mainly to their invasion of the bile 
 duct, a habit which is exceptional with other tapeworms, but with the 
 fringed tapeworm it is the rule rather than the exception. 
 
 Lambs born in the winter and turned upon grass during the rains 
 and moisture of spring are the more likely to suffer from tapeworm 
 invasion. In such cases, or in hea\y infestation, anaemia is indicated 
 by paleness of the \asible mucosae, and this may be accompanied by 
 loss of vivacity and more or less emaciation with arrest in development. 
 Straining and ineffectual efforts at defecation, with prolonged elevation 
 of the tail, are noticed, the feces later becoming unformed or even fluid 
 and containing the segments. 
 
 Death ma}' ensue in advanced emaciation and weakness, or before 
 reaching this stage if the intestine becomes obstiiicted by the worms 
 in mass or there are other resulting complications. Such a course is 
 
178 PARASITES OF THE DOMESTIC ANIMALS 
 
 rare in aged sheep. Where fatahties occur, they are usually among the 
 grazing lambs. 
 
 Cestodes of the Dog 
 
 Of the tapeworms of the dog, nine are considered here, among which 
 there is a wide variation as to frequency and importance. The first 
 eight of the species to be mentioned belong with the family Taeniidae; 
 the ninth is referred to under the Diphyllobothriidse. In all but the 
 last the head is provided with the crown of hooks, and in all the life 
 history is known. 
 
 1. Dipylidium caninum (Taenia cucumerina) . Fig. 94. Taeniidse 
 (p. 170). — The head is small and has a protractile rostellum surrounded 
 by the four suckers (Fig. 95). There are three to four rows of small 
 thorn-like hooks. The neck is slender, succeeded at first by narrow 
 trapezoidal segments. The nature segments are longer than wide and 
 shaped somewhat like a cucumber seed. They have a genital pore on 
 each lateral margin. 
 
 Length, 15-40 cm. (6-16 inches). 
 
 Eggs globular, 43-50 microns in diameter and grouped in small cap- 
 sules (Fig. 96). 
 
 The larva of this worm is a cysticercoid {Cryptocystis trichodedes) 
 found in the body-cavity of the biting louse of the dog, — Trichodedes 
 latus (Fig. 96). Lice are not sufficiently prevalent upon dogs, however, 
 to account for the frequent occurrence of this worm; in fact, later in- 
 vestigations have determined that the dog flea, Ctenocephalus cams, 
 and the human flea, Pidex irritans, harbor its larva, and it is probable 
 that the flea is its more common host. 
 
 2. Dipylidium sexcoronatum. Tseniidse (p. 170). — Hall and Wigdor 
 (Journal of the American Veterinary Medical Association, June, 1918) 
 refer to this tapeworm as follows: "Dipylidium sexcoronatum has been 
 reported from dogs in the United States at Bethesda, Md., and Detroit, 
 Mich., by Hall (1917). We find it fairly often here at Detroit and our 
 impression is that it is as common here as D. caninum. The strobila is 
 much narrower than D. caninum. Some of the specimens with a narrow 
 strobila appear to have only five rows of hooks and should be studied 
 with a view to determining whether D. sexcoronatum has sometimes five 
 rows of hooks, as well as six rows, or whether this material belongs to a 
 new species." 
 
 3. Taenia hydatigena (T. marginata). Fig. 97. Taeniidse (p. 170). — 
 The head is small, but little broader than the neck. The hooks are 
 large, 170-220 microns long, and number 30-34. The mature segments 
 are wider than long, the distal segments elongated. The gravid seg- 
 ments have a median longitudinal groove terminating in a notch pos- 
 
TiENIASIS 179 
 
 teriorly. The number of segments is about 400. The gravid uterus has 
 5-10 branches on each side. 
 
 Length, 1.5-2 meters (57-76 inches). 
 
 Eggs nearly spherical and 31-36 microns in diameter. 
 
 The larva is a cysticercus (Csyticercus tenuicollis) found in the per- 
 itoneum and, more rarely, in the pleura of loiminants and hogs. It has 
 also been reported from rotlonts and monkeys. 
 
 4. Taenia pisiformis (T. serrata). Fig. 98. Tseniidse (p. 170). — 
 The head is small, but little broader than the neck. The hooks are 
 large, 225-294 microns long and 34-38 in number. The segments are 
 at first narrow and much shorter than broad; those mature are approx- 
 imatel}' square. The distal segments are elongated (10-15 mm. by 
 4-6 mm.). The posterior margins of the segments project laterally, 
 giving to the lateral margins of the chain a serrated appearance. The 
 genital pores are prominent, and the utenis in gravid segments has 8-14 
 lateral branches on each side. 
 
 Length, 0.5-2 meters (19-76 inches). 
 
 Eggs oval, 36-40 microns long, 31-36 microns wide. 
 
 The larva is a cysticercus (Cysticercus pisiformis) which develops in 
 the mesentery and omentum of rabbits, and has been found in the mouse 
 and beaver. 
 
 5. Multiceps multiceps (Taenia coenurus). Fig. 113. Tseniidse 
 (p. 170).— The head is small and bears 22-30 hooks. Larger hooks have 
 a handle equal in length to that of the blade and wavy in outline. The 
 segments of the middle portion of the chain arc approximately square. 
 The distal segments are elongated (8-12 mm. long by 3-4 mm. wide). 
 The ripe segments are broader at their middle, narrowing toward their 
 ends which gives them somewhat the appearance of a cucumber seed. 
 The genital organs are well developed, 15-20 cm. (6-8 inches) from the 
 head, or toward the 125th segment. The genital pores are irregularly 
 alternate. The uterus has 16-25 lateral branches on each side. 
 
 Length, 40-60 cm. (16-23^ inches). 
 
 Eggs nearly spherical and 31-36 microns in diameter. 
 
 The larva is a coenurus (Multiceps multiceps; Coenurus cerebralis) 
 which develops in the cerebral cavity and, more rarely, in the spinal 
 canal of herbivora, usually sheep (Figs. 114 and 116). 
 
 6. Multiceps serialis (Taenia serialis).— Tseniidse (p. 170). The 
 head is a little wider than the neck and bears 26-32 hooks. The small 
 hooks have a short blunt handle; the larger hooks a wavy handle as 
 long or a little longer than the blade. The segments are similar to those 
 of M. multiceps, the form of the uterus in gravid segments also being the 
 same. 
 
 Length, 44-74 cm. (17-293^ inches). 
 
 Eggs oval, 34 microns long, 27 microns wide. 
 
Fig. 96. — Egg packet of Dipylidium 
 caninum (left); Cysticercoid (right). 
 
 Fig. 95. — Head of 
 Dipylidium caninum, 
 with I'ostellum pro- 
 jected. 
 
 Fig. 94.— Dipyli- 
 dium caninum, por- 
 tions of adult,— ^ 
 natural size. 
 
 Fig. 9S. — Taenia pisiformis, 
 portions of adult, — natural size. 
 
 Fig. 97. — Tsenia hydati- 
 gena, portions of adult. — nat- 
 ural size. 
 
T.ENIASIS 181 
 
 The larva is a coeniirus (Multiceps serialis; Ccenurus serialis) found 
 in the connective tissue of rabbits and other rodents. 
 
 7. Multiceps gaigeri. Taeniidae (p. 170). — This is a species found 
 in India and Ceylon, and described b}' Hall (Journal of the American 
 Veterinarj'^ Medical Association, November, 1916), the larva of which 
 develops m the central nervous system and also in the connective tissues 
 and serous surfaces of ruminants. Thus in its cystic host this species 
 combines the location of M. multiceps and M. serialis, the larva, as in 
 that of the latter, forming an adventitious capsule. 
 
 The material for examination (Bureau of minimal Industrj^, Hel- 
 minthological Collection) consisted of specimens of tapeworms from 
 the dog and the ccenurus from the goat. From his stud}' of these, Hall 
 (1916) regards this species as more closeh^ related to the gid tapeworm, 
 M. multiceps, than to M. serialis. 
 
 8. Echinococcus granulosus (Taenia echinococcus). Fig. 99. 
 Taeniidae (p. 170). — The chain is but 4-6 nun. (3/16-1/4 of an inch) in 
 length, and is composed of a head and three segments. The head is 
 provided with 28-50 small hooks arranged in two rows. The first and 
 second segments from the scolex are incompletely developed, but one 
 segment at a time becoming gravid, — the third, when its length almost 
 reaches that of the rest of the worm. 
 
 Eggs oval, 32-36 microns long, 25-26 microns broad. . 
 
 The larva is an echinococcus {Echinococcus granulosus; E. polymor- 
 phus) found in the internal organs, usually the liver and lungs, of rumi- 
 nants and hogs, and also in man (Fig. 117). 
 
 Occurrence. — It follows from their habits that dogs should more 
 frequently harbor intestinal parasites than other domestic anunals. 
 Probably over fifty per cent, are infested with varied species, frequently 
 in considerable number. Of these, tapeworms predominate, several 
 species of which often inhabit the intestine of a single individual. 
 
 The intermediate hosts of Dipylidium caninum — fleas and lice, the 
 former ubiquitous in relation to canine existence, — would account for 
 the greater frequenc.y of this tapeworm than any other in dogs. Dogs 
 which have access to butchers' offal are, in addition to this species, 
 readily infected with Echinococcus gramdosus, Tcenia hydatigena, and 
 Multiceps multiceps, the cystic forms of which are harbored in organs 
 of the principal meat-food animals, sheep, hogs, and cattle. Hunting 
 dogs and those which roam afield are the most exposed to invasion with 
 TcBnia pisiformis and Multiceps serialis, these having their larval devel- 
 opment in rabbits. In an}^ case, young dogs are more susceptible to 
 intestinal helminthiasis than those which are older. 
 
 Symptoms, — Notwithstanding their frequent presence in large num- 
 bers, tapeworms seem, as a rule, to have little deleterious influence 
 upon the health of dogs. As is tme of intestinal worms in general, 
 
182 PARASITES OF THE DOMESTIC ANIMALS 
 
 their accumulation may bring about obstruction with attendant dis- 
 placement and degenerative changes in the intestinal walls; and, again, 
 there ma}'' be a serious and even fatal result from their unusual location. 
 Such consequences of taeniasis are, however, exceptional in dogs. In 
 general, the s\miptoms are those of chronic gastro-intestinal catarrh. 
 The capricious appetite varies between extreme voraciousness and com- 
 plete anorexia. Regardless of the amount of food consumed, there is a 
 noticeable emaciation which may become well marked, young dogs 
 especially becoming pot-bellied and stunted in growth. More char- 
 acteristic is restlessness, straining, and itching about the anus, the latter 
 manifested by agitation of the tail and a peculiar squatting and dragging 
 of the hind parts, sometimes referred to in the expressive, but highly 
 untechnical term, ''rough-locking." 
 
 With increasing uneasmess, the development of intestinal pains, 
 howling, and an inclination to bite, which is perhaps conjoined with a 
 dull or wild expression, there are presented symptoms somewhat similar 
 to those of rabies. In such cases convulsions may set in and the animal 
 may die during an attack, or it may gradually succumb after sinking 
 into a cataleptic condition. 
 
 Pathogenesis. — Necropsies upon dogs which have suffered from 
 taeniasis generally show the worms lodged in the small intestine only. 
 Probably as a result of post-mortem wandering, they may also be found 
 in small numbers in the large mtestine or stomach. The inflammation of 
 the mucosa is especially extensive and of aggravated character in in- 
 festation with Echinococcus. This is a tapeworm of the dog which, 
 though relatively very small, sets up the greatest irritation bj'- reason 
 of the vast number of individuals present, w^hich, firmly implanted by 
 their hooks, may completely cover the intestinal lining over large areas. 
 Where obstruction occurs in taeniasis, it is generally brought about by 
 the presence of the larger tapeworms massed in coils. Dipylidium 
 caninwn, though smaller than some other species inhabiting the dog, is 
 most likely to be found the offending agent in such conditions because 
 of its prevalence and the presence of numerous individuals in the 
 same host. The projecting rostellum of this species, sinking deep 
 into the mucosa, is also a factor increasing its capabilities for dam- 
 age. Tcenia hydatigena and T. pisiformis are much larger, but less 
 common, while Midticeps multiceps and M. serialis have thus far 
 been found more commonly in European countries than in the 
 United States. 
 
 Contributing to the systemic effects of tapeworm invasion, there is, 
 as in other helminthiases, the operation of toxins elaborated by the 
 worms." In cases of heavy infestation this factor must be a considerable 
 one, especiallj' when combined with that of poisons derived from the 
 dead and decomposing bodies of the parasites. 
 
TiENIASIS 183 
 
 Diagnosis. — The presence of tapeworms may in most cases be recog- 
 nized b}" the passing of segments, or fragments of the chain, with the 
 feces; occasionally these may also be expelled with vomited matter. 
 Often the fragments may be arrested near or partly protrude from the 
 anus, causing a pruritus in this region which the animal endeavors to 
 relieve by rubbing the parts upon the ground. 
 
 Diagnosis may be assisted in doubtful cases by the administration 
 of a laxative, in the operation of which detached portions of the chain 
 will be expelled if present. Echinococcus, however, on account of its 
 small size, is likely to escape observation in the ordinary means of 
 examining fecal matter. 
 
 Dog Tapeworms in Relation to Human Infection. — Two species of 
 tapeworms harbored by dogs — Echinoccocus granulosus and Dipylidium 
 caninum — are especially of medical interest in that they ma}' also 
 infect man. The first mentioned produces in its larval development a 
 condition known as hydatid disease, or echinococcosis, in man as well 
 as in numerous lower animals. 
 
 The larval or, as it is called, the hydatid form of this tapeworm occurs 
 usually in the liver, lungs and kidneys of these animals, and may pro- 
 duce from the original cyst numerous daughter cysts, the growth going 
 on indefinitely and evolving bladders as large or even much larger than 
 an orange (Fig. 117). Due to its pressure, necrotic degeneration of 
 tissue, and also to secondary infection by bacteria, this growth gives 
 rise to serious disturbances in the organ in which it is lodged. In man 
 the condition is often fatal, less so in the lower animals, probably owing 
 to the fact that their term of life is shorter, or they are likely to be 
 slaughtered before sufficient time has elapsed for the full development 
 of the slow-growing hydatid. 
 
 A more detailed reference to the echinococcus c.vst is given further 
 on in the special consideration of the cestode larvse (p. 210). 
 
 The connnon tapeworm of the dog, Dipylidium caninum, may find 
 adult hostage in the human intestine. According to Hall (Bull. 260, 
 U. S. Dept. of Agriculture, 1915), seventy-six cases of this tapeworm 
 in man, mostly children, have been reported, a number of these from 
 the United States. It has been found in an adult thirty-eight years old, 
 and it is stated that as many as two hundred and fifty-eight of these 
 worms have been found in a single person. 
 
 Considering the privileges which are allowed dogs, it is quite apparent 
 that a flea or louse containuig the Cryptocystis might pass from the dog 
 to the human mouth by the dog licking the face, or through the inter- 
 mediation of food, especially sticky candy to which the insect readily 
 adheres. Children give little attention to incidental contamination 
 of their food, which is frequently partaken of in intimate proximity to 
 their canine companions, the dog often sharing in the feast — perhaps 
 
184 PARASITES OF THE DOMESTIC ANIMALS 
 
 from the same plate. It follows that human mfection with this tape- 
 worm occurs more often among children than among adults. 
 
 As in tseniasis of other animals, the presence of a few of these worms in 
 man is not likely to occasion serious disturbance, though to the human 
 conception, the presence of a tapeworm in the intestine is anything 
 but a pleasant thing to contemplate. Where they are numerous, the 
 irritation, possible obstruction, and other secondary compHcations which 
 may arise, make it, as in lower animals, a more serious condition. 
 
 Prevention calls for restraint in the liberties of dogs, especially about 
 children. Children should not be permitted to handle vagrant and 
 neglected dogs. Those kept about the premises as pets should be ob- 
 served for indications of the presence of tapeworms, and their bodies 
 should be kept free from fleas and lice. 
 
 Cestodes of the Cat 
 
 Of the tapeworms harbored by cats, onl}^ the species Tcenia tcenice- 
 formis is of importance as affecting their health. Others which have 
 been found are: Dipylidimn caninum, Echinococcus granulosus, and 
 Diphyllobothrium latum, the first two described under 
 the Tseniidse of the dog. These latter forms do not 
 appear to cause disturbance to the animal. 
 
 Taenia taeniseformis (T. crassicollis). Tseniidse 
 (p. 170).— The head (Fig. 100) is rounded, has four 
 prominent suckers and a strong rostellum provided 
 with 26-52 hooks. The neck is as wide as, or wider 
 than, the head, and there is no intermediate constric- 
 FiG. 100.— Head of tion. The segments follow immediately from the head, 
 Taenia taeniaeformis, increasing in size to a length of 8-10 mm. (5/16-3/8 
 
 Length, 15-60 cm. (6-23i^ inches). 
 
 Eggs globular, 31-37 microns in diameter. 
 
 The larva is a cysticercus (Cysticercus fasciolaris) inhabiting the 
 liver of rats and mice. 
 
 Occurrence and Symptoms. — This tapeworm is not uncommon 
 in the cat, often infesting the small intestine in large numbers and 
 seriously affecting the animal. 
 
 There is in the beginning a diminution of appetite which gradually 
 passes to refusal to take any food whatever. Diarrhea, at first slight,, 
 later severe, is succeeded by constipation; there is salivation, and in 
 some cases vision and hearing are seriously affected. Colic is a frequent 
 accompaniment during the attacks of which the animal may rush about 
 in a frantic manner, apparently heedless of or unable to see objects with 
 which it may come in contact. 
 
T.ENIASIS 185 
 
 Finally, as a manifestation of the nervous disturbance, there are 
 convulsions; there is much prostation and emaciation, and the animal 
 dies, usually during or shortly after an epileptiform attack. 
 
 Cestodes of Rabbits 
 
 Tapeworm infection is said to frequently appear enzooticall}' among 
 the wild hares of foreign countries. In domestic rabbits such infection 
 is rare. The species here described is occasionally found. It is unarmed, 
 and its life history is unknown. 
 
 Cittotaenia denticulata (Moniezia denticulata). Tseniidse (p. 170). — 
 The head is small, with fiat suckers. The neck is as broad as the head. 
 The larger segments may be 10 mm. (3/8 of an inch) in width, always 
 wider than long. The genital pores are on the posterior fourth of the 
 border of the segment. 
 
 It may reach a length of 8 cm. (3 inches). 
 
 There is little clinical experience with taeniasis of rabbits. In general, 
 what has been said as to such infection in other animals will apply as 
 well to them. Diagnosis can be made by finding the segments in the 
 feces, or by destroying and examining one or two suspected animals. 
 
 Family II. Diphyllobothriid.e 
 
 The best known representative of this family is DiphyUobothrium 
 latum (Dibothriocephalus latus, Bothriocephalus latus). The head is 
 oblong or lanceolate, unarmed, and has two deep slit-like depressions, 
 one dorsal, the other ventral, which serve as suckers (Fig. 109). The 
 neck is not well demarcated from the first segments which are scarcely 
 visible. The segments gradually increase in length and breadth; the 
 largest are 4-5 mm. long and may be 2 cm. wide (3/16 by 3/4 of an 
 inch). The gravid segments become much narrower as their genital 
 organs atrophy and the eggs are discharged, these being expelled in 
 greater part before the separation of the segments from the chain. In 
 sexually mature segments the rosette-shaped uterus may be seen in the 
 middle line. The genital pores are special orifices for ovulation, located 
 in the middle of the ventral surface of the segments (Fig. 101). 
 
 The length of the entire worm may be 2-7 meters (6-22 feet). It 
 may reach a length of 20 meters (Neumann). The segments may 
 number 3,000 or more. 
 
 The eggs are oval, operculated, and 68-70 microns long. In the 
 presence of water a ciliated embryo escapes from the egg by the lifting 
 of the operculum and swims about until it enters the body of a iresh- 
 water fish, said to be especially the pike. In the muscles of this host it 
 develops into the worm-Hke plerocercoid (Fig. 112, e). After the 
 
186 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 definitive host has eaten fish containing the hving kirvse, the tapeworms 
 develop rapidly, becoming mature in about four weeks. 
 
 Occurrence. — This species is sometimes called the broad Russian 
 
 IS^'f i lUBtti 
 
 Fig. 101. — Sections of Diphyllobothrium latum, — natural size (after Boas, by Kirkaldy 
 and Pollard, from Leuckart). 
 
 tapeworm. It infests man and fish-eating dogs in Russia, Switzerland, 
 Japan, Finland, Sweden, and other foreign countries. It is extremely 
 rare in the United States, and is of little medical or economic importance 
 here. 
 
 Teeatment of T^niasis 
 
 Treatment of Taeniasis of the Dog. — Therapeutic measures for the 
 expulsion of tapeworms have two consecutive objects in view; first, the 
 bringing about of a torpid condition or weakening of the worm; second, 
 the expulsion of the entire worm from the host. The first is attained in 
 part by depriving the parasite of its nourishment, and by the adminis- 
 tration of a vermifuge which should sufficiently further weaken it to 
 cause its detachment from the mucosa; the second by a purgative which 
 will expel the detached worm with the evacuations. 
 
 As preparatory to the action of the vermifuge, all food should be kept 
 from the animal for at least twenty-four hours immediately preceding 
 its administration; at the same time the cleaning out process will be 
 considerably aided if a mild laxative is given. Some advocate a milk 
 diet for several days, but in any case the fasting should be absolute for 
 a period of one day. 
 
 Of the vermifuge agents, those which have been found most reliable 
 as taeniafuges are: (1) male fern (aspidium); (2) areca nut; (3) kusso; 
 (4) kamala. Of these male fern is particularly serviceable. Depending 
 upon the weight and age of the animal, the oleoresin of aspidium may 
 be given to dogs in doses of fifteen minims to one dram. It can be 
 advantageously combined with small doses of areca nut (one grain per 
 pound of body- weight) , and conveniently administered in capsule. 
 Aspidium should never be given with oil as this favors its absorption, 
 and it is a local action which is sought. After three to four hours the 
 
T.ENIASIS 187 
 
 dose may be repeated, and twelve hours after the first dose a purgative 
 should be given. 
 
 The dog should be kept where its evacuations can be conveniently 
 examined, and, if it is found that the head of the tapeworm has not been 
 expelled, the treatment is to be repeated in a week to ten days. The 
 expulsion of the worm may be aided somewhat by rectal injections of 
 warm soapy water. 
 
 If areca nut is used uncombined, it may be given in doses of two 
 grains for each pound of body-weight. It can be conveniently adminis- 
 tered shaken up in a little milk. Areca nut in itself is laxative or purga- 
 tive according to dosage. If purgation has not followed within a few 
 hours after its administration, a full dose of castor oil should be given 
 ten to twelve hours later. 
 
 Kusso has an advantage in being quite safe even in excessive doses. 
 Small dogs take of the fluid extract one-half to one dram; large dogs, 
 two to four drams. It can be given in milk and repeated three times at 
 intervals of one hour. Vomiting, which sometimes follows the adminis- 
 tration of kusso, may be prevented by previously giving a medicament 
 having an anesthetic action upon the stomach. 
 
 Kamala is given to dogs in doses of one-half to two drams in honey or 
 syrup. In cases where heavj^ infestation is suspected it should be re- 
 peated in eight hours. Kamala has some purgative action and may 
 also nauseate; the latter effect can be corrected by the same means as for 
 kusso. 
 
 Other taeniafuges sometimes used are: (1) Pumpkin seeds, fed crushed 
 and macerated or as an infusion, and (2) turpentine, one-half to one 
 dram, given with the yolk of an egg and repeated mitil three doses have 
 been administered twenty-four hours apart. Turpentine, however, on 
 account of its irritant effect upon the kidneys, should be used with 
 caution. 
 
 ^^'hatever form of taeniafuge medication may be chosen, the chances 
 of success will depend much upon a brisk purgative action following 
 upon its operation. At best there is often failure to secure the head of 
 the worm, in which event a repetition of the whole treatment is called 
 for in the course of one to several weeks. 
 
 Prevention. — To prevent the spread of taeniasis, all expelled tape- 
 worms and their fragments should be destroyed by burning. Dogs 
 known to be infected had best be isolated and all of their excrement 
 burned. Dogs which have their meat cooked, and those which are not 
 allowed access to the viscera of slaughtered animals and rabbits, are 
 not so likely to be infected, though such precautions will not protect 
 them from the common species Dipylidium caninum, freedom from fleas 
 and lice, and prevention from association with dogs less fortunate in 
 this respect, being essential to avoidance of infection Iw this species. 
 
188 PARASITES OF THE DOMESTIC ANIMALS 
 
 Treatment of Taeniasis of the Cat. — For tseniasis of the cat the same 
 procedure may be followed and the same remedies used as for the dog. 
 The dosage, however, should be reduced and proportioned according to 
 the weight and age of the animal. 
 
 Prevention consists in restraining the animals from feeding upon 
 rats and mice, — the intermediate hosts of their most common tape- 
 worm, — Tcenia tceniceformis. 
 
 Treatment of Taeniasis of Sheep and Goats. — For several days pre- 
 ceding treatment of these animals it is advisable to feed moderately 
 upon green succulent food, avoiding bulk, as fodder and hay. Imme- 
 diately before giving the vermifuge all food should be withheld for a 
 sufficient time to make the animals quite hungry. Powdered areca nut 
 may then be given in one to two dram doses according to weight. It 
 can be administered mixed with bran or bran and chopped beets which 
 the sheep, made ravenous by their preliminary fast, will eat greedily. 
 Three hours afterward a purgative should be given and the evacuations 
 of each individual kept under observation for the appearance of tape- 
 worms. 
 
 Other vermifuges reconmi ended are: (1) Oil of turpentine, one to two 
 drams, given in one-half to one ounce of linseed, cottonseed, or olive 
 oil, and (2) kamala, forty-five grains to one and one-half drams in thin 
 syrup or water, the dose to be repeated once at an interval of four hours. 
 
 Treatment of Taeniasis of Cattle. — Where treatment is indicated for 
 the expulsion of tapeworms of cattle the animals should be dietetically 
 prepared as recommended for sheep. As a vermifuge, tartar emetic is 
 quite suitable for these animals. It may be given in one and one-half to 
 two and one-half dram doses in gruel. Oil of turpentine, three ounces 
 in a pint of linseed oil, makes a reliable remedy. Arsenic in daily 
 ascending doses for a period of fifteen days has also been recommended. 
 The vermifuge treatment should be followed by a purgative of glauber 
 salts. 
 
 Treatment of Taeniasis of the Horse. — The existence of tapeworms 
 in the horse generally remains unrecognized during life. The symptoms 
 are those general to intestinal helminthiasis of horses, and the treat- 
 ment is quite the same as that for ascariasis (p. 234). The animal is to 
 be removed from work, kept from hay, and fed only upon mashes. After 
 at least twenty-four hours of such preparation, give two to four ounces 
 of oil of turpentine, and one dram of oleoresin of aspidium in a pint of 
 linseed oil. Tartar emetic is also quite effectual. It should be given 
 in two doses of three drams each at an interval of twelve hours. It 
 may be mixed with a gruel of linseed meal. 
 
 <^' 
 
CHAPTER XVI 
 
 TAPEWORMS OF CHICKENS 
 
 Though tapeworms are comparativelj' frequent in chickens and other 
 domestic fowl, they have not up to quite recent times been the subject 
 of anj' considerable investigation in this country. In our hterature upon 
 the parasites in general, if not neglected entirely, but one or two species 
 are as a rule described, and these generall}' in an incomplete manner. 
 
 With the exception of but one species, what is at present known as 
 to the larval forms has been determined from studies upon poultry 
 cestodes in foreign countries. Thus far in these investigations the life 
 C3'cle of but one chicken tapeworm — Davainea proglottina — has been 
 experunentally demonstrated, the only one among the six here described 
 which has not been reported in this country. The remaining five have 
 been found infesting chickens in various parts of the United States. 
 
 1 . Choanotaenia inf undibulif ormis iDrepanidotama injimdi- 
 buUformis) (Fig. 102)— The head (Fig. 103) is small, globular 
 or conical, and bears a crown of 16-20 hooks. The suckers 
 are prominent, may be projecting. The neck is very short. 
 The first segments are short; those following are infundibuli- 
 form, with anterior border narrower than the posterior. The 
 genital pores are irregularly alternate. 
 
 The length varies from 2-23 cm. {%-^\^ inches). 
 
 Grassi and Rovelli, comparing cysticercoids which they had 
 found in flies (Musca domestica) with the adult Choanotcenia 
 inf undihidif ormis, noted a stmctural agreement from which 
 they inferred that the larvae were the intermediate stage of 
 this species. No experiments were carried on by these in- 
 vestigators, however, to demonstrate this connection. 
 
 Guberlet, of Oklahoma Agricultural and Mechanical Col- 
 lege, in a series of investigations upon chicken cestodes (1912- Fig. 102. 
 1914) seems to have conclusively demonstrated that the ^nia^^'Jnl 
 cysticercoid of Choanotcenia infundihidiformis occurs in the fundibuli- 
 common house fly. Briefly stated, his results were obtained formis, — 
 by raising cysticercoids in the flies by feeding them on the 
 eggs of the tapeworm. These flies were fed to three of six chicks 
 which had been removed from chance infection as soon as hatched. 
 Three weeks after such feeding all of the chicks were killed, and two were 
 found to be infested with Choanotcenia infundibuUformis. The three 
 birds used as a check on the experiment contained no worms. 
 
190 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 2. Hymenolepis carioca. — The head is piriform with retractile 
 rostelhim. It is unarmed. The segments nmiiber about 500, all much 
 wider than long; terminal segments measure 0.5-0.8 mm. The genital 
 pores are unilateral. The worm is very fragile and delicate. 
 
 Length, 3-8 cm. (1^-3 1/8 inches). 
 The life history is unknown. 
 
 3. Davainea tetragona( Tce/na tetragona). — The head (Fig. 104) is 
 small and tetragonal; rostellum armed with a crown of 100 hooks. The 
 suckers are oval and armed with 8-10 circlets of small hooklets. The 
 short neck is followed by short trapezoid segments, those terminal 
 
 Fig. 103.— Choano- 
 tsenia infundibulifor- 
 mis, scolex much con- 
 tracted, — enlarged 
 (after Guberlet, in 
 "Transactions of the 
 American Microscopi- 
 cal Society"). 
 
 Fig. 104.— Scolex of 
 Davainea tetragona, — 
 enlarged (after Guber- 
 let, in "Transactions 
 of the American Mi- 
 croscopical Society".) 
 
 Fig. 105. — Scolex of Davainea 
 echinobothrida, — enlarged (after 
 Guberlet, in "Transactions of the 
 American Microscopical Society".) 
 
 generally longer than wide. Their length varies between 1-4 mm. The 
 genital pores are unilateral. 
 
 The length varies between 1-25 cm. (3/8-10 inches). 
 
 Investigations of Plana point to certain little snails {Helix carthu- 
 sianella and H. maculosa) as the probable larval hosts of this species. 
 
 4. Davainea cesticillus {Tmnia cesticillus) . — ^The head is globular 
 and has a rostellum scarcely salient or depressed. It is armed with a 
 double crown of 400-500 hooklets which are loosely attached. The 
 suckers are small and unarmed. There is no neck. The first segments 
 are short and much wider than the head; the last are about as long as 
 broad. The genital pores are irregularly alternate. 
 
 Length, 1-4.5 cm. (3/8-1 3/4 inches). By some authors it is said to 
 attain a much greater length (10-13 cm.). 
 
TAPE^YORMS OF CHICKENS 191 
 
 According to Grassi and Rovelli the intermediate host is a lepidop- 
 terous or coleopterous insect. 
 
 5. Davainea echinobothrida (Tcenia echinohotJirida). — The small 
 head (Fig. 105) presents an infundibulum provided with a double crown 
 of about 200 hooks. The suckers are armed with 8-10 circlets. There 
 is no neck. The segments gradually increase in Avidth, the largest being 
 1-4 mm. The genital pores are irregularh' alternate. 
 
 Length, 5-25 cm. (2-93^ inches). 
 
 Nothing is known of its larval development. 
 
 This species has a characteristic pathological effect in that the scolex. 
 with its accessoiy armature about the suckers, bores through the in- 
 testinal mucosa, producing large nodules or ulcers. The condition in 
 fowls is termed "nodular tteniasis" and is described b}' Moore (Bureau 
 of Animal Industry, Cir. No. 3, 1895). The nodules are often mistaken 
 for other diseases showing similar features. 
 
 6. Davainea proglottina (Tcenia proglottina) . — The head is quad- 
 rangular, slightly rounded. The rostellum is armed at its base with 
 80-95 hooks. The chain is composed of 2-5 segments. The terminal 
 and largest segments have a tendency to detach and develop separately 
 in the intestine. These free segments maj- acquire a length exceeding 
 that of the entire chain. The genital pores are irregularly alternate. 
 
 Length, 0.5-1.55 mm. 
 
 Grassi and Rovelli have demonstrated that the larva of this species 
 is a cysticercoid which inhabits several species of snail — Limax cinereus, 
 L. agrestis, L. variegatus. 
 
 The species has not as yet been reported in this country. 
 
 Occurrence. — Guberlet, in a report of his investigations carried on 
 in Nebraska (Journal of the American Veterinary INIedical Association, 
 ]\Iay, 1916), sets forth some significant data as to the prevalence, in 
 parts of the LTnited States at least, of chicken cestode infection. Dining 
 1912-13 he examined sixty-eight birds collected mostly from Nebraska 
 and Illinois. From this material he obtained 1,561 tapeworms, specif- 
 ically distributed as follows: Davainea tetragona, 598; D. cesticillus, 582; 
 ChoanoUenia infundibuliformis, 17Q; Hymenolepsis carioca, 154; Davainea 
 echinobothrida, 51 . The worms were present in numbers per host varv-ing 
 from 1-35. (The author is informed by Dr. Guberlet that he has since 
 found as many as 115 in a single animal.) Most of the birds examined 
 ranged in age from fouf to six months. 
 
 Symptoms. — As a rule it is only in moderate to heavy infection that 
 tapeworms bring about morbid conditions in fowl. In any case the 
 symptoms are not well defined. They may vary in different individuals 
 having an equal degree of infestation, age especially having an influence, 
 young birds being much more affected than adults and exhibiting the 
 sATiiptoms more definitely. The following are among the more usual: 
 
192 PARASITES OF THE DOMESTIC ANIMALS 
 
 There is an abnormal desire for food, in spite of which the heavih' 
 infested chickens emaciate and become anaemic, as manifested by pale- 
 ness of the comb and wattles. The feathers become erect, ruffled, and 
 dull, and the birds have a tendency to isolate themselves, often in 
 drooping attitudes, or the constantly hungry creatures may seem never 
 to be at ease, but are constantly running about, this probably accounting 
 in part for the loss of flesh. In such aggravated cases there is often ad- 
 vanced emaciation, and, completely exhausted, the bird may die. 
 
 Diagnosis. — A reliable diagnosis can onl}^ be made by finding the 
 segments in the feces, or by killing and examining one or two of the 
 birds showing suspicious symptoms. When the latter method is adopted 
 the intestine should be removed and slit open under water. After 
 gentle stirring to remove the contents, it may be transferred to a basin 
 of clean water, when the worms, if present, will usually be seen attached 
 to the mucosa. 
 
 Control. — As in other forms of helminthiasis, control measures are 
 most effectually applied to the parasites in their stage of larval develop- 
 ment. Until more is known of the life histories of the chicken tapeworms 
 little can be done in the way of prevention other than that based by 
 analogy upon what has already been demonstrated. It is scarceh' 
 practical to keep poultry from eating such possible intermediate hosts 
 as worms and insects. Means may be taken, however, to restrict their 
 access to flies, snails, and the lower crustaceans of stagnant water, 
 though such precaution cannot well be applied to birds running at large. 
 A more feasible accessory measure is the prevention of the larvae from 
 reaching the intermediate hosts by isolating the infected birds in screened 
 quarters where their droppings may be collected and made sterile by 
 burning or other means. 
 
 Treatment. — Vermifuges may be administered in the form of pills 
 made up with bread. Probably the most suitable is areca nut which 
 can be given to adult chickens in doses of from ten to twenty grains 
 according to weight. Young animals may take from three to five 
 grains. After three days the treatment should be repeated. Other 
 remedies used are male fern, kamala, turpentine, and pumpkin seeds, 
 the dosage being proportionate to weight. 
 
 Such a method of treatment has a disadvantage in that each bird 
 must be treated individually. Where the infection occurs in large 
 flocks the repeated handling of each bird involves such an amount of 
 time and patience as to put it practically out of the question. Again 
 we are indebted to Guberlet for experiments which seem to point the 
 way to a more practical method. Bearing upon this department of his 
 work, his report is here quoted in part. 
 
 "Fifteen birds which showed symptoms of tapeworm infection were 
 placed in a cage which was insect-proof and were given the following 
 
TAPEWORMS OF CHICKENS 193 
 
 treatment : A gallon of a mixture of wheat and oats, to which was added 
 a small tablespoonful of concentrated Ij-e, was cooked slowh' for about 
 two hours and allowed to cool. The birds were fasted for alDout fifteen 
 hours and were then given as much of the mixture as they would eat, 
 with plenty of water. Twelve hours later one of the birds was killed 
 and an examination of the small intestine was made. It was found 
 that nearly all of the worms in the intestine were loose, the scolices being 
 detached from the wall, and were also apparently dead. The rest of 
 the birds were given a second dose twenty-four hours after the first. 
 INIan}' worms had passed with the droppings in from twenty-four to 
 twenty-six hours after the first feeding. ^Nlost of the worms in these 
 droppings were dead, but in all probability the embryos were still alive 
 in the mature proglottids. Twelve hours after the second dose was 
 given another bird was killed and it was found that only a few worms 
 were left and all of these were detached and dead. The intestine was 
 filled with a peculiar gray-colored, slimy substance composed mainly 
 of mucus. ]\Iany entire worms and fragments were passed with the 
 droppings during the period of feeding. The lye acted to some extent 
 as a purgative. 
 
 "The birds were given normal diet again, and in a few daj's they 
 showed no s\nnptoms of infection. Eight days after the second dose had 
 been given two more birds were killed and examinations made. One 
 possessed a small fragment of a tapeworm and the other was entireh^ 
 free. 
 
 "This remedy has been known to many poultry raisers for some time, 
 but they have neglected to use it, mainly on account of the fact that 
 heretofore no definite evidence has ever been presented concerning its 
 actual working possibilities. It may not, and in all probability will not, 
 remove all of the worms, but it does remove most of them so that they 
 are not serious and can be controlled in the flock as a whole." 
 
CHAPTER XVII 
 
 THE TAPEWORM LARV.E 
 
 Certain tapeworms are to be considered as to their pathogenicity 
 from two important points of view. They are not only parasites in their 
 adult state in the intestines of domestic carnivores and man, but, in the 
 larval stage live as somatic parasites in animals used as food by man 
 and it may be in man himself. Depending much upon their numbers 
 and form of cyst, these cause no disturbance to their host, or, through 
 their growth, pressure, and inaccessibility, may constitute a menace to 
 health far more serious than that of the adult worms in the intestines. 
 
 Three forms of cestode larvae are principallj^ concerned in this connec- 
 tion, — cysticercus (Fig. 107), coenurus (Fig. 114), andXechinococcus 
 (Fig. 117). A brief synoptical arrangement of these, including the 
 cysticercoid and plerocercoid, follows: 
 
 I. Larva having a caudal vesicle. Cystic 
 
 A. Larva of large size. Liquid in caudal 
 vesicle abundant. Found in tissues 
 and closed cavities of Herbivora and 
 Omnivora, occasionally in Carnivora. 
 1. Vesicle and head single, i. e., cyst 
 monosomatic and monocephalic. 
 
 Cysticercus 
 {Cysticercus 
 -pisiformis, larva of 
 Tcenia pisiformis) 
 
 2. Vesicles multiple, each having a 
 single head, i. e., polysomatic and 
 monocephalic. 
 
 3. Vesicles multiple, having many 
 heads in each, i. e., polysomatic 
 and polycephalic. 
 
 Multiceps 
 
 (Multiceps multicepSf 
 larva of M. multiceps) 
 
 Echinococcus 
 
 (Echinococcus granu- 
 losus, larva of E, 
 granulosus) 
 
THE TAPEWORM LARV^ 
 
 195 
 
 B. Larva small. Little or no liquid in 
 caudal vesicle. 
 
 1. Larva firm, 
 like process. 
 
 terminating in a tail- 
 
 Cysticercoid 
 
 {Monocercus Davainece 
 tetragonce, larva of 
 Davainea tetragona) 
 
 Cryptocystis 
 
 (Cryptocystis tricho- 
 dedes, larva of Dipy- 
 lidium caninum) 
 
 IL Larva without caudal vesicle. 
 
 A. Larva worm-like. Found in muscles 
 of fish. 
 
 Plerocercoid 
 (Larva of 
 DiphyUobothrium 
 latum) 
 
 Cysticercosis (Measles) 
 
 The presence of cysticerci in the connective tissue of muscles and 
 other parts of the animal organism constitutes the condition commonly 
 known as measles (cysticercosis). The disease is mainly of importance 
 from the viewpoint of food sanitation, in view of the fact that measly 
 beef or pork, imperfectly sterilized by cooking, when consumed by man, 
 is likely to infect him with one or more tapeworms. 
 
 The cysticerci of medical interest are, in their order of frequency: 
 Cysticercus bovis of the ox, the cystic form of Tcenia saginata of man, 
 Cysticercus ceUulosce of the pig (also of the dog, cat, and occasionally 
 man), the C3^stic form of Tcenia solium of man, and Cysticercus tenuicollis 
 of the sheep (occasionally of the ox and pig), the cystic form of Tcenia 
 hydatigena of the dog. 
 
 For the development and structure of the cysticerci the reader is 
 referred to the Life History of the Taendiise (p. 170). 
 
 Measles of the Ox 
 
 Taenia saginata (T. mediocanellata). Fig. 106. Tsniidae (p. 170). — 
 This species, commonly known as the beef tapeworm, of which Cysti- 
 cercus bovis is the larval form, lives exclusively in the intestine of man. 
 The head (Fig. 109, B) is small, pear-shaped, and has four elliptical 
 suckers which are frequently pigmented. There are no hooks, and in 
 place of the rostellum there is a sucker-like depression. The neck is 
 
196 
 
 PARASITES OF THE DOMESTIC ANBIALS 
 
 long and narrower than the head. The segments, which may nmnber 
 from one thousand to one thousand three hundred or more, are at first 
 much wider than long. The complete development of the generative 
 organs occurs at about the six hundredth segment, at which location 
 the segments are about as long as broad. Segments containing the 
 mature embryos reach a length of 15-20 mm. (5/8-3/4 of an inch) and a 
 breadth of 5-7 mm. (1/4 -5/16 of an inch). The distal margin of each 
 segment is somewhat swollen and surrounds the base of the following 
 segment. The genital pores are irregularly alternate and protrude from 
 the margins more and more markedl}' as the segments approach the 
 distal end of the chain. The median trunk of the gravid uterus has 
 twenty to thirtj'-five delicate lateral branches on each side, and these 
 give off shorter secondary branches. 
 
 The length of the entire chain may be from 3 to 12 meters (9-38 feet), 
 or it may reach a much greater length. 
 
 Fig. 106. — Taenia saginata, portions of adult, — natural size (after Boas, by Kirkaldy 
 and Pollard, from Leuckart). 
 
 The eggs (Fig. 110) are more or less globular, the shell frequently 
 carrying one or two filaments. As found in the feces, the eggs often 
 have the outer shell absent. 
 
 Next to a small species — Hymenolepis nana — this is the most common 
 tapeworm of man in the United States, and, in fact, with the exception 
 of Diphyllohothrium latum in a few districts, is the most prevalent 
 species infesting man in other parts of the world. It is not found 
 adult in other animals, and its cysticercus lives almost exclusively in 
 the ox. 
 
 Occurrence of Beef Measles. — That the beef tapeworm and its cj-sts 
 (Cysticercus bovis) are more commonl}^ met with in the United States 
 than the pork tapeworms is probably due to the fact that beef is more 
 often eaten rare in this countrj- than is pork. Beef measles, therefore, 
 is, in its relation to food sanitation, of the greater importance. Estimates 
 made upon cattle slaughtered under Federal inspection indicate that 
 nearly one per cent, of all the cattle slaughtered in the United States 
 
THE TAPEWORM LARV.E 197 
 
 are affected, which, m addition to the exposure of human beings to 
 tapeworm infection, is a matter involving considerable economic loss 
 in the condemnation of beef otherwise of perfectly good food value. 
 
 When it is considered that the gravid segments of the beef tapeworm 
 each contain in the neighborhood of ten thousand eggs, and that eight 
 to ten of these segments are usually passed by the human host each day, 
 it is quite evident that, under certain not unusual conditions, the in- 
 fected person could be responsible for the presence of the cj'sticerci in a 
 large number of cattle. The chances for such transmission will be in 
 relation to the location and habits of the carrier of the tapeworm. If 
 it is his custom to defecate about stables or barnyards, the chance that 
 some of the many thousands of voided embryos will reach their bovine 
 hosts is obviously much increased. Where human excrement is used 
 for soiling without its first having been made non-infective by special 
 treatment, cysticercus infection among cattle and hogs is especially 
 frequent. 
 
 Measles is more often found in young than in aged animals. This is 
 probably explained by the fact that beef animals are usually slaughtered 
 young and are more susceptible to infection during the first two years of 
 their life when the tissues offer less resistance to the migration of the 
 embrj'os. In aged animals the cysts are likely to be in a state of ad- 
 vanced degeneration or entireh' absorbed. 
 
 Location and Appearance. — The cysticerci may be found in any 
 organ, but are more especially to l^e looked for in the interfascicular 
 connective tissue of striated muscle (Fig. 108). Of the nmscles invaded, 
 the first to be mentioned in order of frequenc}^ are those of mastication, 
 chiefly the pterygoids and masseters; following these are the heart — 
 which is probably as frequently infested as the masticatory muscles — 
 the muscles of the neck, intercostals, and muscular portion of the 
 diaphragm. In any case it is unusual to find the cysts numerous through- 
 out the muscle, though cases occur of general invasion involving most 
 of the organs of the body. 
 
 The size and appearance of the cysts vary in relation to their age and 
 stage of development. Experimental infections have shown that in 
 seventeen to twenty-five days they measure 2-4 mm. (3/32-3/16 of an 
 inch) in length and 1.5-3 mm. (1/16-1/8 of an inch) in breadth. They 
 are grayish white in color, the outer connective tissue envelope inclosing 
 a fluid which surrounds the clear vesicle or bladder worm. This is 
 0.5-1.5 mm. (1/32-1/16 of an inch) in diameter, and has at one point a 
 yellowish white spot indicating the location of the invaginated scolex 
 which will evaginate on pressure upon the vesicle. 
 
 Experiments by Hertwig have demonstrated that the cysts become 
 fully developed in eighteen weeks after the occurrence of infestation. 
 At this time he found the entire dimensions of the larger cysts to be 
 
198 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. 107. — Diagram of 
 Cysticercus. 
 
 7 by 4.5 mm. (9/32 by 3/16 of an inch), while those of the bladder were 
 
 6 by 4 mm. (1/4 by 3/16 of an inch). 
 
 Degeneration. — After a period of time, depending somewhat upon 
 
 their location, the cysticerci undergo caseous degeneration followed by 
 
 calcareous infiltration. That these changes may 
 
 set in early has been shown in the experiments 
 
 of Hertwig, who found them four weeks after 
 
 infestation. Commonly the degenerative changes 
 
 do not occur until full development is reached or 
 
 for some time after. The cysticerci most likely 
 
 to undergo early degeneration are those located 
 
 in the heart, while those of the muscles of 
 
 mastication probably survive the longest. If 
 
 they are found degenerated in the latter muscles, 
 
 therefore, it is not likely that cysticerci in other 
 
 parts of the body will be living unless they are from a later infection. 
 The degenerated cysts may be recognized by their yellowish, or some- 
 times greenish color. They may be semisolid or quite gritty; pus may 
 be present as a result of pyogenic or- 
 ganisms gathered by the embryos in 
 their migrations. The caseation, how- 
 ever, may not always involve the para- 
 site. In such cases the scolex is likely 
 to be found just under the cyst wall with 
 its usual characteristics retained, though 
 the caudal bladder is apparently absent. 
 As cysts when dissected away and ex- 
 posed to the air tend to shrink by evapo- 
 ration, their structure is more easily 
 made out if they are kept moistened 
 with a drop or two of water during the 
 examination. 
 
 Vitality. — The cysts of beef measles 
 naturally disintegrate at about three 
 weeks after the death of the host, there- 
 fore meat kept in cold storage for this 
 Fig. 108.— Fragment of beef mus- period will not be likely to Contain living 
 
 cle, showing cysts of Cysticercus larvse. In fresh beef all will be killed 
 
 bovis, — natural size (after Neveu 
 Lemaire, from Railliet). 
 
 by the apphcation of sufficient heat (60- 
 70° C. = 140-156 F.) to cook the meat 
 until its cut surface presents a uniform gray color throughout. Freezing 
 for a number of days will destroy them, but this method has a disad- 
 vantage in that decomposition of the meat follows rapidly, making it 
 necessary that it be quickly used. Based upon experiments by Ran- 
 
THE TAPEWORM LARV.E 
 
 199 
 
 som relative to this method, Federal meat inspection regulations provide 
 that beef carcasses showing a slight degree of infestation may be passed 
 for food if held for six days at a temperature not exceeding 15° F. 
 (-9.44° C), as an alternative to the requirement of retention for twenty- 
 one days. 
 
 Symptoms. — Symptoms in bovine measles are practically nil. There 
 is rarely a history of disturbance from the presence of the cysts, and it is 
 extremely exceptional for the condition to be recognized before the 
 animal is slaughtei-ed. 
 
 Measles of the Pig 
 
 Taenia solium. — Tieniidae (p. 170). This species, to which Cysticercus 
 cellulosce gives rise, also lives in the human intestine and is commonly 
 referred to as the pork or armed tapeworm. It is smaller than T. sag- 
 inata. The head (Fig. 109, A) is glolnilai' and loss than I mm. in diam- 
 
 Fn;. 109. — "Head" of Taenia solium (A), of T. saginata (B), and Diphjl- 
 lobothrium latum (C). (After Boas, by Kirkaldy and Pollard). 
 
 eter; the rostellum is short and provided with a double crown of hooks. 
 The neck is long and slender. The first segments are very short, grad- 
 ually increasing in length and lireadth. At about one meter (39 inches) 
 from the head they are as long as broad and have the generative organs 
 fulh' developed. Toward the distal end of the chain they measure 10- 
 12 mm. (3/8-1/2 an inch) in length and 5-6 mm. (1/4 of an inch) in 
 breadth. The total number of segments is fi-om 800 to 900. The genital 
 pores are more i-egularly alternate than in T. saginata. The median trunk 
 of the gravid uterus has 7 to 12 ti'oe-like lateral branches on each side. 
 
200 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 The entire length of the worm is 2-3 meters (6-9 feet), though it 
 may be longer. 
 
 The eggs (Fig. 110) are oval and provided with a very delicate shell. 
 The shell surrounding the onchosphere is globular and thick. 
 
 This tapeworm is much more rare in the United States than is T. 
 saginata. In general, its distribution may be said to correspond Avith 
 that of the domestic pig, correlated with the custom of eating the flesh 
 of this animal raw or unperfectly cooked. The cysticercus not only 
 infests the pig, but may find lodgment in man himself if the eggs from 
 an adult worm infesting his intestine find their way to his stomach. 
 
 Fig. 110.— Egg of Tsenia 
 saginata, with outer shell and 
 filaments; embryo, with em- 
 bryonal shell, in center. Egg 
 of T. solium (above), show- 
 ing embryo with embryonal 
 shell. 
 
 Fig. 111. — Mature segment of Taenia 
 saginata (left) and T. solium (right) , showing 
 laterally branched uterus. 
 
 For this reason, with the added one that the 
 larvae may become established in the central 
 nervous system or eye, Tcenia solium consti- 
 tutes a much more serious infestation than 
 does T. saginata. 
 
 A simple method for determining to which 
 of these two species the infecting tapeworm 
 belongs consists in clearing up a voided segment, pressing it between 
 two clean slides, and observing the form of the gravid uterus as the 
 specimen is held before a strong light. If the median trunk shows 
 numerous delicate lateral branches on each side (20-35) it indicates 
 that the infection is with Tania saginata. If these branches are less 
 numerous (7-12) and more robust, it may be concluded that the seg- 
 ment belongs to T. solium (Fig. 111). 
 
 If treatment has resulted in the expulsion of the entire worm, an 
 exact differentiation can be made by examination of the head under low 
 power magnification. The pork tapeworm will show the cephalic arma- 
 ture which in the beef tapeworm is absent. 
 
 Occurrence of Pork Measles. — While the larvse of the unarmed 
 tapeworm of man live only in cattle, those of the armed tapeworm may 
 
THE TAPEWORM LARV.E 
 
 201 
 
 develop in almost an}- mannnal to which the}' find access. The hog, 
 however, is the most common host, and, from the point of view of public 
 health, the most important. 
 
 As has been noted, the cysticercus of Tcenia solium (Cysticercus cel- 
 lulosce) is a more dangerous parasite than that of T. saginata, as it may- 
 lodge in organs such as the brain or eye with serious consequences. 
 Man can readily become a victim by auto-infection from his own armed 
 tapeworm, the eggs of which may reach his stomach by way of the 
 pyloris, or in being conveyed to the mouth by unclean fingers. By the 
 latter means, moustache twirlers and nail biters are especially exposed. 
 
 Fortunatel}', the United States is favored by the rarity of the pork 
 tapeworm and consequently its cysts. Pig measles is most prevalent in 
 
 Fig. 112. — Stages in tapeworm larval development: a, six-hooked larva K;"| 
 (hexacanth or onchosphere) of Taenia solium; b, cystic stage of same; c, same p-.^ 
 with head evaginated; d, ciliated larva of Diphyllobothrium latum; e, plero- \J 
 
 cercoid of same — all enlarged (after Boas, by Kirkaldy and Pollard, from 
 Lcuckart). 
 
 districts of foreign countries where Ijad hygienic conditions pi-evail; 
 where pigs are kept near dwellings, and their flesh is eaten raw or im- 
 perfectly cooked, conjoined with the practice of depositing human 
 excrement in the open or spreading it upon the fields as fertihzer. In 
 countries where sanitary control is of a more advanced standard the 
 prevalence of the ])ork tapeworm has been greatly- reduced. 
 
 Location and Appearance. — The muscles most often invaded by the 
 cysts are those of the tongue, neck, and shoulder, then, in order of 
 frequencA', the intercostals, abdominal, psoas, the muscles of the thigh, 
 and those of the posterior vertebral region. Organs less often infested 
 are the liver, kidneys, heart, lungs, brain and eye. 
 
 While the cysts may be scattered and few in number, the}^ are, on 
 the other hand, sometimes present in certain locations in enormous 
 numbers. Kuchenmeister in one case found one hundred and thirtA'- 
 
202 PARASITES OF THE DOMESTIC ANIMALS 
 
 three in a piece of meat weighing seventeen grammes (260 gr.), — propor- 
 tionately eight thousand per kilogramme (2 lbs). 
 
 More delicate and transparent than those of beef measles, the cysts 
 are elliptical in form, 6-15 mm. long by 5-10 mm. broad (1/4-5/8 by 
 7/32-3/8 of an inch). The wall enveloping the vesicle is a thin semi- 
 transparent connective tissue membrane which, in loose connection with 
 the surrounding tissue, when removed, leaves a reddened alveolar pit. 
 Pressure upon the caudal vesicle causes the evagination of the larval 
 head which, on examination by low magnification, is seen to be te- 
 tragonal and to possess, in addition to the four suckers, a double crown 
 of twenty-two to thirty hooks, — characters defining it as the larval 
 head of Tcenia solium. 
 
 At about twenty days from infestation the cyst shows as a delicate 
 vesicle about the size of a pin head, with the rudimentary head indicated 
 by a cloudy point, and as yet without enveloping connective tissue mem- 
 brane. At the age of one hundred and ten days all of the cysts are 
 approximately of equal size; the scolex is developed and lies invaginated 
 into the caudal bladder. When located in organs such as the lungs, 
 liver, and spleen, they often appear as grayish, caseous, calcareous, or 
 purulent nodules somewhat reseml^ling those of tuberculosis. Differen- 
 tiation can be made by careful examination which will reveal the hooks 
 and often the larval heads. 
 
 In some cases a diagnosis can be made while the animal is still living 
 Ijy examination of the inferior surface of the tongue. If cysts are present 
 in that organ, they will be near the base and at the sides of the frsenum, 
 where they may be seen as semi-transparent, round or oval vesicles 
 protiiiding beneath the mucous membrane. 
 
 Degeneration. — Degeneration of the cysts may begin at any stage 
 of their development, though those in the visceral organs are the first to 
 undergo these changes. The process begins Avith the connective tissue 
 envelop and later involves the scolex. The caseous cysts present a 
 gray color, while those which have become calcified are white. In the 
 older degenerated cysts the changes have advanced to transformation 
 into small calcareous bodies without fluid, constituting the "dry 
 measles " as termed by the butcher. In such cases the larvae are un- 
 doubtedly dead. 
 
 Vitality. — The cysticercus of pork measles is slightly more resistant 
 to heat than is that of beef measles. Under post-mortem conditions it 
 survives much longer. Ostertag found living larvge in pork forty-two 
 days after it had been slaughtered. Preservation in cold storage as for 
 beef measles, therefore, will not be efTe.ctual. All cysts will be rendered 
 harmless if the pork is cooked until its cut surface presents a uniformly 
 whitish color. 
 
 Symptoms. — Ordinarily measles of the pig. as in the ox, presents 
 
THE TAPEWORM LARV.E 203 
 
 no recognizable symptoms, and, unless the cysts can be seen beneath 
 the visible mucous membranes, the condition is only observed post- 
 mortem. If the cysticerci become lodged in nerve centers, there may be 
 such manifestations as circling movements, grinding of the teeth, or, 
 possibly, convulsions and opisthotonos; symptoms which can no more 
 than suggest measles as a possible cause. ^ / ^^\/Uf^, ! ' 
 
 Measles of the Sheep 
 
 Tcenia hydatigena, of which Cysticercus tenuicollis of the sheep is the 
 larval form, has been described under Cestodes of the Dog (p. 178). 
 
 Occurrence. — Cysticercus tenuicollis has its development under serous 
 membranes of the sheep principally, but it may also appear in other 
 ruminants and in the pig. Infestation is by food and water bearing 
 ova which have been spread about by dogs harboring the adult worm. 
 
 Experiments have shown that the majority of the embryos reach the 
 peritoneal cavity by way of the liver. Ten days after infestation tor- 
 tuous hemorrhagic trails may be found upon the surface of this organ 
 under the capsule of Glisson. These are produced by the migrations of 
 the parasites, and are in close relation, usually at their extremities, with 
 vesicles 0.5-3.5 mm. in diameter. The head is fully developed about 
 the fortieth day, and the vesicle reaches its full growth at about the 
 seventh month, when it may have a diameter of 1.5-5 cm. (5/8-2 inches), 
 often about the size and form of a pigeon's egg. 
 
 These cysts ("water-balls") may be found in var>'ing numbers, their 
 size and location depending upon the age of the infestation. Their 
 seat, especially in young animals, is usually beneath the serous capsule 
 of the liver, though, particularly in old infestations, large bladders may 
 ])e found in most any part of the peritoneal cavity. 
 
 As it relates to food sanitation, this cysticercus of sheep is of little 
 importance. The location and size of the cysts render them easy of 
 elimination from parts used as human food. 
 
 As a mattei- of control, it is obvious, in reference to the life history of 
 the tapeworm, that offal containing such cysts should be inaccessible 
 to dogs. 
 
 Symptoms. — Sheep measles can rarely be recognized until after the 
 death of the animal. 
 
 Cysticercus ovis. — Muscular cysticercosis in sheep has been shown 
 by investigations within the past few years to be more common than 
 had been suspected. It has been determined by Ransom that the 
 cysticercus is derived from a tapeworm having its adult development in 
 tiie dog, and not to a tapeworm of man as had been supposed. 
 
 The following data in regard to this form of measles are quoted from 
 Hall (Bulletin No. 260, U. S. Dept. of Agriculture): 
 
204 PARASITES OF THE DOMESTIC AXI^LVLS 
 
 "Ransom's investigations showed that under careful inspection the 
 percentage of afTected sheep in this countrj- has amounted to two per 
 cent, or more, and that approximately twenty thousand sheep carcasses 
 were retained in 1912 in abattoirs under Federal inspection on account 
 of sheep measles due to this parasite. 
 
 ''The bladder worm, Cysticercus ovis, in the meat of sheep is oval and 
 ranges in size from about one-third of a centimeter (one-eighth of an 
 inch) to almost a centimeter (three-eighths of an inch) in length. Inside 
 of this bladder there is a single tapeworm head, in which respect, as well 
 as in size, this cysticercus differs from a hydatid or a coenurus. Numer- 
 ous C3'sts, however, may be scattered through the musculature, so that 
 in their numbers there is a compensation, so to speak, for their small 
 size and lack of multiplicity' of heads. Inasmuch as the presence of these 
 cj'sts calls for condemnation of a part or all of the infested carcass, ac- 
 cording to the degree of the infestation, and the number of carcasses 
 amounts to twenty thousand a year, this parasite has considerable 
 economic interest for this countiy, and never more than at the present 
 time when the "high cost of living" is such a vital topic. 
 
 "When one of these cysticerci from mutton is ingested by a dog, the 
 tapeworm head passes undigested to the dog's intestine and develops 
 into a fairh' large tapeworm, comparable to the gid tapeworm. Sim- 
 ilarly, this tapeworm, Toenia ovis, produces eggs which are passed 
 out with the feces of the dog, and which are ingested by sheep as 
 they graze over range or pasture or drink water contaminated by these 
 feces, 
 
 "The parasite has been found in Europe, Africa, and New Zealand. 
 It has been found thus far in seven States in this country. It appears 
 to be particular!}^ prevalent in the AVest, a fact that is possibly related 
 to carelessness on the part of the western sheepmen as regards disposal 
 of carcasses of sheep d^dng on the range." 
 
 Control. — ^Measures of prevention consist in restraining dogs from 
 access to the flesh of affected sheep unless it is rendered non-infective 
 by cooking. Homeless dogs should be destroyed, and others going 
 about where their excrement may contaminate the food and water of 
 sheep should be kept free from tapeworms as a precuation, not only 
 against this, but other tapeworm larvae infesting sheep. 
 
 CcExuRosis, Gid 
 
 Gid, turnsick, or staggers are popular terms applied to a disease of 
 the brain or spinal cord, caused by the presence in these locations of 
 the gid parasite Midticeps multiceps {Ccenwnis cerebralis), the coenurus 
 or larval stage of the tapeworm of the dog Multiceps multiceps, Fig. 113 
 (p. 179). 
 
THE TAPEWOR^I LARA\E 
 
 205 
 
 It is observed most often in sheep, more rarely in cattle, goats, and 
 other ruminants. It has been reported in the horse. 
 
 Occurrence. — Gid is a common disease in Europe where it has l)een 
 known for mam- j-ears. The parasite has been observed in this country 
 at least as early as 1901, though symptoms which were undoubtedly 
 those of gid were authentically reported from our far western fiocks 
 during at least ten years preceding. 
 In 1909 Taylor and Bo^^lton found 
 an outbreak in a flock of sheep about 
 forty miles from Ithaca, New York. 
 Necropsies in these cases revealed 
 the presence of the gid parasites 
 from which, by feeding to dogs, 
 they claim to have raised the adult 
 tapeworm. This is the first authen- 
 tic instance of gid in the Eastern 
 United States, and the first account 
 of it was given by Dr. James Law, 
 of Cornell University, in a paper 
 read before the New York State 
 Veterinar>^ Medical Society' in the 
 same year. 
 
 In view of the large number of 
 sheep and dogs which have been 
 brought to the United States from 
 countries where gid prevails, it is 
 somewhat remarkable that the dis- 
 ease has not been more often ob- 
 served here. It is probable that nu- 
 merous cases have occurred which 
 have passed unrecognized and con- 
 sequently unrecorded, the SAaiiptoms Fig. 113.— Portions of adult gid tape- 
 being ascribed to other causes. It is worm (Multiceps multiceps), — natural size 
 
 (after Ransom, from Railliet, Bull. Xo. ^ 
 Bureau An. Ind., U. S. Dept. of Agr.). 
 
 certain that it now has a foothold in 
 this country, in view of which fact, 
 and the further one that in other countries it is one of the most de- 
 structive parasitic diseases of sheep, veterinarians and sheep raisers 
 should be on the lookout for it and take proper preventive precautions. 
 The Coenurus. — The completely developed coenurus (Figs. 114 and 
 116) consists of a membraneous vesicle which may vary in size from that 
 of a hazelnut to that of a hen's egg. When located on the brain it tends 
 to assume a spherical form; when on the cord, which is more rare, it 
 becomes adaptively elongated. The wall is thin, translucent, and dis- 
 tended by a colorless fluid. On the surface of the vesicle there are little 
 
206 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 white, irregTilarh' grouped spots, each representing an invaginated larval 
 tapeworm head. These vary in degree of development and in nmnber 
 from four hundred to five hundred, and herein lies an essential differ- 
 ence between coenurus and cj-sticercus, the latter containing but one 
 
 Fig. 114. — Diagrammatic section of C'cx'iiuius: a, normal dis- 
 position of scolex; b, c, d, e, diagrammatic representation to show 
 the homology between cysticercus and coenurus (after Ransom, 
 from Railliet, Bull. No. 66, Bureau An. Ind., U. S. Dcpt. Agr.). 
 
 Fig. 115. — Brain of lamb, showing the furrows pro- 
 duced by the migration of the young gid bladderworms, 
 taken at a time immediately following the period of 
 invasion — i. e., from fourteen to thirtj'-eight days after 
 infestation, — natural size (after Ransom, from Leuck- 
 art, Bull. No. 66, Bureau An. Ind., U. S. Dept. Agr.). 
 
 Ik IK) ( id b! iddciworm 
 ■^ho^Mng niimatuic tapeworm 
 heads, — natural size (after 
 Ransom, from Railliet, Bull. 
 No. 66, Bureau An. Ind., U. S. 
 Dept. Agr.). 
 
 head. In some cases the heads may be found evaginated to the surface 
 of the vesicle (Davaine), when the cerebral disturbance by pressure is 
 contributed to by the direct irritation from the booklets. 
 
 Development. — Animals susceptible to gid become infested by eggs 
 of the tapeworm Midticeps multice'ps which is harbored by dogs. The 
 eggs and gravid segments, spread about as they are, will, in the presence 
 
THE TAPEWORM LARV.E 207 
 
 of moisture and favorable temperature, retain their power to infect 
 for several weeks. In dry locations and under the influence of a hot 
 sun the period of their vitality is reduced, probably to a few days at 
 most. Eggs, through the mediation of food and water, reaching the 
 digestive juices of sheep and cattle have their shells dissolved, setting 
 free the contained eml^ryos which, on reaching the intestine, penetrate 
 its walls by means of their booklets. From here it is probable that they 
 are passively carried to other parts of the body by the blood and hnnph 
 currents. With rare exception, only those embryos which reach the 
 brain or spinal cord continue their development. 
 
 The central nervous system is reached by the embryos about the 
 eighth day after the occurrence of infection, upon the arrival at which 
 location they lose their booklets and transform into small cysts. In the 
 course of their burrowings along the surface of the brain they leave 
 small sinuous tracks which may be found three to five weeks after in- 
 fection, often marked by a yellowish purulent material (Fig. 115). At 
 the termination of these furrows the young bladderworms become 
 stationaiy, and their development proceeds. 
 
 In five to six weeks the cysts are about 1 cm. (3/8 of an inch) in diam- 
 eter and the heads have begun to appear, these attaining their full 
 development in ten to thirteen weeks. The cj'sts continue to grow 
 until they have reached a diameter of from 3 to 5 cm. (1 3/16 to 2 inches), 
 during which time new heads are in process of formation (Fig. 116). 
 Heads in various stages of development, therefore, may be found in the 
 same vesicle. 
 
 Tabular Review of Life History of Multiceps Multiceps 
 Adult Tapeworm in intestine of dog. 
 
 Egg. — Expelled from intestines. 
 
 Hexacanth. — Freed from egg in digestive tract when 
 
 I ingested by sheep. 
 
 Acephalocyst — In brain or cord of sheep. 
 
 Coenurus (Polycephalic cyst). — Same. 
 
 Scolex. — Attached to intestinal wall of dog after in- 
 
 I gestion of cyst. 
 
 Adult Tapeworm. — In intestine of dog. 
 
 Post-mortem Appearance. — In chronic cases there are usually one 
 or more cysts, rarely as many as six, though cases are recorded in which 
 
^208 PARASITES OF THE DOMESTIC ANIMALS 
 
 there were more than twice this number. The lesions produced will 
 differ according to the development attained by the parasites at the 
 time of the examination. Primarily the lesions are disseminated, and 
 the small cysts may be found at various places upon the convex surface 
 of the brain, surrounded by a yellowish exudate, granules, and cal- 
 careous particles, while, in the vicinity, there may be a small hem- 
 orrhagic area. In cases which have presented the characteristic symp- 
 toms of turnsickness, or gid properly so-called, but one large vesicle of 
 advanced development is ordinarily found (Fig. 116). Such cysts are 
 usually located upon the surface of the cerebral hemisphere, where, 
 by their pressure, they produce an ansemia and softening of the cortical 
 substance. In old cases with large cysts situated upon the brain's sur- 
 face the constant compression upon the roof of the cranium may, by 
 absorption, bring about thinning of the bone to such a degree that it 
 will yield to even comparatively slight pressure of the fingers. 
 
 Exceptionally, the coenurus may be found free in an excess of fluid 
 in a lateral ventricle, and, again rarely, exploration of the vertebral 
 canal will reveal a cyst in the lumbar or cervical region, or it may be 
 at the medulla oblongata. Such cysts are much elongated, and usually 
 there is but one. At the cyst's location the medullary substance is 
 atrophied and softened. Such muscles as may be secondarily involved 
 show the alterations of atrophy and cachexia. 
 
 Symptoms. — As may be inferred from the foregoing, the symptoms 
 presented in coenurosis will be conditional upon the age of the infection 
 and the size attained b}^ the cysts, and also upon their location, the 
 latter factor furnishing the two forms of the affection, — the cephalic, 
 when located in the brain, and the medullary if in the vertebral canal. 
 
 If the parasites are few in number, there will be no symptoms during 
 the early stages, or the^^ may be slight and unnoticed. If there is a 
 heavy invasion the cerebral disturbances caused by the migrations of the 
 parasites may be manifested as stated below. According to Moller, 
 however, these primary symptoms are not observed in four-fifths of 
 the cases. 
 
 Early in the infestation there is dullness, somnolence, inappetence, 
 and usually a rapid loss of flesh. Visual disturbance is soon noticed, the 
 animal colliding with objects which it is apparently unable to see. 
 Examination of the eyes at this time will show a congestion of the 
 sclera; later there is strabismus with either convergence or divergence, 
 and the pupils may be unequally dilated. There are concomitant 
 troubles of motility, and, as the disease progresses, the animal frequently 
 falls down or may assume a recumbent position for the entire day. 
 If it becomes unable to rise, it is probable that death will soon follow. 
 
 When these early symptoms occur, they generally first appear ten 
 to twenty days after infection and persist for a variable period of two 
 
THE TAPEWORM LARV.E 209 
 
 to ten days. The}- then subside, and, during a following latent period 
 of four to six months, it is only by close observation that anything 
 abnormal about the animal can be detected. The ocular disturbances 
 already referred to then appear; the head is held in a peculiar position, 
 and the animal turns in circles or it ma^' stagger and stumble about, 
 repeatedly falling. The movements are made in an impulsive manner, 
 with feet lifted high, and the turning may be to the right or to the left, 
 usually toward the side on which the brain is compressed. Other move- 
 ments than turning may be exhibited, and, in fact, their character will 
 depend upon the part of the brain affected by the cyst. 
 
 These s^inptoms are not continuous, appearing several times during 
 the day with intervals of comparative repose. In three to six weeks 
 from their onset the animal passes into a state of complete paralysis 
 and dies from exhaustion, or it may be in convulsions. 
 • Such characteristic phenomena of gid are of the final stage, and are 
 due to the pressure of the fully developed coenurus upon the brain and, 
 in part also, to direct irritation from the booklets of the partly evag- 
 inated larval tapeworm heads. It is only at this stage that the turning 
 movements appear, therefore the disease does not truly merit the name 
 of gid or turnsickness until these manifestations are reached. 
 
 In gid of the spinal cord the parasite is usually located in the lumbar 
 region. The chief symptom is a gradually increasing weakness and 
 paralysis of the hind quarters (hydatic paraplegia). The bladder and 
 rectum become involved and the animal becomes progressively weaker 
 and emaciated. Death occurs in general debility and exhaustion after 
 a course of one to three months. 
 
 The s^anptoms of gid in other animals are of the same general char- 
 acter as those in sheep. 
 
 Control. — Reviewing the knowledge possessed as to the etiology of 
 gid, the measures to be followed for its eradication are suggested. 
 Chance infection of dogs by the tapeworm should be removed by burn- 
 ing the heads harboring the cj'sts, or by cooking the affected brains if 
 they are to be fed to these animals. Dogs kept in the vicinity of animals 
 susceptible to gid should be given tseniafuge treatment every three 
 months (p. 186). During the operation of this treatment they should 
 be confined and the expelled worms, fragments, and feces collected and 
 burned or deeply buried. 
 
 Gid is a further contribution to the accumulating reasons why un- 
 cared for and unnecessarj' dogs — numerically limitless in most connnu- 
 nities — should be destroyed. 
 
 Treatment. — On account of the inaccessible location of the parasites, 
 treatment, except by surgical means, is useless. The operative measure 
 consists in trephining the cranial cavity and removing the coenurus, 
 but this can only be advised as practical in the case of animals having 
 
210 PARASITES OF THE DOMESTIC ANIMALS 
 
 an especial value. Cold packs upon the head or continuous irrigation, 
 accompanied by purgatives, have been recommended for the acute 
 stage, but such treatment can be no moi'e than palliative, and is scarcely 
 practical unless under exceptional conditions. 
 
 In general, it is better, from considerations of economy, to slaughter 
 animals upon the first evidence of gid. 
 
 Echinococcosis 
 
 Hydatid Disease. 
 
 Hydatid disease is caused by the presence of Echinococcus granulosus 
 {E. polymorphus, E. multilocularis, etc.) or so-called hydatid, the cystic 
 stage of the tapeworm of the dog, — Echinococcus granulosus (Tcenia 
 echinococcus), elsewhere referred to under the cestodes of that animal 
 (p. 181). It occurs in man and all of the domestic mammals, the hy-" 
 datids usually located in the organs of the abdominal or thoracic cavit}', 
 most often the liver, though not infrequently the lungs, spleen, serous 
 membranes, and other organs, several of which may be affected in the 
 same animal. The disease is as cosmopolitan as dogs and their par- 
 asites, therefore it is of world-wide prevalence. 
 
 The Echinococcus (Fig. 117). — While the echinococcus is the largest 
 of the tapeworm cysts, the dog tapeworm, of which it is the larval form, 
 is but 5 mm. (3/16 of an inch), or thereabouts, in length, and consists 
 of a head and three segments. When uninfluenced by pressure, the 
 echinococcus cyst is more or less spherical in shape and presents a com- 
 plex structure, the parts of which may be set forth for study as follows: 
 
 1. An external cuticular membrane (hydatic membrane). 
 
 2. An internal germinal membrane. 
 
 3. The fluid which distends the vesicle. 
 
 4. The proligerous vesicles, which contain the larval tapeworm heads. 
 
 5. The daughter vesicles. 
 
 Surrounding the whole is a capsule formed from the connective 
 tissue of the organ in which the structure is lodged. 
 
 1. The cuticular membrane limits the echinococcus externally. It 
 is whitish in color, concentrically laminated in structure, and in large 
 vesicles may attain a thickness of 1 mm. 
 
 2. The germinal membrane is much thinner than the cuticular, 
 usually not exceeding 20-25 microns in thickness. On its internal sur- 
 face there appear groups of small papilke, representing the beginning 
 development of the proligerous vesicles. 
 
 3. The hydatic fluid is colorless or yellowish and in reaction is neutral 
 or slightly acid. It may contain a number of substances, mostly de- 
 rived by endosmosis from the blood and lymph of the organ invaded. 
 
 4. The proligerous vesicles appear on the internal surface of the 
 
THE TAPEW0R:M LARV.E 
 
 211 
 
 germinal membrane when the mother vesicle has developed to a suffi- 
 cient size. At first papillary, each has a cavity that gradually enlarges, 
 and the vesicles thus formed have an attachment to the germinal mem- 
 brane by a short pedicle. Within each there develops a variable num- 
 ber — usuallv five to twentv or moi-e — of little oval bodies. These are 
 
 Fig. 117. — Diagram of EchiuDcocus liydatid: cu, thick cuticu- 
 lar monibrane; gr, germinal ni("iiil)raiic; a. b., development of 
 proligerous vesicle; c, development of the heads according to 
 Leuckart; d, development of heads according to Moniez; e, fully 
 developed brood capsule with heads; f, brood capsule has ruptured 
 and the heads hang into the lumen of the hydatid; g, liberated 
 head floating in the hydatid; h, i, k, 1, m, formation of secondary 
 exogenous daughter cyst; n, o, p, formation of endogenous cyst, 
 after Kuhn and Davaine; cj, daughter cyst with one endogenous 
 and one exogenous grand-daughter cyst; r. s., formation of en- 
 dogenous daughter cysts, after Xaunyn and Leuckart; r, at ex- 
 pense of head; s, from brood capsule; t, constricted portion of the 
 mother cyst (copied from Osborn's "Economic Zoology," after 
 R. Blanchard; Bureau An. Ind., U. S. Dept. Agr.) 
 
 the lar\'al tapeworm heads. When completely formed the heads meas- 
 ure slightly more than 0.1 mm. and show the suckers and double crown 
 of hooks. 
 
 5. Daughter or secondary vesicles sunilar in character to the mother 
 vesicle have origin in the hydatic membrane which they distend and 
 finally rupture, faUing into or outside of the mother vesicle. In the 
 first case they are termed endogenous vesicles., in the second exogenous 
 
212 PARASITES OF THE DOMESTIC ANIMALS 
 
 vesicles. The exogenous vesicles are capable of implantation upon 
 organs somewhat remote from the primary vesicle. This occurs more 
 commonly in the pig and ruminants than in man. 
 
 The daughter vesicles may, in the same manner, give off grand- 
 daughter vesicles which, like the parent vesicles, maj^ be endogenous 
 or exogenous. 
 
 All of these vesicles develop proligerous vesicles and consequently 
 the larval tapeworm heads, or they may remain sterile, in which case 
 they are referred to as acejjhalocysts. 
 
 It will be noted from the foregoing that one onchosphere ma}^ develop 
 hundreds of tapeworm heads. 
 
 The echinococcus is usually considered as one species, though there 
 is a form which has received the name of Echinococcus multilocularis 
 {E. alveolaris), thought to be due to a tapeworm -.hffering slightly from 
 E. granulosus. Its main distinguishing character is the size of the 
 vesicles, which does not exceed that of the pea. They have a honey- 
 comb arrangement, and are filled with a gelatinous material, the majority 
 of the cysts remaining sterile. The mass of vesicles may grow to the 
 size of a child's head, and constitutes a verj^ fatal form of echinococcosis. 
 It has been found in the ox and pig, but more frequently in man. 
 
 Development. — Embryos finding their way to the intestine with 
 food or water that has been contaminated Avith egg-containing excrement 
 of dogs are probably carried to the liver by the portal system. Four 
 weeks after infecting pigs, Leuckart found small white nodules about 
 1 mm. in diameter, each with a capsule derived from the hepatic con- 
 nective tissue, and containing within it the globular echinococcus. At 
 about five months the cysts were the size of a hazelnut, and each con- 
 tained a thick-walled whitish-colored vesicle, — the mother vesicle. 
 
 The development of the echinococcus is slow. It may remain simple 
 and its growth be limited to increase in volume and thickening of the 
 cuticular membrane, in which case it may reach a diameter of 15 cm. 
 (6 inches) . Generally its size does not exceed that of an orange, and its 
 growth is attained by the formation of secondary vesicles. Where these 
 pass to the inside of the mother vesicle this becomes dilated in an irreg- 
 ular manner, influenced somewhat by the compression of the adjacent 
 organs of the host (Fig. 117). 
 
 As regards the formation of the daughter vesicles, the process has 
 usualh^ been described as a normal one following the complete develop- 
 ment of the hydatid. Deve, in a paper upon this subject (1917), states 
 that every multivesicular cyst is one which has had its vitahty menaced, 
 and that the endogenous vesicles are the result of a defense reaction. 
 The simple cyst with its brood capsules, according to this authority, 
 represents the normal Iwdatid. 
 
THE TAPEWORM LARV.E 213 
 
 Tabular Review of Life History of Echinococcus Granulosus 
 Adult Tapeworm. — In intestine of clog. 
 
 Egg. — Expelled from intestines. 
 
 I 
 Embryo . — Released from egg in digestive tract after 
 I ingestion by pig, ruminant, or other 
 
 1 mammal. 
 
 Mother Vesicle (Hydatid).— In liver or other organ of 
 I I same. 
 
 Daughter Vessicles 
 
 Scoleces. — ^Attached to intestinal wall of dog 
 i after ingestion of brood capsules con- 
 1 taining larval heads. 
 Adult Tapeworms. — In intestine of dog. 
 
 Regarding the longevity of the hydatids, such information as is pos- 
 sessed is furnished mainly by cases of hydatid disease occurring in man. 
 A case is recorded of the persistence of an echinococcus cj^st in a horse 
 for seven years. Usually when found in lower animals it is in those 
 slaughtered for food, and in most such cases the animals are not old 
 enough for the hj^datids to have reached their full development. It is 
 probably for this reason that the disease is clinically unobserved or is 
 much less serious in these animals than in man where the hydatid devel- 
 opment remains uninterrupted. 
 
 The hmnan evidence seems to indicate that the longevity of the cyst 
 may be only limited by that of its host, for a case is recorded where it 
 had existed for thirty-five years and another where the swelling had 
 gradually spread over the face for fortj^-three years, and when operated 
 upon had attained the size of a child's head. 
 
 Post-mortem Appearance. — Hepatic echinococcosis is accompanied 
 by considerable alteration. When the cyst is large the liver becomes 
 hj^pertrophied and its weight may be increased as much as ten times 
 that of normal. The increase in volume may compress neighboring 
 organs, hindering their function and displacing them. The diaphragm 
 especially is crowded and pressed forward upon the lungs. The surface 
 of the liver has protruding elevations of various size and number, and 
 Glisson's capsule is noticeably thickened, perhaps forming adhesions 
 with contiguous organs. Section of the organ reveals cavities of un- 
 equal size from which the hydatic liquid with contained vesicles flows 
 out. The connective tissue capsules of the cysts will vary in thickness 
 from 3 to 10 mm. (1/16 to 3/8 of an inch). These capsules are structurally 
 
!14 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 somewhat compact, and are generally little adherent to the wall of the 
 hj'-datid. 
 
 Old liA'datids may become considerabty modified or completely 
 destro3'ed. In such cases the walls are much thickened and show 
 degenerative changes. The fluid diminishes and disappears with the 
 contraction of the cavity, the degenerative material in the walls be- 
 comes more dense, there is calcareous infiltration, and, finally, the 
 h3'datid may be transformed into a calcareous mass. 
 
 Symptoms. — The symptoms of hepatic echinococcosis in lower 
 animals are, as a rule, too vague for recognition of the specific affection; 
 
 Fig. 118. — Echinococcus granulosus, with fibrous sac laid )Dacl<, showing 
 with brood capsules (after Leuckart). 
 
 ,-datid 
 
 it usually remains for post-mortem examination to establish the diagno- 
 sis. Pulmonary echinococcosis is generally accompanied by the hepatic 
 form, and may exhibit respiratory disturbances, as accelerated respira- 
 tion and dyspnoea, — sjanptoms which may be contributed to by pressure 
 •of the enlarged liver upon the diaphragm. In the region invaded by tlie 
 hydatid the vesicular murmur is lessened or wanting, while in parts 
 nearby it is increased. Percussion will generally definitely establish 
 its location. 
 
 Hydatid disease rarely progresses to a fatal termination in lower 
 animals. 
 
 Control. — As the tapeworm from which the echinococcus is derived 
 
THE TAPEWORM LAR\ .E 215 
 
 is harbored by the dog, rarely the cat, infection of man and domestic 
 animals is by the dissemination of the eggs of this tapeworm with the 
 excrement of its hosts. It follows that all hydatic viscera in slaughter- 
 ing establishments or elsewhere should at once be destroyed bv burning, 
 thus preventing the larval tapeworm heads from reaching the intestines 
 of dogs and cats. Where the disease has appeared it is a good precau- 
 tionary measure, though often impractical, to administer tceniafuge 
 treatment (p. 186) at repeated intervals to all dogs in the vicinity. 
 During the treatment the animals should be confinetl where their feca! 
 material can be caiefully collected and burned. 
 
CHAPTER XVIII 
 
 PHYLU:\I III. CCELHELISIIXTHES 
 
 The Smooth and Segmented Roundworms 
 
 The Ccelhelniinthes are distinguished from all of the worms thus far 
 considered by the presence of a coelom, or bodj' cavity located between 
 the outer body wall and the intestine. With the exception of the thorn- 
 headed worms, the digestive tract is complete, and there may or may 
 not be a closed blood circulation. Excretory vessels connect the cavity 
 of the bodj^ with the outside. The body muscles are ''epithelial muscle 
 cells" developed from the outer epithelial wall of the coelom. Sub- 
 groups exhibit distinct differences in the character of the coelom. In 
 the Annelida, to Avhich the earthworms belong, it is segmented, the 
 segments (somites) corresponding to the annulations or ringing of the 
 body wall. In the Nemathehninthes, which includes most of the par- 
 asitic species, there is no segmentation of the body cavity or annulation 
 of the body wall. In the Hirudinea, the annulated group which con- 
 tains the leeches, the coelom is but shghtly developed, and usually the 
 annulations outnumber the somites. 
 
 The phylum Coelhelminthes has the two classes named below for 
 discussion in this work, the first containing all of the endoparasitic 
 worms which remain to be considered, while of the second, only the 
 leeches are of direct parasitic interest. 
 
 Class I. Nemathehninthes. — Body without external or internal seg- 
 mentation. 
 
 Class II. Annelida. — Body with" external and internal segmentation. 
 
 Class I. Nemathelminthes 
 
 Coelhelminthes (p. 216). — This group contains the roundworms, or 
 so-called threadworms, though not all are filiform. There are both 
 free and parasitic forms, examples of the former living under stones 
 and in other moist places. The parasitic species are by far the more 
 numerous and important. 
 
 The bod}^ is elongated, and, in being cylindrical, differs from that of 
 the Platyhelminthes which is flat, while the absence of annulations and 
 segmentation distinguishes it from that of the Annelida. 
 
 The class includes two parasitic orders. The first contains the typical 
 
CCELHELMINTHES 
 
 217 
 
 representatives of the class and, with the exception of the thorn-headed 
 worms, all of the species of medical interest. 
 
 Order I. Nematoda. — Alimentary canal present. 
 
 Order II. Acanthocephala. — Thorn-headed. Alimentary canal ab- 
 sent. 
 
 Order I. Nematoda 
 
 Xemathelminthcs (p. 216). — The order Nematoda includes numerous 
 species having a wide distribution as parasites of animals and plants. 
 The outer surface of the 
 body is covered by a 
 tough chitinous cuticle 
 which is secreted b}' an 
 underlying layer corre- 
 sponding to the epithe- 
 lium and derma. The 
 cuticular surface may be 
 plain, striated, or more or 
 less mottled. Transverse 
 section of the body wall 
 shows four thickenings — 
 two median and two 
 lateral — corresponding to 
 the dorsal, ventral, and 
 lateral lines which are 
 cUsposed longitudinally. 
 Within the lateral thick- 
 enings are contained the 
 two excretory vessels 
 which, in the vicinity of 
 the head, unite by a 
 transverse commissure 
 reaching the exterior on 
 the ventral surface. The 
 muscles are a layer of 
 vesicular cells derived 
 
 from the epithelium of the outer coelomic wall. They are divided by 
 the lateral and median lines into four fields, and so project into the 
 coelom as to occupy considerable of its space (Fig. 119). 
 
 The digestive system is simple and complete, beginning with the 
 anterior terminal mouth and ending in an anus which is ventral and 
 close to the caudal extremity of the body, A muscular esophagus suc- 
 ceeds the mouth, soon expanding to form a bulbous sucking organ 
 lined throughout with a cuticular layer. From this point to 
 
 Fig. 119. — Transection of t)ody of Ascaris equi (fe- 
 male), showing cuticular wall, muscle cells and proto- 
 plasmic processes extending into ccclom, transversely 
 cut portions of ovary and uterus, and intestinal canal in 
 center (from microphotograph by Hoedt). 
 
 the 
 
218 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 anus the alimentary canal is usually a uniform tube with little or 
 no flexion. 
 
 The nervous system consists of a nerve ring surrounding the esophagus, 
 and of the nerves given off from this ring passing forward and back, 
 the largest of which are in the dorsal and ventral lines. Along the course 
 of these nerves there are ganglionic cells, but there is no massing to form 
 true ganglia as occurs in the Annelida. 
 
 The sexes are usually separate, hermaphroditic forms occurring 
 among free-living species. In general, the females attain a distinctly 
 
 greater length and thickness of 
 the body than do the males, and 
 in other respects they can easily 
 be distinguished. The males are 
 usually provided with chitinous 
 copulatory organs known as 
 spicules. These are curved, 
 spine-like structures which lie 
 in a sheath close to the anus, 
 and they can be protruded or 
 retracted through the cloacal 
 opening (Fig. 120). They are 
 usually two in number, but 
 there ma}^ be but one. The 
 character of the spicules often 
 serves as a guide in the estab- 
 lishment of relationships of cer- 
 tain groups. Surrounding the 
 spicules there is, in some forms, 
 a membraneous expansion which 
 is referred to as the caudal bursa 
 or pouch. This structure is best 
 developed in the Strongylidse, 
 where its varied characteristics 
 furnish an aid in the recognition 
 of species. The bursa is a clasp- 
 ing organ used in copulation, while- the spicules serve to direct the course 
 of the semen. In the female there is a special genital opening,— the 
 vulva, located on the ventral anterior half of the body, or it may be to- 
 ward the anus, its position varying according to species. The cylindrical 
 body is usually more or less distended with eggs, and frequently the 
 egg-packed uteri can be distinctly seen under low magnification and 
 transmitted light. 
 
 The internal reproductive systems of the male and female are much 
 alike. In both they are long tubular organs, coiled forward and back. 
 
 Fig. 120. — Posterior extremity of male nema- 
 tode; diagrammatic longitudinal section: cl, 
 cloaca; d, intestine; m, retractor muscle of 
 spicule; s, sheath of spicule; w, body-wall (after 
 Boas, by Kirkaldy and Pollard). 
 
C(ELHELMINTHES 219 
 
 and lying loosely in the coelomic cavity. In the nial(> this genital tract 
 is always single, the finer part of the tube constituting the testis, the 
 heavier remaining portion serving as a seminal vesicle and terminating 
 in the duct. The ovaries and uteri are likewise continuous structures, 
 the former being constituted by the finer portions, while the uteri are 
 usually much distended (Fig. 119). In certain forms there is but one 
 genital tube in the female, but in most all there are two which unite 
 close to the external opening to form the vagina. There is no distinct 
 vitellarium as in the flatworms, the ovary assuming the function of this 
 gland. 
 
 The eggs are usually globular or ovoid in shape; as there is copulation, 
 they are fertilized in the uterus. Following this the development may 
 or may not take place while the eggs are retained. 
 
 As to the terms oviparous and ovoviviparous. frequentl}' used in 
 summarizing the characteristics of parasitic groups, it may be well to 
 direct attention here to their correct application. 
 
 The term oviparous is properly applied to the oviposition of eggs 
 which undergo incubation after they have been oviposited, or to the 
 oviposition of eggs which have been incubated within the genital cavity 
 of the female and at the time they are oviposited contain enil)ryos more 
 or less developed. 
 
 The word ovoviviparous is commonly used hi reference to the oviposi- 
 tion of eggs containing embryos developed and ready to emerge at the 
 time the eggs are extruded, as might be in the last-stated case. It is 
 more correctly applied where the embryos, having been developed, 
 escape from the eggs while these are still within the body of the female. 
 
 In other words, the escape of the embryos from the eggs occurs out- 
 side of the body of the parent in the oviparous method, within the parent 
 body in the ovoviviparous. 
 
 The term viviparous, often applied in biology for ovoviviparous, 
 has reference to the typical mammalian method of giving birth, where 
 the egg is not concerned in this process, and there is consequently no 
 hatching. 
 
 Parasitism of the Nematodes in General . 
 
 In most of the nematode parasites there is a post-embryonic free 
 existence, the infection of the host being direct and necessary to the 
 parasite's sexual maturity. A notable exception is furnished by Trich- 
 inella, where there is no period of free life, the transfer from host to 
 host being accomplished by the ingestion of food containing the encysted 
 larvae. 
 
 The degree of injury to their hosts by the nematodes varies consider- 
 ably and is frequently not characteristic. In general, it may be said 
 to depend upon the number of the parasites present, but the seriousness 
 
220 PARASITES OF THE DOMESTIC ANIMALS 
 
 of their effect does not depend upon this wholly. A relatively light 
 invasion with forms which elaborate toxins possessing a high degree of 
 toxicity may have a more deleterious influence upon the health of the 
 animal than a heavier infestation with worms from which the elimina- 
 tions are less toxic. Again independent of numbers, adult worms or 
 their larvae can, by their migrations, set up in their unusual locations 
 serious inflammatory and degenerative changes which may be of an 
 infective character due to the bacteria which they transport. 
 
 Intestinal worms which attach to the mucosa are far more capable 
 of producing serious effects than those which live free in the intestinal 
 contents. The former live upon the tissues of their host and cause at 
 their attachment a wound through which infection may readily enter, 
 while the latter obtain their nourishment from the partly digested 
 alimentary material and do not directly lacerate the mucosa. 
 
 Location is a main pathogenic factor. This may be accidental by 
 active or passive migration, as in the case of adult or larval filarise, 
 which seem capable of wandering to most any part of the body, or it 
 may be specific, certain nematodes normally infesting only the intestines, 
 others the respiratory tract, while some occupy the blood vascular 
 system in their larval state or both as larvae and adults. Again, Trich- 
 inella spiralis causes its most serious disturbance during the migration 
 of the embryos through the musculature of its host. In general, it may 
 be said that nematode invasion of the intestines is less serious than that 
 of the respiratory tract. The injurious effects from verminous parasitism 
 of the blood are usually due to injury to the vascular walls, or, if the 
 worms are numerous and massed, to interference with the blood flow. 
 Following upon this there may be the production of a thrombus and 
 formation of emboli with the subsequent development of aneurism. 
 AVhile parasites in the blood in any case constitute a serious infection, 
 the greater number of specific conditions due to such parasitism are 
 caused by blood-invading Protozoa. 
 
 The specific limitations as to host of the parasitic worms is probably 
 much influenced by the character of the nutriment with which they are 
 supplied in each particular case. Certain hosts having no more than a 
 class relationship may harbor intestinal worms of the same species, but 
 are more likely to do so if there is a measure of similarity in the char- 
 acter of the hosts' alimentation. This is exemplified in the distinctly 
 omnivorous animals, man and the pig, each furnishing hostage for the 
 intestinal worms Ascaris lumbricoides (A. suis) and Gigantorhynchus 
 hirudinaceus, while, again, the carnivorous dog and cat both harbor 
 Belascaris marginata and Anktjlostoma canina. 
 
 Opportunity is also a factor. Animals of similar diet are alike exposed 
 to infection by food specific for or most likely to be contaminated with 
 larvae or eggs of certain species of parasites. Such parasitism as the 
 
CCELHELMINTHES 221 
 
 invasion of the intestines of man by the thorn-headed worm of the pig 
 {Gigantorliynchus hirudinaceus) is regarded as straj" or accidental, ])iit 
 if the grub of the May beetle, the larval host of this worm, constituted 
 a choice morsel of diet for man as it does for the pig, it is probable that 
 the thorn-headed worm would much more frequently inhabit man's 
 intestines. 
 
 Adaptive modifications from a free to a parasitic life, and adaptations 
 of the parasite to differing host environments, or to new locations taken 
 up in the body of the same host, are best exemplified in the Protozoa. 
 In the more complexly organized wo^ns the faculty of adaptation is 
 possessed in less degree; though undoubtedl}- the parasitic forms have 
 without exception passed through at least the first of the gradations 
 mentioned. The adult nematodes infesting the respiratory tract, as 
 Didyocaulus filaria of sheep, and those infesting the blood vascular 
 system, as Dirofilaria immitis of the dog, have probabl.y reached these 
 regions from a priniar}' parasitism in a less obscure part of the body, 
 the adaptivitj' having become sufficiently fixed that the conditions 
 supplied by the location later acquired are now specifically essential 
 to their sexual development and reproduction. 
 
 Treatment in General. — Treatment in nematode helminthiasis has 
 in view primarily the expulsion of the worms, and secondarih' the 
 building up of the general health of the animal. Anthelmintics act by 
 destroying or in some way so affecting the worms that they are easily 
 expelled from the body. An agent capable of killing the parasites may 
 have a like effect upon the host if used without due precaution; in any 
 event it is likel}- to be too drastic and cause an acute disturl)ance more 
 serious than the subacute one which it is sought to remedy. In the 
 case of intestinal worms, remedies which reduce them to a sufficiently 
 passive state that they may be readily swept out by the action of a 
 purgative are to be preferred; and here the effect of the vermifuge 
 upon the host, as compared with that of a true vermicide, is one 
 of degree, and the tolerance of the patient is to be taken into con- 
 sideration. 
 
 Essentially the success of vermifuge treatment will ])e influence 1 by 
 the location of the worms; only those in tubular organs in communica- 
 tion with the outside can be reached by such medication, while its action 
 will be hampered in the case of those which burrow into and attach 
 upon the mucous lining. 
 
 It has been said that it may be taken as an axiom in helminthology 
 that each worm in the body develops from an egg or larva which has 
 entered from without. Worms do not go on multiplying indefinitely 
 with the production of new adult generations in the same host. The 
 degree of the infestation, therefore, depends primarily upon the degree 
 of contamination of food or water taken in by the animal, and secondarily 
 
2^12 PARASITES OF THE DOMESTIC ANIMALS 
 
 upon the susceptibility and favorable hostage offered by the individual 
 to the parasite. 
 
 It follows that preventive measures should be based upon the life 
 history of the species to which such measures are applied. Where 
 this is known and intelligently taken advantage of, the problem of the 
 eradication of the parasites becomes much easier of solution than it 
 otherwise would be. For the same reason, more detailed reference to 
 control is reserved for application to particular cases in the pages to 
 follow. 
 
 The nematode parasites are to be considered under seven families 
 having marked differences as to parasitic habit and also as to degree 
 of injury which they cause in their hosts. These are as follows: 
 
 Family I. Ascaridae. 
 
 Family II. Oxjau'idae. 
 
 Family III. Heterakidse. 
 
 Family IV. Filariidse. 
 
 Family V. Strongjdida?. 
 
 Family VI. Eustrongylidae. 
 
 Family VII. Trichinellidse. 
 
 Classification of Parasites of the Phylum Ccelhelminthes 
 
 Phylum III. Coelhehninthes. P. 216. 
 
 Class A. Nemathelminthes. Smooth-bodied roundworms. P. 216. 
 Order 1. Nematoda. P. 217. 
 Family (a) Ascaridae. P. 229. 
 Genus and Species: 
 
 Ascaris equi. Host, equines. P. 233. 
 Belascaris marginata. Host, dog, cat. P. 237. 
 Toxascaris limbata. Host, dog. P. 238. 
 Ascaris lumbricoides. Hosts, man, hog, sheep. P. 239. 
 A. vitulorum. Host, cattle. P. 241. 
 Family (b) Oxjairidse. Seat worms. P. 235. 
 Genus and Species: 
 
 Oxyuris equi. Host, equines. P. 235. 
 Family (c) Heterakid^. P. 242. 
 Genus and Species: 
 
 Heterakis perspicillum. Host, poultry. P. 242. 
 H. vesicularis. Host, poultry. P. 242. 
 Family (d) Filariidge. P. 244. 
 Genus and Species: 
 
 Set aria labiato-papillosa. Host, equines. P. 244. 
 Habronema megastoma. Host, equines. P. 245. 
 H. microstoma. Host, equines. P. 246. 
 
CCELHELMIXTHES 223 
 
 Gon^ylonema scutata. Hosts, sheep, cattle. P. 247. 
 
 Filaria labiato-papillosa. Hosts, cattle, deer. P. 248. 
 
 Dirofilaria iinmitis. Host, dog. P. 248. 
 
 Spiroptera sangiiinolenta. Host, dog. P. 250. 
 
 Ardiienna strongylina. Host, hog. P. 251. 
 
 Physocephahis sexalatiis. Host, hog. P. 252. 
 
 Dispharagus spiralis. Host, poiiltiy. P. 254. 
 
 D. hamulosiis. Host, poultry. P. 254. 
 
 D. nasiitus. Host, poultiy. P. 254. 
 
 Tetrameres fissispina. Host, poultry. P. 254. 
 Family (e) Strongylida. P. 255. 
 Genus and Species: 
 
 Stephanurus dentatus. Host, hog. P. 295. 
 Subfamily (a) Metastrongylins AVoi-ms of the respiratory tract. 
 P. 256. 
 Genus and Species: 
 
 Dictj'ocaulus filaria. Hosts, sheep, goat. P. 256. 
 
 Synthetocaulus rufescens. Hosts, sheep, goat. P. 257. 
 
 S. capillaris. Hosts, sheep, goat. P. 258. 
 
 Dictyocaulus yiviparous. Host, cattle. P. 259. 
 
 jMetastrongylus apri. Host, pig. P. 260. 
 
 M. breyiyaginatus. Host, pig. P. 260. 
 
 Dictyocaulus arnfieldi. Host, equines. P. 261. 
 
 Htemostrongylus yasorum. Host, dog. P. 261. 
 
 Synthetocaulus abstrusus. Host, cat. ?. 262. 
 Subfamily (6) Trichostrongylina. Woi-ms of the stomach and 
 intestine. P. 268. 
 Genus and Species: 
 
 Hiemonchus contortus. Hosts, sheep, goat, cattle. P. 268. 
 
 Cooperia cui'ticei. Hosts, sheep, goat. P. 268. 
 
 Ostertagia nuu-shalli. Host, sheep. P. 269. 
 
 Trichostrongylus Lnstabilis. Hosts, sheep, goat. P. 271. 
 
 Ostertagia ostertagi. Host, cattle. P. 272. 
 
 Nematodirus filicollis. Hosts, cattle, sheep, goat. P. 273. 
 
 Cooperia oncoi;)hora. Hosts, cattle, sheep. P. 275. 
 Subfamily (c) Strongylinae. Worms of the large and small in- 
 testines. P. 280. 
 Genus and Species : 
 
 Q^sophago.stomum columbianum. Hosts, .sheep, goat. P. 
 281. 
 
 O^. yenulosum. Hosts, sheep, goat. P. 282. 
 
 (E. radiatum. Ho.st, cattle. P. 285. 
 
 (E. subulatum. Host, hog. P. 287. 
 
 Chabertia oyina. Host, sheep. P. 287. 
 
224 PARASITES OF THE DOMESTIC ANIMALS 
 
 Strong3'lus equinus. Host, equines. P. 288. 
 St. edentatus. Host, equines. P. 289. 
 St. vulgaris. Host, equines. P. 289. 
 Cylicostomuni tetracanthum. Host, equines. P. 289. 
 Ankvlostoma canina. Hosts, dog, cat. P. 291. 
 Uncinaria stenocephala. Host, dog. P. 292. 
 Bunostomum trigonocephalum. Host, ruminants. P. 293. 
 B. phlebotomum. Host, cattle. P. 293. 
 S3aigamus trachealis. Host, fowl. P. 293. 
 Sj-n. bronchialis. Host, water fowl. P. 293. 
 Family (f) Eustrongylida?. P. 296. 
 Genus and Species : 
 
 Dioctoph\ane renale. Hosts, dog and other animals. P. 296. 
 Family (g) Trichinellidffi. P. 299. 
 Genus and Species: 
 
 Trichuris ovis. Host, ruminants. P. 299. 
 T. crenatus. Host, hog. P. 299. 
 T. depressiusculus. Host, dog. P. 300. 
 Trichinella spiralis. Hosts, hog, rat, mouse, and other 
 mammals. P. 301. 
 Order 2. Acanthocephala. P. 306. 
 
 Family (a) Gigantorhynchidae. P. 306. 
 Genus and Species : 
 
 Gigantorhynchus hirudinaceus. Host, hog, man. P. 306. 
 Class B. Annelida. Annulated worms. P. 307. 
 Order 1. Hirudinea. Leeches. P. 307. 
 Family (a) Gnathobdellidse. P. 308. 
 Genus and Species : 
 Hirudo medicinalis. Medicinal leech. P. 309. 
 Hsemopis sanguisuga. Horse leech. P. 308. 
 
 With slight omissions, the following descriptions of superfamilies 
 and their subdivisions are transcribed from a work upon the nematode 
 parasites of small mammals by Maurice C. Hall (1916). 
 
 ''Esophagus consists of a chitinous tube which is embedded along 
 the greater part of its length in a chain of single cells. The anterior 
 portion of the body, occupied by the esophagus, usually very slender; 
 the posterior portion, occupied by the intestine and reproductive 
 organs, more or less swollen, or at least thicker than the anterior portion. 
 Anus terminal or subterminal. Male with only one spicule or with no 
 spicule. One testis. Female with one ovary. Vulva situated at the 
 junction of the anterior and posterior portion of the body. Oviparous 
 or ovoviviparous. In digestive tract or adnexa or in urinary bladder 
 as adults. Life history usually simple. Larva of at least one intestinal 
 
CCELHELMINTHES 2^25 
 
 form penetrates to and enc>'sts in the musculature of the host of the 
 adult worm. 
 
 Superfamily Trichmelloidea Hall, 19 IG. 
 
 Type-family Trichinellidae Stiles and Crane, 1910. 
 
 "Male without spicule. Female ovoviviparous; the spherical egg is 
 
 suri-ounded with a delicate membrane and is without a true eggshell. 
 
 Worms in the intestine of the host animal. 
 
 Subfamily Trichinelliuie Ransom, 1911. 
 Type-genus Trichinella Railliet, 1895. 
 "Male with one spicule, or, exceptionally, with onlj- a copulatory 
 sheath. Eggs lemon-shaped, the apertures at each end closed with 
 opercular plugs. Development, so far as known, direct and without 
 intermediate host. Egg development often slow. Eggs with thick shell; 
 •do not hatch until swallowed by a suitable host. 
 
 Subfamily Trichurinse, Ransom, 1911. 
 Type-genus Trichuris, Roederer, 17G1. 
 "Mouth connnonly provided with two or three prominent or incon- 
 spicuous lips which are often supplied with papilke, but the mouth 
 may be of variable shape and without lips. When three lips are present 
 one is median and dorsal, the others are submedian and are approximated 
 in the ventral line. Buccal capsule is not present. Males are provided 
 with one or two spicules, rarel}' with none. Female with two ovaries, 
 oviparous, rarely, as in Oxyuris vivipara, viviparous. As a rule develojj- 
 ment is direct and without intermediate host; exceptionall}' (as in 
 ascarids of fish) there is an intermediate host. 
 
 Superfamily Ascaroidea, Railliet and Henry, 1915. 
 "Mouth with three prominent lips supplied with joapillffi, the dorsal 
 lip being median and the two other submedian and approximated in 
 the ventral line, or with three main lips and three relativeh' prominent 
 and inconspicuous intermediate lips (interlabia). Male usually with 
 two spicules. Caudal extremity of female terminates conically and 
 fairly abruptly. 
 
 Type-family Ascaridse, Cobbold, 1864. 
 Type-genus Ascaris, Linnaeus, 1758. 
 "Mouth provided with two or three lips or without lips and of va- 
 riable shape. Esophagus cylindrical or club-shaped, often followed by 
 a distinct bulb. Males with a preanal sucker, which may be limited 
 by a chitinous ring or a delicate cutaneous membrane, or formed by a 
 simple longitudinal depression; this sucker is not present in Seuratum. 
 Two spicules, one or l)oth of which may tend to atrophy or show im- 
 perfect chitinization, and with accessory piece present or absent. 'S'ulva 
 near middle of body. 
 
 Family Heterakidip, Railliet and Henrj', 1914. 
 "Mouth with three well-defined lips; esophageal bulb present or 
 
226 PARASITES OF THE DOMESTIC ANIMALS 
 
 absent; preanal sucker neaiij^ circular and limited by a chitinous ring; 
 spicules equal or unequal. 
 
 Subfamily Heterakinse, Railliet and Henry, 1912. 
 
 Type-genus Heterakis, Dujardin, 1845. 
 
 "Mouth with simple, usually inconspicuous Hps. Male usually with 
 
 one spicule, at times reduced, imperfectly chitinized or absent. Caudal 
 
 extremity of female much elongated and sublobate. Vulva anterior. 
 
 Eggs characteristically flattened on one side. 
 
 Family Ox;ynaridse, Cobbold, 1864. 
 
 Subfamily Oxjiirinse, Hall, 1916. 
 
 Type-genus Ox^auis, Rudolphi, 1803. 
 
 ''Males with a well-developed caudal bursa supported by rays; in 
 
 forms near the outer limit of the superfamily the bursa is occasionally 
 
 verj^ small and the rays atj^pical, or the bursa may be lacking altogether. 
 
 Esophagus without posterior bulb. Mouth naked or with a buccal 
 
 capsule and six papillae, distinct or indistinct. Male usually with two 
 
 spicules and female usually with two ovaries. Oviparous or viviparous. 
 
 Superfamily Strongyloidea, Weinlancl, 1858. 
 
 "Buccal capsule present. Bursa highly developed, with a typical 
 
 system of supporting rays consisting of one or two dorsal raj'S and two 
 
 lateral ray systems of six rays each. Male with two spicules and female 
 
 with two ovaries. Vulva at times anterior to the middle of the body, 
 
 but usually posterior of the middle. Oviparous, eggs segmenting when 
 
 laid. Development, so far as known, direct. Embryo rhabditiform. 
 
 In digestive, rarely in respiratory system. 
 
 Type-family Strongylidae, Cobbold, 1864. 
 
 "Buccal capsule present. In digestive, occasionally in respiratory, 
 
 system. Development direct, at tunes complex, involving cutaneous 
 
 infection, nodular development or other embryonic or larval migration. 
 
 Subfamily Strongylinae, Railliet, 1893. 
 Type-genus Strongylus, Mueller, 1780. 
 "Simple mouth without a buccal capsule. Parasitic only in the di- 
 gestive system. Development direct and simple, involving in all cases 
 known only the possibility of infection by ingestion. 
 
 Family TrichostrongyUda), Railliet, 1915. 
 ' ' Body straight or curved, but not regularly coiled in a spiral . Females 
 with two ovaries. 
 
 Subfamily Trichostrongylinse, Leiper, 1908. 
 Type-genus Trichostrongylus, Looss, 1905. 
 "Buccal capsule present or absent. Bursa present or absent; when 
 present, frequently atypical in structure and number of rays. Ovip- 
 arous, with eggs in variable stages of segmentation when oviposited, 
 or viviparous. Embrj'o not rhabditiform. Usually in respiratory and 
 circulator}' S3^stems, rarely in digestive sj-stem. 
 
COELHELMINTHES 227 
 
 Family ]\Ietastrongylidse, Leiper, 1908. 
 ''Buccal capsule absent. ]Male with two equal spicules and female 
 with two ovaries. Eggs in van-ing stages of development when ovipos- 
 ited. Embiyo not rhabditiform. Parasitic in the respiratory and cir- 
 culator}' systems. 
 
 Subfamih' Metastrongj-linte, Leiper, 1908. 
 T3'pe-genus Metastrongylus, Molin, 1861. 
 "Body usually very long and slender. Mouth with two lips or with- 
 out lips and surrounded with circumoral papilla?. Esophagus slender, 
 without posterior bulb. Anus subterminal. INIale with a single spicule 
 or with two unequal spicules. Tail provided with papillae, usuall}^ 
 curved spirally, and with bursal alse present or absent. Female larger 
 than male. Vulva present, or, less often, absent in gravid females; 
 when present, usually anterior to the middle of the body or near the 
 middle, rarely near posterior extremity. Oviparous, ovoviviparous, 
 or viviparous. Development in many cases, perhaps in all, requires 
 an intermediate host. 
 
 Superfamily Filarioidea, Weinland, 1858. 
 ''Body long and filiform. Alouth without lips. Male with two 
 spicules, usually quite dissimilar. Vulva near the anterior extremity of 
 the body. Adults subcutaneous, in blood, or on serous surfaces. 
 
 Tj^pe-family Filariidse, Claus, 1885. 
 "Vulva anterior, near mouth. Spicules quite dissimilar. Inter- 
 mediate stages, so far as known, occur in blood-sucking arthropoda. 
 
 Subfamily Filariina?, Stiles, 1907, 
 
 Type-genus Filaria, Mueller, 1787, 
 
 "Mouth with two lips; or without lips in forms where vulva is near 
 
 posterior extremit}' of body, Male with posterior extremity of body 
 
 commonly expanded and alate. Female with \'nlva usually in middle 
 
 portion of body, exceptionally near posterior extremit}^ 
 
 Family Spiruridae, (Erly, 1885. 
 Type-genus Spirura, E. Blanchard, 1849. 
 "Bod}' long and filiform. Anterior portion of bod}' ornamented with 
 cuticular bosses. In the median lines, immediately behind the mouth, 
 are two semilunar depressions sinmlating suckers. The vulva is sit- 
 uated a short distance anterior of the anus. 
 
 Subfamily Gongyloneminse, Hall, 1916. 
 Type-genus Gongylonema, Mohn, 1857. 
 "Females with two uteri and with \ailva in the middle portion of 
 the body, not close to anterior or posterior extremities. Pharjmx with- 
 out cuticular rays or spirals. 
 
 Subfamily Spirurinae, Railliet, 1915, 
 
 Type-genus Spirura. E. Blanchard, 1849. 
 
 "INIouth with two lips leading into a pharynx which is strengthened 
 
228 PARASITES OF THE DOMESTIC ANIjVIALS 
 
 by cuticular ridges in the form of rings or spirals. Spicules unequal, 
 the longer several times the length of the shorter. Four pairs of preanal 
 papillae. Eggs containmg embiyos when oviposited. 
 
 Subfamily Arduenninse, Railhet and Henry, 1911. 
 Type-genus Arduenna, Railhet and Henry, 1911. 
 
CHAPTER XIX / 
 
 NEMATODA. FAIMILY I. ASCARID.E 
 
 The Large Rouxdworms of the Intestine 
 
 Xematoda (p. 217). The nematodes of this family have the body- 
 relatively thick (Fig. 125). The mouth is commonly provided with 
 three lips which may be prominent or inconspicuous and often bear 
 papillse. When three lips are present one is dorsal, the other two sub- 
 median, touching on the ventral median hne (Fig. 121). The males 
 are somewhat smaller than the females and usually have the caudal 
 extremity curved ventrally in the form of a hook. There may be one 
 spicule or two. The females have two ovaries and they are oviparous. 
 So far as known, development in all which are parasitic in warm-blooded 
 animals is without intermediate host and infection is direct. 
 
 All of the ascarids live as parasites in the intestines of their hosts, 
 though they may be found in other organs and in the body cavities 
 reached by their migrations. They hve free in the in- 
 testinal contents, obtaining their sustenance by absorp- 
 tion of the partly digested nutriment of their host 
 through their smiple alimentary tube. 
 
 Investigations as to Life History. — Investigations 
 by Capt. F. H. Stewart (F. H. Stewart On the Life 
 Histor}' of Ascaris lumbricoides, British Medical Jour- 
 nal, 1916, Vol. 2, No. 2896) have brought results of 
 great importance bearing upon the hfe histoiy of Ascaris Fig. 121.— Dor- 
 lumhricoides and closely related forms. In these experi- fj ^xtremity^^of 
 ments Stewart found that if rats or mice were fed ascarid, showing 
 Ascaris eggs, the eggs hatched in the alimentaiy tract superior median 
 and the embr3'os migrated to the hver, spleen, and lungs, lateral lips. 
 During these migrations they passed through certain 
 developmental changes, and man}- of them finally again reached the 
 alimentary tract b}^ way of the lungs, trachea, and esophagus. Within 
 the alimentary tract they did not continue their development and were 
 soon expelled with the feces, so that rats and mice surviving the pneu- 
 monia commonh' caused by the invasion of the lungs became free of 
 the parasites as earh' as the sixteenth day after infection. 
 
 From these findings Stewart concluded that in infection with Ascaris 
 lumbricoides it is necessary in the life cycle for the eggs to be swallowed 
 by rats or mice, and that the embryos hatching from the eggs undergo 
 
230 PARASITES OF THE DOMESTIC ANIMALS 
 
 certain migrations and changes of development, after which they may 
 be carried in the feces or saHva of the rats or mice to food or other 
 materials which may be ingested by human beings or pigs, thus ulti- 
 matelj^ reaching their final host. 
 
 This conclusion is contrary to the opinion usually accepted that 
 Ascaris infects man or the pig directly through the ingestion of the eggs 
 of the parasite. In a preliminary note upon the life history of Ascaris 
 lumhricoides and related forms Ransom and Foster, of the Zoological 
 Division of the Bureau of Animal Industry, state that in a repetition 
 of Stewart's experiments in feeding rats and mice with Ascaris eggs 
 they obtained results agreeing very closely with those which he had 
 recorded, also that further investigations have shown that guinea pigs 
 as well as rats and mice may be similarly infected by feeding Ascaris 
 eggs. Their negative or uncertain results from attempts to infect pigs 
 with Ascaris by feeding the eggs agreed with the experience of Stewart 
 and other investigators, nevertheless they did not feel justified in accept- 
 ing these results as evidence against the hypothesis of a direct develop- 
 ment without an intermediate host. They note that Epstein in care- 
 fully controlled experiments with feeding eggs of Ascar'is lumbricoides 
 used very young subjects and that the positive results which he obtained 
 can scarcel}^ be explained upon any other assumption than that a direct 
 development of the parasites occurred following feeding of the eggs. 
 The failures of others to infect adult human beings and the unsuccessful 
 attempts to infect pigs several months old in the same way are considered 
 as suggesting the possibility that age is an important factor influencing 
 the susceptibility of human beings and pigs to infection with Ascaris. 
 In support of this, and in agreement with the migration of larvse which 
 occurs in rats and mice, they cite an instance of a pig about six weeks 
 old which, dying from unknown causes, revealed on examination an 
 Ascaris larva in a fragment of lung and numerous immature ascarids 
 in the intestine, the largest about two inches long. 
 
 In order to test the possibility of infecting very young pigs these 
 investigators used two young pigs from a sow which was found by fecal 
 examination to be free from egg-producing ascarids. At the age of 
 about two weeks one of these pigs was given a large number of Ascaris 
 eggs containing motile-vermiform embryos. One week after feeding 
 the eggs this pig died; the other pig continued in good health. ''Exam- 
 ination of the dead pig," the authors state, "revealed a pneumonia, 
 with numerous petechial hemorrhages in the lung tissue. Numerous 
 ascarid larvse, varying in length from 0.7 to 1.2 mm. in length, were 
 found in the lungs, trachea, and pharynx; none in the liver, spleen, 
 esophagus, small intestine, or large intestine." As to conclusions the 
 authors are further quoted as follows: 
 
 "Stewart's very important discoveries concerning the behavior of 
 
ASCARID.E 231 
 
 Ascaris larvae in rats and mice, the various contributions of other in- 
 vestigators toward the sohition of the problem of the life history of 
 Ascaris lumbricoides and related parasites, and our own experiences, 
 appear to justify certain conclusions, some of which in anticipation of a 
 more extended statement in a future paper, may be briefly given as 
 follows : 
 
 "The development of Ascaris lumbricoides and closely related forms 
 is direct, and no intermediate host is required. 
 
 "The eggs, when swallowed, hatch out in the alimentary tract; 
 the embrj'os, however, do not at once settle down in the intestine, but 
 migrate to various other organs, including the liver, spleen, and lungs. 
 
 "Within a week, in the case of the pig Ascaris, the migrating larvse 
 may be found in the lungs and have meanwhile undergone considerable 
 development and growth. 
 
 "From the lungs the larv£e migrate up the trachea and into the 
 esophagus by wa}' of the pharynx, and this migration up the trachea 
 ma}^ already become established in pigs, as well as in artificiall.y infected 
 rats and mice, as early as a week after infection. 
 
 "Upon reaching the alimentar}^ tract a second time after their passage 
 through the lungs, the larvae, if in a suitable host, presumably settle 
 down in the intestine and complete their development to maturity; 
 if in an unsuitable host, such as rats and mice, they soon pass out of 
 the bod}' in the feces. 
 
 "Heavy invasions of the lungs by the larvae of Ascaris produce a 
 serious pneumonia which is frequently fatal in rats and mice and ap- 
 parenth' caused the death of a young pig one week after it had been 
 fed with numerous Ascarid eggs. 
 
 "It is not improl)able that ascarids are frequently responsible for 
 lung troubles in children, pigs, and other young animals. The fact 
 that the larvae invade the lungs as well as other organs bej'ond the 
 alimentary tract and can cause a serious or even fatal pn^monia in- 
 dicates that these parasites are endowed with greater capacity for harm 
 than has heretofore been supposed. 
 
 "Age is a highly important factor in determining susceptibility to 
 infection with Ascaris, and susceptibiUty to infection greatly decreases 
 as the host animal becomes older. This, of course, is in harmony with 
 the well-known fact that it is particularly children and young pigs 
 among which infestation with Ascaris is common, and that Ascaris is 
 relativel}' of rare occurrence in adult human beings and in old hogs." 
 
 ASCARIASIS 
 
 Ascariasis occurs most frequently in young animals, those matured 
 rarely harboring the worms in such numbers as to bring about symptoms 
 
232 PARASITES OF THE DOMESTIC ANIMALS 
 
 by Avhich the condition can be recognized. Where there is a heavy in- 
 festation they cause injury by their irritation to the intestinal mucosa. 
 In such cases they may become massed and constitute an obstruction 
 to the intestinal lumen sufficient to cause stasis of the contents and de- 
 generative changes in the intestinal walls. 
 
 The ascarids are active worms, and have a tendency to wander to 
 unusual locations; one or two may find lodgment in accessory organs of 
 the intestines b}-- way of their ducts and, by the consequent continuous 
 irritation, bring about results of a serious nature. Verminous fistulae 
 may be thus established, or there iliay be abscess formation with dis- 
 charge of pus into the peritoneal cavity, followed by peritonitis. In 
 dogs and cats especially, the worms when numerous often pass to the 
 stomach in considerable numbers, setting up more or less gastric dis- 
 turbance and consequent vomiting, tha expelled material generally 
 containing from one to several worms. 
 
 Certain foreign investigators, having demonstrated the presence of 
 blood in ascarids, have concluded from this that these worms are blood 
 suckers. Hall, in an article upon the parasites of the dog in Michigan 
 (Journal of the American Veterinary Medical Association, June, 1917), 
 states that an ascarid which he collected from the feces of a dog showed 
 a pronounced red color in the intestine, evidently due to blood. As 
 post-mortem examination of the dog the same day revealed a severe 
 hemorrhagic enteritis, he concludes that this was evidently the explana- 
 tion for the blood in the intestine of the ascarid. The conditions found 
 in this case suggest the possibility of similar conditions in cases regarded 
 as evidence that these worms are blood suckers, — a conclusion that cer- 
 tainly has no support in the structure of the ascarid's mouth. 
 
 There seems reason to doubt that ascarids feed upon epithelial cells, 
 as stated by some authors. Their simple intestinal tube is restrictively 
 modified to the primary function of absorption of nutriment already 
 made in a certain state of solution by the digestive juices of the host, 
 and it is unlikely that such digestive powers as are retained by the 
 parasites would be adapted to a diet of epithelial cells. In view of the 
 fact that free epithelial cells and their debris are contained in the alimen- 
 tary contents of the host, it follows that such material would be in- 
 gested along with the alhnentary matter by the worms and would be 
 found in their intestinal contents. 
 
 Aside from the mechanical injury caused by the ascarids, there are 
 to be considered the effects of toxic products elaborated by their bodies. 
 These may be practically nil or considerable according to the character 
 and degree of the infestation. The loss of condition in heavy invasions 
 can probably be attributed to the systemic effect of these poisons com- 
 bined with that of the catarrhal enteritis. It seems reasonable to con- 
 clude that the deprivation of nutriment, which has been appropriated 
 
ASCARIDiE 233 
 
 by the horde of parasites in the ahmentary canal, is also a morbid factor. 
 ^Manifestations of the toxemia are often of a nervous character; there 
 is hyperrefiex irritability, and con^^.llsions are a not infrequent accom- 
 paniment. 
 
 In general, it may be said of the ascarids that, while the}^ often in- 
 habit the intestines without perceptible indications of their invasion 
 other than their occasional expulsion with the feces, their presence con- 
 stitutes a condition calling for treatment. They should be expelled by 
 the administration of a vermifuge, in most cases followed bj' a purgative, 
 and their bodies collected and burned. Not only should the treatment 
 be carried out for considerations pertaining to the health of the host, 
 but to prevent the spreading about of the worms with their eggs and 
 embrvos to infest other animals. 
 
 Ascarids of the Horse 
 
 One species of ascarid inhabits the intestine of the horse, ass, and mule. 
 
 Ascaris equi (A. megalocephala, A. equorum). Ascaridse (p. 229). — 
 This is the largest species of the family. The bod}' is yellowish white, 
 about the thickness of a lead pencil, and somewhat rigid. The head 
 is distinct and bears three lips. The caudal extremit}- of the male is 
 bordered laterall}' by two small membranous wings, and ventralh' on 
 each side there are 80-100 papilla. The female is considerably longer 
 and thicker than the male. The vulva is situated toward the anterior 
 quarter of the bod}'. 
 
 Length of female: 15-30 cm. (6-12 inches), or it may be somewhat 
 longer. 
 
 Eggs globular, 90-100 microns in diameter. 
 
 The species is found only in Equida?, and lives in the small intestine, 
 occasionally found in oth(>r organs by migration. 
 
 Occurrence and Symptoms. — The large ascarid is verj' common in 
 the small intestine of the horse. Unless numerous, they do not, as a 
 rule, perceptibly affect the health of their host, often the only evidence 
 of their presence being the voiding of one or more of the wornis with 
 the feces. Young annuals do not bear the parasitism so well, and in 
 moderate to hea^y infestations are likely to manifest serious disturb- 
 ances of a local and systemic character. 
 
 As a result of the irritation to the mucosa there is a chronic intestinal 
 catarrh, and this may be accompanied by a diarrhea which is persistent, 
 or alternating with a hard dr}- feces covered with slimy mucous material. 
 Colic is a not infrequent s\nnptom, and there may be intervals of more 
 or less tympany. The worms, when massed in large numbers, are 
 capable of bringing about an obstruction with all that follows such a 
 condition, possibly involving intussusception and even rupture. 
 
234 PARASITES OF THE DOMESTIC ANIMALS 
 
 Young animals, as a result of aggravated ascariasis, lose condition 
 and there is arrest in their development. Due largely to the accumula- 
 tion of gas, they are likel}^ to become more or less pot-bellied, the activity 
 of the skin is reduced, and the coat takes on a dry, harsh, and erect 
 appearance. The alertness and inclination to play, natural to foals and 
 young horses, is lost, and the animals maj' stand about looking more or 
 less dejected. 
 
 Nervous disturbances are occasionally exhibited by vertigo or, 
 rarely, by epileptiform or tetanic symptoms. They may be due to reflex 
 irritation or to toxic products from the bodies of living worms, to which 
 is added toxins from the bodies of worms which are dead and decompos- 
 ing. 
 
 Etiology. — Infection occurs by the introduction of eggs and embryos 
 into the alimentary canal with food and water. Development takes 
 place after the eggs have left the body of the host and is favored by 
 factors of warmth and moisture, such as is suppHed by moist earth and 
 a temperature of about 37° C. (98° F.). AVhile segmentation will not 
 proceed under low temperature conditions, the eggs will retain their 
 fertility in unfavorable surroundings for a comparatively long period 
 and will develop upon reaching a favorable environment. Embryos 
 within the eggs appear to possess considerable resistance, since they 
 have been observed to retain their vitality in dried horse manure for 
 six months. It is probable that infection is by eggs, and that few em- 
 br3^os are released until the intestinal contents of the equine host is 
 reached. 
 
 Control. — Considering the persistent vitality of the eggs and em- 
 bryos, it is especially important as a prophylactic measure that as man}^ 
 as possible of the expelled worms be collected and burned. If they are 
 permitted to find their way to the manure pile or to be scattered about, 
 some of the myriads of eggs contained in their bodies will meet with 
 conditions favorable to their development and infect other horses. 
 Precaution should be taken that the drinking water for horses does not 
 receive contamination from collected manure, and that it be as pure and 
 free from surface drainage as possible. 
 
 Treatment. — Treatment should be preceded by the withholding of 
 all bulk}^ food for twenty-four to fortj'-eight hours. During this time 
 the animal should be at rest and may be given bran mashes, to which a 
 moderate amount of grain may be added during the first twenty-four 
 hours if the preparation is to be for the longer period. 
 
 While the preliminary fasting of the host for a daj^ or two probably 
 will not sufficiently "starve" the parasites to be of any value as an aid 
 in their expulsion, it permits the removal of the bulky portion of the 
 intestinal contents and prepares for a diffuse action of the anthelmintic 
 which otherwise would not be possible. 
 
ASCARID.E 235 
 
 Following the period of fasting, give two to four ounces of oil of tur- 
 pentine and one dram of oleoresin of aspidiuni, in a pint of linseed oil. 
 If necessary, follow twelve hours later with an additional pint or two of 
 linseed oil. 
 
 Tartar emetic in two to three dram doses, repeated once at an interval 
 of twelve hours, is also an effectual cxpellant. This is best administered 
 with linseed meal which may be stii-red into a small bran mash. 
 
 These doses are for aged horses of average size, and are to be modified 
 according to age and somewhat as to weight. 
 
 The vermifuge is in most cases to be followed twelve to twenty-four 
 hours later by a purge, preferabl}' oleaginous, but this should not be 
 given if there is diarrhea, and may not be necessary if the animals are 
 upon grass. 
 
 Sulphate of iron and arsenic are remedies which have also been recom- 
 mended. If arsenic is used, it should be given in the form of powdered 
 arsenous acid in increasing doses for about two weeks. 
 
 Family II. Oxyuridae. Xematoda (p. 217). — This family is consid- 
 ered by many authors as belonging with the Ascaridse. Conspicuous 
 characteristics of the group are the curved anterior portion of the body 
 and the elongated and attenuated caudal extremity of the female. The 
 males usually have but one spicule, and this may be reduced and im- 
 perfectly developed. The vulva of the female is anterior. 
 
 Oxyuris equi (O. curvula, O. mastigodes). Oxyuridse (p. 235). — 
 The body is generalh' white, somewhat thickened, and curved. The 
 mouth is provided with three lips. The male is much smaller than the 
 female, and has an obtuse caudal extremity which bears several papillse, 
 the largest of which sustains a caudal bursa. There is but one spicule 
 and this is straight and slender. In the female the anterior portion of 
 the body is thickened and curved, while the posterior portion is at- 
 tenuated to a point. The \ailva is about 8-10 nun. (3/8 of an inch) from 
 the mouth. The body may have its posterior attenuated portion of 
 variable length (Fig. 122) ; in some individuals this is very much pro- 
 longed and filamentous. This difference has led some authors to 
 describe two species of Ox>in'is of the horse — O. curvula and 0. 7nasti- 
 godes, the latter including those with the extended caudal extremity. 
 Railliet has demonstrated that forms exist possessing all intermediate 
 gradations between those with very short and those with very long tail 
 extremities, and that there is not, therefore, a difference of true specific 
 character. 
 
 Length of female, 4-15 cm. (1 5/8-6 inches) ; male, al^out 1 cm. (3/8 of 
 an inch). 
 
 Eggs oval and operculated; 85-95 microns long, 40-45 microns wide. 
 
 The species inhabits all of the large intestine of the horse, ass, and 
 mule. 
 
236 PARASITES OF THE DOMESTIC ANIMALS 
 
 Occurrence. — Oxyuris equi is a common inhabitant of the large intes- 
 tine of the horse. The condition produced by these worms is usually 
 referred to as oxyuriasis, and they are commonly known as seat-worms 
 or pin-worms. Often they are observed projecting from the margin of 
 the anus to which they adhere while depositing their eggs. By means 
 of a sticky substance the eggs attach about the skin of the anus and 
 perineum and develop embryos within two to three days. | Later the 
 substance by which they are fixed to the skin dries and the eggs drop 
 
 Fig. 122. — Oxyuris equi, showing varj'ing lengths of posterior 
 attenuated portion. 
 
 to the ground where, through scattered manure, they contaminate the 
 pasturage, or, if the animal is in the stable, the feed ma}" be contam- 
 inated in the same manner. 
 
 The eggs are provided at one end with a sort of operculum which, on 
 reaching the stomach, is digested away. The released embrj^os are then 
 carried with the alimentar}" material to the large intestine where they 
 reach maturity. 
 
 Effect. — The offense of the oxyurids is mainly one of unsightliness. 
 The}' produce itching about the anus which may become intense, causing 
 the animal to rub the parts and thus bring about a denudation of the 
 
ASCARID^ 237 
 
 tail and skin. The tail is frequently agitated, and annojdng habits of 
 "switching" and "line-hugging" may have origin from this source. 
 
 In aggravated cases there may be loss of flesh due to the constant 
 irritation to which the animal is subjected. The anus becomes swollen, 
 flacid, and, on defecation, the mucous membrane is noticed to be a deep 
 red. 
 
 The condition is readily diagnosed in observing the protruding or ex- 
 pelled worms. The sticky yellowish-colored deposit about the anus and 
 perineum, together with denudation of the skin and base of the tail 
 by rubbing, indicates the presence of the worms. 
 
 Treatment. — Treatment is mainly per rectum. Previous to the ad- 
 ministration of vermifuge cnemata the bowel should be emptied by an 
 injection of glycerin and water or of warm soap.y water. As an expellant, 
 either of the following may be used: (1) Infusion of quassia, one to two 
 quarts; (2) infusion of tobacco, one ounce to one quart of water; (3) 
 vinegar in soapy water; (4) one quart of a one per cent, solution of 
 lysol; (5) one to two ounces of oil of turpentine shaken up in a quart of 
 Ume water and linseed oil; (6) mercurial ointment repeatedly applied 
 to the borders of the anal orifice is also of service. The injections are 
 best given through a rubber siphon. 
 
 As developing worms from ingested eggs ma}' be in the intestines too 
 far forward to be acted upon by the enemata, it is well to supplement 
 this treatment with the administration of a vermifuge as recommended 
 for the large ascarids of the small intestine. 
 
 Treatment is to be repeated at intervals of four to six days until 
 indications of the presence of the worms have disappeared. 
 
 The adhering deposit about the rectum and perineum should be 
 regularly removed and so disposed of that the contained eggs cannot 
 reinfect. 
 
 AsCARIDiE OF THE DoG AXD CaT 
 
 One species of ascarid is connnon in the dog and cat, although some 
 authors recognize two— Belascaris marginata of the dog, and B. mystax 
 of the cat. Other than being a little smaller, the ascarid of the cat 
 scarcely differs from that of the dog, and at the present time the ma- 
 jority of helminthologists consider the difference as one of variety only. 
 
 A much less conuuon species infesting dogs in this country is Tox- 
 ascaris limhata. 
 
 Belascaris marginata (Ascaris marginata, A. mystax, Belascaris 
 mystax, B. cati). Ascaridee (p. 229).— The body is white, or reddish 
 white. The head is usually curved and is provided on each side with a 
 membranous wing, giving the appearance of an arrow-head (Fig. 123). 
 On the curved tail of the male there are two small membranous 
 lateral wings and twenty-six papillae on each side. The \'ulva of the 
 
238 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 female is situated toward the anterior quarter of the body. The tail 
 is obtuse. 
 
 Length of female, 9-14 cm. (3 1/2-5 1/2 inches); male, 5-10 cm. (2-4 
 inches). 
 
 Eggs globular, 75-80 microns in diameter. 
 
 Infests the small intestine. 
 
 Fig. 123. — Belascaris marginata: A, 
 male; C, female, natural size. 
 
 head, enlarged; B, 
 
 Toxascaris limbata (Toxascaris marginata). Ascaridse (p. 229). — 
 The body is firm and whitish or pale red in color. The cephalic wings 
 are long, narrow, and somewhat lanceolate. The spicules of the male 
 are not quite equal. 
 
 Length of female, 6.5-10 cm. (2 1/2-4 inches) ; male, 4-6 cm. (1 1/2- 
 2 3/8 inches). 
 
 The eggs are 75 to 85 microns in diameter. 
 
 Parasitic in the intestines of the dog. 
 
 Occurrence in the Dog. — Belascaris marginata is most often found 
 in young dogs of three to four months. It is probable that about thirty 
 per cent, of all puppies harbor the worms in more or less numbers in 
 
ASCARID^ 239 
 
 their small intestine. The}' frequently enter the stomach and cause 
 vomiting, the expelled material often containing several worms. Other- 
 wise the S}iiiptoms are much hke those caused by the presence of tape- 
 worms. There is emaciation, enlarged abdomen, and irregular appetite. 
 There may be diarrhea or constipation, and, finall}', epileptiform or 
 rabiform seizures. B^^ massing in the small intestine, they may induce 
 invagination and fatal obstruction to the alimentary matter. 
 
 Necropsies upon dogs which have died from ascariasis reveal the 
 lesions of an intense hemorrhagic enteritis, with tumified mucosa, show- 
 ing small ulcerative points and involvement of the submucous tunics. 
 
 Treatment. — (1) Powdered areca nut, two grains to each pound of 
 bod^'-weight, ma^' be given shaken up in a little milk. (2) Santonin is 
 one of the most frequently used remedies. The dosage should be care- 
 fully graded, giving one-eighth of a grain per pound of body-weight, the 
 dose in no case to exceed three grains. It ma}' be administered sus- 
 pended in milk or combined with one-fourth to two grains of calomel, 
 made into a pill. (3) Fifteen minims to one dram of oleoresin of as- 
 pidium, singly or combined with a grain of areca nut, per pound of body- 
 weight, may be given in capsule. (4) Benzene, in fifteen drop to one 
 dram doses in oil, has been recommended. 
 
 The anthelmintic should be administered in the morning after a 
 twelve hours' fast. If the bowels are not ah'eady freely active, it is 
 well to follow the remedy a few hours later with a purgative of castor 
 oil or syrup of buckthorn. Care should be taken in the administration 
 of these drugs to to}' puppies. Santonin, especially, should not be given 
 until they are at least eight weeks old; under that age, a simple laxative 
 will often bring away quite a number of the worms. 
 
 If vomiting occurs after giving the medicine, allow an interval of 
 two or three days before repeating; then precede by a stomach sedative 
 of bismuth or a small dose of cocaine. 
 
 Occurrence in the Cat. — Ascariasis of the cat does not sufficiently 
 differ from that of the dog to merit a special description. As in the dog, 
 the worms are more likely to infest young animals, though cats seem 
 to bear the invasion better. 
 
 Remedies recommended for the dog will serve as well for the cat, 
 though the peculiar intolerance of these animals should be taken into 
 consideration in the selection and dosage. (1) Cusso, fifteen to thirty 
 grains, is relativel}- safe, but is likeh' to cause vomiting. (2) Oleoresin 
 of aspidium, minims fifteen to twenty, may be given in milk. 
 
 ASCARID.E OF THE HoG AND ShEEP 
 
 Ascaris lumbricoides (A. suis, A. suum, A. ovis). Fig. 125. 
 
 Ascaridse (p. 229). — The head has three strong lips, the lateral sides of 
 
240 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. 124 
 Ascaris lumbricoides, 
 with shell and albu- 
 rn i n o u s envelope 
 (copied from Braun's 
 "Animal Parasites of 
 Man"). 
 
 which are generally 
 denticulate. The body 
 is white, firm, and elas- 
 tic. The males have 
 two spicules and numer- 
 ous papillae anterior and 
 posterior to the anus. 
 The vulva of the female 
 is situated toward the 
 Egg of anterior third of the 
 body. 
 
 Length of female, 20- 
 25 cm. (8-10 inches); 
 male, 15-17 cm. (6-6 3/4 
 inches) . 
 
 Eggs, oval, 60-75 microns long by 40-58 
 microns wide. The shell is mammillated. 
 
 In its adult state this worm lives in the 
 intestines of the hog and sheep, and also of 
 man. 
 
 The ascarid of the hog and sheep and 
 that of man so closely resemble each other 
 that a number of authors now consider 
 them as one species; others distinguish a 
 specific difference, claiming that the ascarid 
 of the pig differs from the human ascarid 
 in being thinner, having the longitudinal 
 strise closer, spicules less sharp, and ova 
 smaller. It would seem, however, that such 
 slight differences should be regarded as of 
 no more than varietal importance. 
 
 Heavy invasions of these worms in the 
 intestines of hogs bring about the con- 
 ditions such as have alread,y been described 
 in aggravated intestinal helminthiasis. In 
 young pigs especially, there is general un- 
 thrift, and emaciation may become quite 
 advanced. There is usually a cough, and 
 this is likely to be accompanied by occa- 
 sional vomiting. The pig shows a pecu- 
 liar restlessness, wandering about without 
 apparent motive and emitting cries indica- 
 tive of colicky pains. The lumen of the 
 intestines may be obstructed by the 
 
 Fig. 125. — - Aseari 
 coides, male at right, 
 left, natural size. 
 
 i luml^ri- 
 female at 
 
ASCARID.E 241 
 
 worms in mass with the usual sequence of localized inflammatory 
 changes. 
 
 Invasion of the Ijile duct of pigs with these ascaiids is of frequent 
 occurrence and may often bring about a fatal result. Autopsies at the 
 Pennsylvania State Laboratories upon pigs dead from this parasitism 
 have in some cases revealed the common bile duct literally packed and 
 occluded with the worms. 
 
 Treatment. — Treatment is mainly proph.vlactic. Thorough clean- 
 ing up, Ixuning of litter, and a liberal application of disinfectants is 
 essential, and the source of water supply and drainage should be looked 
 to. Infested pigs should be isolated and precautions taken against 
 reinfection. 
 
 Medicine is best administered in milk, or other semi-fluid media, fed 
 to the pigs as a whole, the dosing of individual pigs being a somewhat 
 discouraging task. It is better to separate the pigs for this purpose into 
 groups of not more than ten of nearly equal size, otherwise the largest 
 and most aggressive will get more than their portion. 
 
 As a vermifuge, pulverized areca nut may be usetl, the dose being 
 approximately one grain to each pound of body-weight. This should 
 l^e followed by a pui'gative, preferably saline, the dose graded according 
 to size of pigs, and administered as al)ove. Benzene, in one to three 
 dram doses mixed with the food, has been recommended as effective. 
 
 When individual treatment of young pigs is resorted to, one to five 
 grains of calomel, given in milk and followed by castor oil, will in many 
 cases be sufficient to dislodge the worms. For older pigs it is better to 
 follow the calomel with a saline evacuant. 
 
 Ascariasis of Sheep. — Ascarids are rarely found in sheep. In the 
 Bureau of Animal Industiy Collection there are specimens of ascarids 
 obtained from sheep at Blairsville, Pa., Brookings, South Dakota, and 
 Bethesda. Aid. (Bulletin 127. 1911.) 
 
 ASCARID.E OF THE Ox 
 
 Ascaris vitulorum. Ascaridse (p. 229). — The head is small and has 
 three lips which are somewhat enlarged at the base. The body is white 
 or may be reddish white. The caudal extiemity of the male has two 
 rows of papillae, 10-15 in each ; these are lateral and pre-anal. The vulva 
 of the female is situated toward the anterior sixth of the body. 
 
 Length of female, 22-30 cm. (8 1 '2-1 1 3/4 inches) ; male, 15-20 cm. (6- 
 7 3/4 inches). 
 
 Eggs, 75-80 microns in diameter. 
 
 Lives in the intestine of calves; rare in adult cattle. 
 
 This worm is most frequently met with in parts of Southern Europe, 
 where it is found hi rather large mmibers in the small intestine of calves 
 slaughtered for veal. 
 
242 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Heterakiasis of Chickens 
 
 Family III. Heterakidae. Nematoda (p. 217).— This family, like 
 the Oxyuridae, is placed by some authors with the Ascaridse. The 
 t3Te-genus is Heterakis, of which two species infesting chickens are to 
 be described. 
 
 1. Heterakis perspicillum (H. inflexa). Fig. 126. Heterakida 
 (p. 242).— The mouth has three lips of unequal size, the dorsal lip the 
 largest. The body is yellowish white. The caudal extremity of the 
 
 Fig. 126. — Heterakis perspicillum: a, female; b, male; 
 c, Heterakis vesicularis. All natural size. 
 
 male terminates obliquely, and is provided on each side with a mem- 
 branous wing and ten papillae. The two spicules are nearly equal. 
 On the ventral surface anterior to the anus there is a rounded sucker. 
 The caudal extremity of the female is straight, conical, and terminates 
 in a point. The vulva is located in the anterior part of the body. 
 
 Length of female, 6-12 cm. (2 1/2-4 3/8 inches) ; male, 3-8 cm. (1 1/4- 
 31/8 inches). 
 
 Eggs, elliptical, 75-80 microns in length by 45-50 microns in width. 
 
 The species is common in the small intestine of the chicken, turkey, 
 and guinea fowl. 
 
 2. Heterakis vesicularis (H. papillosa). Fig. 126. Heterakidae 
 (p. 242). — The mouth has three small lips of equal size. The body is 
 
ASCARID^ 243 
 
 white and attenuated at its two extremities. The caudal extremity of 
 the male is straight, with lateral wings, and twelve papillae. The spicules 
 are unequal. The caudal extremity of the female is very slender. The 
 vulva is posterior to the middle of the body. 
 
 Length of female, 10-15 mm. (3/8-5/8 of an inch); male, 7-13 nmi. 
 (5/16-1/2 inch). 
 
 Eggs, elliptical, 63-71 microns in length by 38-48 microns in width. 
 
 This species — nmch smaller than the preceding — is also common, 
 and lives in the cecum of the chicken, turkey, guinea fowl, pheasant, 
 pea-fowl, duck, and goose. 
 
 Symptoms. — Heterakiasis of chickens is usually caused by Heter- 
 akis perspicillum. In general, the presence of the worms is indicated 
 by dullness and an indisposition to move about. Though the appetite 
 may be preserved, there is more or less emaciation, the feathers become 
 erect and lusterless, and the wings droop. If the condition is aggravated 
 the symptoms progress, diarrhea sets in, the appetite dwindles, the 
 comb becomes pale, and the creature, with eyes half closed, remains 
 huddled up and unmovable until death comes to its relief. 
 
 In such cases necropsy will reveal the lesions of a subacute enteritis, 
 and frequently the presence of numerous tapeworms as well as round- 
 worms. 
 
 Intestinal helminthiasis in fowls is often an accompaniment to diseases 
 presenting somewhat similar spnptoms, therefore care should be taken 
 that a coincidence does not mislead, and that such causes of high mortal- 
 ity as fowl-cholera be not overlooked. 
 
 Treatment. — Sick birds should be isolated in clean bright quarters 
 and their droppings fvequentl}' removed and destroyed. As medicinal 
 treatment, probably areca nut is most effectual. This may be given to 
 full-grown birds in doses of eighteen to twenty-four grains, administered 
 in bolus made up with Hnseed meal or bread. Calomel, one to two grains, 
 given in the same manner, has also been recommended. 
 
 Essentially, thorough cleaning up and disinfection are necessary to 
 the successful eradication of the parasites. 
 
CHAPTER XX 
 NEMATODA. FAMILY IV. FILARIID^ 
 
 The Thread-like Worms 
 
 Nematoda (p. 217). — The nematodes of this family have the body 
 long and filiform (Figs. 127 and 129). The shape of the mouth varies; 
 it may be provided with lips or it may be surrounded with papillae. 
 The esophagus is slender, without posterior bulb. The males may have 
 one spicule or two unequal spicules, and the tail is generally spirally 
 rolled. The females have two ovaries; vulva usually anterior to the 
 middle of the body. The embryonal development is usualty within the 
 body of the female. 
 
 Parasitism. — The filarise live as parasites chiefly in serous cavities 
 of the body, blood and lymph channels, and in the submucous and sub- 
 cutaneous connective tissues. They may be found in most any part of 
 the body, but do not commonly inhabit the lumen of the alimentary 
 canal. 
 
 The parasitism of the filariae produces a condition in their hosts known 
 as filariasis. 
 
 FiLARIID.E OF THE HORSE 
 
 1. Setaria labiato-papillosa (Filaria equina). Fig. 127. Filariidse 
 (p. 244). — ^The Iwdy is long, white, filiform, and attenuated at both 
 ends. The integument has fine transverse striations. The mouth is 
 small, circular, and provided with a chitinoiis ring, the border of which 
 is divided by four salient papilla?. Outside of this on each side are two 
 small papillae in the form of small spines. The tail of the male is rolled 
 up spirally and presents on each side four preanal and four or five 
 postanal papilla?. There are two spicules. The tail of the female is 
 slightly spiral and is terminated by a papilla. The vulva is situated 
 near the anterior extremity. 
 
 Length of female, 9-12 cm. (3 1/2-4 3/4 inches); male, 6-8 cm. 
 (2 3/8-3 1/8 inches). 
 
 Newly hatched embryos are about 280 microns long by 7 microns in 
 breadth. The embryonic development is within the body of the female. 
 
 Occurrence. — This species is most often met with in the peritoneal 
 cavity — more rarely in the pleural cavity of the horse, ass, and mule. 
 The worms are especially fitted for migrations by their slender and 
 attenuated bodies, and, from their location in serous cavities, may pass 
 
FILARIID.E 
 
 ^245 
 
 to the subperitoneal and subpleural connective tissues or to the mus- 
 cular septa, scrotum, or other parts of the body. The small filarise 
 occasionally found in the anterior chamber of the eye are considered 
 l)y most authors to belong to this species. 
 
 Efifect. — Unless present in exceptionally large numbers, these worms 
 do not produce serious disturbance. Their presence in the eye may 
 cause inflammation with bulging and opacity of the 
 cornea for the relief of which operative measures must 
 be resorted to. 
 
 Nothing definite is known as to the evolution of 
 this nematode; the fact that the embryos have been 
 olDserved in the blood of the horse, points to the 
 probability that they pass to the body of a blood- 
 sucking insect. 
 
 2. Habronema megastoma (Spiroptera megas- 
 toma). Filariidae (p. 244). — This is a small nematode 
 with whitish colored body attenuated at the extremi- 
 ties. The cephalic portion is separated from the 
 remainder of the body by a constriction, and is pro- 
 vided with four chitinous lips. The mouth is con- 
 tinued by an infundibuliform pharynx. The caudal 
 extremity of the male is rolled and bears two lateral 
 wings, each sustained by four preanal and one pos- 
 tanal papillae. There are two spicules. The tail of 
 the female is straight and obtuse; vulva situated to- 
 ward anterior third of the body. 
 
 Length of female, 10-13 mm. (3/8 of an inch); 
 male, 7-10 mm. (1/4- 3/8 of an inch). 
 
 Eggs, elongate, 33 microns long by 8 microns in 
 breadth. Development and hatching are within the 
 body of the female (ovoviviparous). The liberated 
 embr3'os measure 600-700 microns in length. 
 
 The life history is not known. 
 
 This species infests the submucosa of the stomach 
 of the horse. They are usually in the right sac, and 
 their presence may be recognized l)y oval or rounded 
 prominences varying in size from that of a hazel nut 
 to that of a walnut. The mucous membrane covering the tumors is 
 unaltered with the exception of a number of perforations at the summits 
 which communicate with the contained cavities. Within the.se cavities 
 are lodged the worms which, on pressure upon the tumor, are extruded 
 together with a purulent matter. 
 
 It is probable that the worms reach their subnmcous lodgment as 
 embrA^os b}' way of the gastric ciypts, the irritation of their presence 
 
 Fig. 127. — .Setaria 
 labiato-papillosa.male 
 at loft, female at right. 
 
246 PARASITES OF THE DOMESTIC ANIMALS 
 
 setting up proliferative changes with the formation of prominences. 
 Outwardly the tumors are limited by the muscular layers of the stom- 
 ach, the connective tissue involved being that of the submucosa. In 
 old tumors the walls become of a dense fibrous character, taking some- 
 what the consistency of cartilage. In these no worms may be found, or 
 there may be a few of their disintegrated bodies contained in a small 
 amount of purulent material. 
 
 Essentially the presence of such parasites can only be revealed post- 
 mortem. The tumors are not as a rule numerous, and do not seem to 
 cause any serious disturbance. 
 
 The manner of infestation by the worms is not known, nor is it known 
 whether they multiply within the tumors. 
 
 3. Habronema microstoma (Spiroptera microstoma). Filariidse 
 (p. 244). — This species is larger than the preceding and may also be dis- 
 tinguished from it by the absence of the constriction behind the cephalic 
 extremity. The mouth presents a notch on each side, and there are two 
 lateral lips. The tail of the male is rolled spirally, has two lateral wings, 
 and a varying number of papillse. There are two spicules. The vulva 
 of the female is situated near the anterior third of the body. 
 
 Length of female, 12-27 mm. (1/2-1 inch); male, 10-20 mm. (3/8-3/4 
 of an inch). 
 
 The eggs are elongate and truncated at their extremities. They are 
 45-49 microns long by 16 microns wide. Development and hatching 
 are within the body of the female (o vo viviparous) . The hberated em- 
 bryos measure 90-98 microns in length. 
 
 The life history is not known. 
 
 Occurrence. — Post-morten inspection of the interior of the horse's 
 stomach will occasionally reveal the presence of these worms in such 
 quantity as to cause an undulating movement of the contents of the 
 organ, due to their active motion. While most of the worms are free, 
 many may be found with their heads inserted in the gastric crypts of 
 the right sac. More or less inflammatory disturbance of the mucosa 
 may thus be set up, in some cases involving ulceration. 
 
 As in the case of the preceding species, infestation with these worms 
 can only be revealed when they are brought to light after the death of 
 the host. Where a chronic gastric disturbance is suspected to be due 
 to parasites of the stomach, one or two ounces of oil of turpentine may 
 be given in two or three pints of linseed oil. 
 
 FiLARiiD^ OF Sheep and Cattle 
 
 1. Gongylonema scutata (Spiroptera scutata). Fig. 128. Filariidse 
 (p. 244). — The body is long and filiform, white or yellowish white, 
 striated transversely^, and slightly attenuated toward the extremities. 
 
FILARIID.E 
 
 247 
 
 The mouth has two lateral and four smaller submedian papilla. On 
 the anterior 1 to 3 mm. of the body are rounded or oval cuticular tuber- 
 cles arranged more or less regularly in rows. The tail of the male is 
 rolled up and has two asynunetrical wings and two spicules. The \ailva 
 of the female is situated in front of the anus. 
 
 Length of female, 8-14 cm. (3 1/8-5 1/2 inches); male, 3-5 cm. (1 1/4 
 2 inches). 
 
 The eggs are oval. Embrj-onal development is within the body of 
 the female. 
 
 Occurrence.— This is a common species found in a large percentage 
 
 .5 <^l 
 
 
 Fig. 128. — Gongyloncma scutata: a, anterior portion of body, 
 dorsal view; b, posterior extremity of female; c, posterior ex- 
 tremity of male, ventral view; d, same viewed obliquelj^ from 
 left side, — all enlarged (after Ransom, from Neumann, Bull. 
 No. 127, Bureau An. Ind., U. S. Dept. Agr.). 
 
 of sheep and cattle slaughtered in the abattoirs of this country and 
 Europe. It has also been observed in the horse and in the mouth and 
 pharynx of pigs. It inhabits the mucosa of the esophagus, usually in the 
 thoracic portion where it is lodged just l^encath the epithelium. Its body 
 runs parallel to the long axis of the organ and is disposed in a spiral man- 
 ner, givmg somewhat the appearance of the wool-fiber of a merino sheep. 
 There is no apparent effect upon the health of animals harboring this 
 worm. Its only economic importance seems to be in rendering the 
 esophagus undesirable for use in meat food products. 
 
248 PARASITES OF THE DOMESTIC ANIMALS 
 
 Experiments by Ransom and Hall have shown that dung beetles and 
 croton bugs fed upon the eggs of Gongylonema scutata become infested 
 with an encysted larval stage of the parasite. Evidence is thus furnished 
 that the mammalian hosts of the worm become infested as a result of 
 swallowing insects bearing the encysted larvse. 
 
 2. Filaria labiato-papillosa (F. cervina). Filariida^ (p. 244). — This 
 species resembles Setaria labiato-papillosa of the horse, but differs from 
 it in the absence of transverse striations of the integument and in the 
 caudal papilla of the female, which form a terminal cluster of small 
 blunt points, anterior to which are two thick conical papillae. 
 
 Length of female, 6-12 cm. (2 3/8-4 3/4 inches); male, 4-6 cm. 
 (1 1/2-2 3/8 inches). 
 
 Development and hatching is within the body of the female (ovovi- 
 viparous). The freed embryos are 140-230 microns in length. 
 
 This nematode of the ox and deer is found almost exclusively in the 
 peritoneal cavity. It does not appear to have any effect upon the health 
 of its hosts. A worm occasionally found in the eye of the ox is con- 
 sidered as belonging with this species. 
 
 FlLARIID^ OF THE DoG 
 
 1. Dirofilaria immitis (Filaria immitis). Fig. 129. Filariidae 
 (p. 244). — The body is white, long, decidedly thread-like, with ends 
 having an obtuse appearance. The mouth is small and surrounded by 
 six indistinct papilla?. The posterior extremity of the male is slender, 
 rolled spirally, and bears two small lateral wings. There are two 
 spicules. The posterior extremity of the female is obtuse. 
 
 The female is 25 to 30 cm. in length and about 1 mm. in diameter 
 (9 3/4 inches by 1/32 of an inch). The length of the male is 12-18 cm. 
 (4 3/4-7 inches). 
 
 The embryos are developed and hatched in the body of the female 
 (ovoviviparous). As they enter the circulation they measure 285- 
 295 microns in length and have a diameter of about 5 microns. The 
 anterior extremity is obtuse, the posterior extremity attenuated and 
 slender. 
 
 Occurrence. — Hematic filariasis of dogs, produced by this species, 
 has been most frequently met with in China and Japan, about fifty 
 per cent, of all dogs in the latter country, it is estimated, being affected. 
 It occurs also in other countries, including North America. 
 
 The usual seat of invasion is the blood-vascular system, particularly 
 the right ventricle of the heart, the pulmonar}^ arteries being more 
 rarely involved. Not infrequently mature filarrae are found in the sub- 
 cutaneous connective tissue. In the heart and large arteries the worms 
 may be found in a tangled mass containing hundreds so interlaced as to 
 make it difficult to extricate single individuals. 
 
FILARIID.E 
 
 249 
 
 Pathogenesis. — The disturbances caused l)y the presence of the 
 mature filarial are principally mechanical. Dependinjj: upon their 
 number, they more or less interfere with the circulation, in some cases 
 forming- a thrombus which may give rise to emboli in the branches of 
 the pulmonaiy artery. In such cases necrotic 
 areas in the lungs with abscess formation may 
 result. 
 
 The larvae, probably- by their toxic protlucts. 
 bring about anaemia with a leucocytosis which, 
 depending upon the number of the parasites 
 present, may be more or less pronounced. As 
 a result of the invasion of the heart, local mani- 
 festations of endocarditis are to be looked foi-. 
 The heart's action is variouslv disturbed, lead- 
 ing to dropsical conditions accompanied l)y 
 cough and dyspnoea. Nephritis and convul- 
 sions may develop as a later complication. If 
 the condition terminates in death, it is usually- 
 from paralysis of the heart or a general weakness 
 followed by complete paralysis. 
 
 Diagnosis. — The parasites ma}- be present 
 without causing observable manifestations, 
 while, on the other hand, no line of clinical 
 symptoms can with certainty be attril)uted to 
 such invasion. A more precise diagnosis can 
 usually be made by microscopic examination of 
 the blood for demonstration of the jiresence of 
 the larvae. Under low magnification, a drop of 
 infected blood placed between a slide and a 
 coverslip will reveal fine worm-like larvae in 
 snake-like movements between the corpuscles. 
 It is claimed by most investigators that they 
 appear in greatest numbers in the peripheral 
 circulation during the night, and, therefore, that 
 amination is best drawn during these hours. 
 
 Infection. — The manner of natural infection with this parasite has 
 not yet been satisfactorily determined. Manson concluded from his 
 investigations that the larvae of Filaria bancrofti (F. sanguinis hominis) — 
 a blood parasite of man resembling the species under consideration — 
 pass into the digestive tract of a mosquito (Culex) when it sucks the 
 blood of an affected person. Later the mosquito, after depositing its eggs 
 upon the water, dies, the body disintegrates, and the lai-val filariae are lib- 
 erated, man becoming infected by drinking the water thus contaminated. 
 It has been held that Dirofilaria immitis has a similar development. 
 
 Fig. 129. — Dirofilaria im- 
 mitis; male at loft, female at 
 right, — natural size (after 
 Railli.'t). 
 
 blood for such ex- 
 
250 PARASITES OF THE DOMESTIC ANIMALS 
 
 According to Noe, some of the larvae are taken with the infected blood 
 into the bodies of blood-sucking insects. From the intestine they 
 migrate to the Malpighian tubes where they undergo a certain degree of 
 development. In about twelve days from the time they entered the 
 body of the insect they pass through the walls of the Malpighian tubes 
 and enter the mouth parts. If the piercing organ of the insect is broken 
 during the act of sucking blood, the animal becomes infected, and the 
 larvse are carried with the blood or l>anph to the heart where they attain 
 sexual maturity. 
 
 Grassi demonstrated by his investigations that nearly all of the larvse 
 of the filaria of man die in the intestines of mosquitoes, and that the dog 
 filaria cannot live in other parasitic insects harbored by dogs. He con- 
 cluded, therefore, that the larvse from affected animals reach the water 
 directly. 
 
 The prevalence of the disease in low marshy locahties points to the 
 transmission of hematic filariasis through contaminated water. The 
 larvse from affected animals may reach the water with the excrement, the 
 urine, or, occasionally, with blood from wounds. In such case infection 
 may be direct or after the larvse have undergone a further development 
 in an intermediate small crustacean, as cyclops, the parasites gaining 
 entrance to the mammalian host by way of the alimentary canal and 
 from here reaching the blood stream to be carried b}^ the venous blood 
 to the right heart. 
 
 Treatment. — -Therapeutic measures in this form of filariasis, espe- 
 cially where there is pronounced disturbance of nutrition and circula- 
 tion, is unsatisfactory. Nutritious food and the avoidance of exertion, 
 conjoined with the administration of heart stimulants and prevention, 
 so far as possible, of reinfection, may bring results if the parasites are 
 not too numerous or the disturbances occasioned by them are not too 
 far advanced. 
 
 2. Spiroptera sanguinolenta (Filaria sanguinolenta) . Filariidae 
 (p. 244). — ^The most prominent characteristic of this worm is its blood- 
 red color. The tail of the male is obtuse, spiral, and has two lateral 
 wings. There are two spicules. The tail of the female is obtuse and 
 slightly curved. The vulva is situated 2 to 3 mm. behind the mouth. 
 
 Length of female, 6-8 cm. (2 3/8-3 1/8 inches); male, 3-5 cm. (1 1/4- 
 2 inches). 
 
 The eggs are thick-shelled, elliptical, and about 30 microns long by 
 12 microns in width. 
 
 Occurrence and Pathogenesis. — This nematode of the dog is usually 
 found lodged in tumors of the esophagus and stomach, though it is 
 occasionally met with in large blood vessels, the lungs, and in lymph 
 nodes. The tumors varj^ in size from that of a hazel nut to that of a 
 pigeon's egg, and usually but few are present. They lie beneath the 
 
FILARIID.E 251 
 
 mucosa, which is unaltered with the exception of an opening at the 
 tumor's sunnnit. Outwardly, they are limited by the muscular coat. 
 
 Upon incision of the hardened tissue of the tumor it is found to contain 
 cavities which, on pressure, yield a purulent fluid with which are ex- 
 truded the parasites. A varying number of worms may be found coiled 
 up in these chambers, generally from two or three up to twenty. 
 
 Symptoms and Course. — The most characteristic symptom of the 
 presence of this worm is persistent vomiting. A fatal termination may 
 be brought about from inanition resulting from the repeated vomiting, 
 or the gastric tumors may rupture upon the peritoneum and cause a 
 fatal peritonitis. 
 
 Development. — Railliet has demonstrated that the eggs retain their 
 shells in their passage through the intestines of the dog and reach the 
 outside with the excrement. Researches of Grassi have shown that the 
 embryos then pass into the body of a cockroach, probably' by its feeding 
 upon the egg-containing excrement of infected dogs. In the bodj^-cavity 
 of this insect he found large cysts containing larval nematodes agreeing 
 in color with this species. The cysts were fed to dogs which, after two 
 weeks, showed on necropsy the young parasites alread}^ embedded in 
 the mucosa of the esophagus. Natural infection of dogs probably 
 occurs by their eating the roaches containing these cj^sts. 
 
 Treatment. — In the absence of precise symptoms indicating the 
 presence of these worms, the diagnosis in practicalh' all cases being made 
 post-mortem, there is little to be said as to the treatment of the affec- 
 tion. Bismuth or small doses of cocaine may be given as palliative 
 treatment for the relief of the recurrent vomiting, 
 
 FlLARIID^ OF THE HoG 
 
 1. Arduenna strongylina (Spiroptera strongylina). Filariidae (p. 
 244). — The body is subcylindrical and often curved ina semicircle. The 
 anterior portion is attenuated, the posterior somewhat broader. The 
 cuticle is densely striated transversely. The mouth has two lateral 
 lips, each with three lobes leading into a small buccal capsule which is 
 followed by a cylindrical pharynx marked with cuticular ridges forming a 
 series of spirals. The caudal end of the male is curved, has two unequal 
 wings, and five pairs of stalked papillae asymmetrically arranged. The 
 spicules are long and very unequal. The vulva of the female is slightly 
 anterior to the middle of the body. 
 
 Length of female, 16-22 mm. (5/8-7/8 of an inch); male, 10-15 mm. 
 (3/8-5/8 of an inch). 
 
 The eggs are oval, 34-39 microns long by 20 microns wide. They 
 have thick shells and contain well-developed embryos at the time of 
 oviposition. 
 
252 PARASITES OF THE DOMESTIC ANIMALS 
 
 The species is parasitic in the stomach and small intestine of the hog. 
 
 2. Physocephalus sexalatus (Spiroptera sexalata). Filariidie (p. 
 244). — The body is subcylindrical and slightly'- tapering anteriorly. The 
 head is made distinct by a cuticular inflation extending to the posterior 
 end of the pharynx. The mouth has two three-lobed lips, each lobe 
 having a rounded papilla and leading into a small buccal capsule. The 
 cylindrical pharynx has a spiral band which usually breaks up into 
 separate rings in the middle of its course and again becomes spiral toward 
 the posterior end. The body of the male is nearly uniform in diameter. 
 The caudal extremity is twisted spirally and has narrow membranous 
 wings which are symmetrical. There are eight pairs of papillae, of which 
 four pairs are preanal and stalked, the postanal papillae small, with 
 short stalks, and close to the tail. The spicules are very unequal. The 
 body of the female is thickest near the anus, terminating abruptly in a 
 blunt point furnished with a small conical tip. The vulva is posterior to 
 the middle of the body. 
 
 Length of female, 13-19 mm. (1/2-3/4 of an inch). In the region di- 
 rectly anterior to the anus the width is 333-450 microns. The male is 
 6-9 mm. (3/16-11/32 of an inch) in length. 
 
 The eggs are oval, 34 by 15 microns, slightly flattened at the poles, 
 and thick-shelled. They contain well-developed embryos at the time of 
 oviposition. 
 
 The species is parasitic in the stomach and small intestine of the hog. 
 
 In neither of these two species is the life history known. The thickness 
 of the egg-shell indicates that the embryos are not released until this is 
 acted upon by the gastric juice of the host, and, therefore, that develop- 
 ment occurs without an intermediate host. 
 
 In a report upon his investigations of these worms published in 1912, 
 Foster, of the Zoological Division of the Bureau of Animal Industry, 
 gives the following summary: 
 
 "Two species of roundworms belonging to the family Filariidae, of 
 particular interest to helminthologists and veterinarians on account of 
 their wide distribution and frequency of occurrence in American swine 
 and the possibility thai they may cause serious injury to their host, are 
 given special consideration in this paper. 
 
 "One of these species, identified as Spiroptera strongylina, has re- 
 cently been placed in a new genus, Arduenna, of which it is the type, 
 and several errors regarding the anatomy of this parasite have been 
 corrected. Another species, Arduenna dentata, has been found in China 
 associated with Arduenna strongylina, and, although not yet reported in 
 American swine, is mentioned in this connection, as further investiga- 
 tion may reveal its presence in this country. 
 
 "Arduenna strongylina is much more common in American swine than 
 it is said to be in European swine, and has been found abundantly in 
 
FILARIID.E 253 
 
 the slaughterhouses of St. Louis, Chicago, South Omaha, and Kansas 
 City, and has also been collected at Benning, D. C, and Bethesda, Md. 
 
 "Specimens of hogs' stomachs received from Chicago showed the 
 worms deeply fastened in the submucosa or embedded in necrotic tissue 
 near which were deep ulcers. The condition suggested infection with 
 Bacillus necrophorus, the inoculation with which might easily result from 
 the burrowing of the worms; however, owing to the sterile condition of 
 the specimens received, this could not be satisfactorily demonstrated. 
 A similar diseased condition of the stomachs of hogs in Europe is attril)- 
 uted Iw Von Ratz to infection with Arduenna strongylina. Under the 
 circumstances the worm should be regarded with grave suspicion, and 
 general prophylactic measures foi- the prevention of the spread of the 
 infection are suggested. 
 
 "Commonl}^ associated with Arduenna strongylina in this country is 
 another worm, identified as Physocephalus sexalatus, first described by 
 Molin from specimens from the peccary {Dicotyles labiatus) from Brazil; 
 also found by him associated with Arduenna strongylina from the wild 
 boar in Germany. It is also reported by A'on Listow (who apparentl>- 
 mistook this species for Arduenna strongylina) and Plana, from Europe, 
 and by Railliet and Henry from Madagascar and Indo-China, in the 
 former case associated with a severe gastritis. Seurat (1912) has re- 
 cently reported this species from the ass and dromedary in Algeria, but 
 his statements would seem to I'equire confirmation. 
 
 "According to the writers' experience, Physocephalus sexalatus is 
 almost as widely distributed as Arduenna strongylina, since out of eight 
 lots of specimens of the latter species, specimens of Physocephalus sexala- 
 tus were found in all but one. In a mixed infection, however, it has 
 never been found as abundantly as Arduenna strongylina. This worm 
 has apparently the same habit of injuring the mucosa as has Arduenna 
 strongylina, as both species were found in the same necrotic tissue in a 
 hog's stomach. It must therefoi-e be considered only less dangerous 
 because it is less abundant, and should be subject to the same treatment 
 suggested for infestation with Arduenna strongylina.'" 
 
 Control. — As that part of the parasite's life history external to the 
 host is not known, no more than general preventive measures can be 
 recommended. The author quoted above suggests the following: 
 
 "1. Hogs suffering from loss of appetite oi- failing to fatten undei- 
 proper food and hygiene should be examined for evidence of infection b>- 
 killing one or two and looking in the stomach for worms; or, where 
 practicable, the feces of the entire herd may be examined microscopically. 
 
 "2. Those swine found infested with stomach worms should be 
 isolated from noninfected or presumably noninfected swine in clean 
 pens, and the dung removed daily and mixed with quicklime or dis- 
 posed of by carting it to places to which hogs do not have access. 
 
254 PARASITES OF THE DOMESTIC ANIMALS 
 
 "3. The noninfected swine should not be allowed to remain in the 
 same pens formerly occupied by the infested animals, but should have 
 clean quarters. The old pens should be thoroughly disinfected with lune 
 after removing the clung and burning over the ground where feasible." 
 
 Treatment. — Treatment in such infection is mainly prophylactic. 
 As a medicinal remedy, probably benzine is one of the best. It may be 
 given in two to four dram doses in milk, administered as recommended in 
 the treatment for ascarids. Areca nut, one grain per pound of body- 
 weight, may be given in the same manner. 
 
 FiLARiiD^ OF Chickens 
 
 Of the filariae harbored by poultry, four species may be mentioned 
 here. As to the first three at least, there is little of record in this country. 
 
 1. Dispharagus spiralis. Filariidse (p. 244). — The body is generally 
 rolled spirally. There are three papillse around the mouth. The tail 
 of the male is spiral and is provided with wings. There is but one 
 spicule. The female is 9 mm. (3/8 of an inch) and the male is 7 nun. 
 (5/16 of an inch) in length. 
 
 This species lives in the wall of the esophagus and intestines of poultry. 
 
 2. Dispharagus hamulosus. Filariid® (p. 244). — The body has 
 eight denticulated longitudinal wings. The female is 16-25 mm. (5/8- 
 1 inch) and the male is 14 mm. (9/16 of an inch) in length. 
 
 This worm has been found in Brazil and in Italy. It is parasitic in 
 the gizzard of fowls. 
 
 3. Dispharagus nasutus. Filariida? (p. 244).— The body is slightly 
 attenuated at its extremities. There are two long terminal papillse 
 on each side of the mouth, from which two fiexuous wings have their 
 beginning. These pass to a distance of 0.6 mm., then curve forward. 
 The male is filiform, with caudal extremity spiral. There are two 
 unequal spicules. The vulva of the female is in the anterior portion of 
 the body. The female is 5-9 mm. (3/16-3/8 of an inch) and the male 
 is 5 mm. in length. 
 
 It inhabits the gizzard of fowls. 
 
 4. Tetrameres fissispina (Tropisurus fissispinus). Filariidse (p. 244). 
 — This species is characterized by a marked sexual dmiorphism. The 
 male is white, slender, 3-6 mm. (1/8-1/4 of an inch) in length, and bears 
 upon the median and lateral hues spines forming four longitudinal series. 
 The body of the female is subglobular, 2 mm. in length by 1-2 mm. (in 
 width; reddish in color; tail short and conical. 
 
 The species is found in the proventriculus of the domestic duck where 
 it inhabits submucous cysts and may set up a serious inflammation of 
 these parts. It is said to be quite common in parts of New York State, 
 and it is probable that it exists in other localities. 
 
chapter xxi 
 
 xe:\iatoda. fa:mily v. stroxgylid.e. subfa:\iily i. 
 :^ietastroxgylix.e 
 
 AVORMS OF THE RESPIRATORY TrACT 
 
 Xematoda (p. 217). — The most prominent character by which this 
 family may be recognized is the caudal bursa of the male which is usually 
 well developed. The body is elongate, cylindrical, and in some cases 
 filiform. A buccal capsule may be present or absent and ma}' be armed 
 with teeth in its interior. The esophagus is more or less enlarged poste- 
 riorly. The males have a more or less well-developed caudal bursa, 
 usually divided into lateral lobes, each supported by ra^'-like chitinous 
 thickenings. There are two equal or unequal spicules. The \ailva of the 
 female may be posterior or anterior to the middle of the body, usually 
 posterior, in some cases near the anus. 
 
 Parasitism. — While these worms in their adult form mostly infest 
 the lumen of the alimentar}- and respiratory tracts, other organs may be 
 primarily or secondarily- involved. The subserous larval phase of in- 
 testinal invasion b}- the genus (Esophagostomum and the vascular 
 larvae of Strongylus vulgaiis may be mentioned in this connection, while 
 other organs are not uncommonly invaded by migration. The term 
 strongylosis is a general one which has been applied to any helminthiasis 
 produced by strongyles. It is more precisely used when qualified by 
 terms indicating the seat of invasion, as gastric, intestinal, bronchial, 
 vascular, or renal strongylosis. 
 
 Being responsible for some of the most depletive and fatal forms of 
 parasitism, the strongyl worms have especially demanded study and 
 investigation; this has established important advances in knowledge 
 as to their pathogenicity, though much remains to be revealed as to 
 their life histories and consequently as to effectual means for their 
 control. In general it may be said that low marshy pasturage and wet 
 seasons favor infestation with strongyles, which would indicate that the 
 ova and embr^-os of some forms at least are spread by water, and that 
 contaminated water and herbage are the vehicles by which the parasites 
 reach their hosts. 
 
 As in other parasitic invasions, age and physical condition have a 
 decided influence in predisposition to strongylosis. Young ruminating 
 animals are especially susceptible to the broncho-pulmonary form, 
 while in all animals which mav be affected both vouth and senilitv favor 
 
256 PARASITES OF THE DOMESTIC ANIMALS 
 
 intestinal infestation. Again, the general rule applies that resistance is 
 always reduced in animals in low physical condition, while, essentially, 
 crowding and general unsanitary conditions favor the transmission and 
 spread of the parasites. 
 
 Of the Strongylidae three subfamilies may be distinguished, viz: 
 
 Subfamily I. Metastrongylince. 
 
 Subfamily II. Trichostrongylinae. 
 
 Subfamily III. Strongylinae. 
 
 Subfamily I. Metastrongylix^ 
 
 Strongy-lidse (p. 255). — This subgroup comprises the strongyles 
 parasitic in the respiratory system and some in the circulatory system. 
 The buccal capsule is absent or very slightly developed. The bursa of 
 the male is frequently atypical in structure and number of rays. There 
 are two equal spicules. The eggs are in varying stages of development 
 when deposited. 
 
 The life history is as yet unknown. It is probable that infection is 
 without intermediate host. Romanovitch and Slavine (1914) found 
 that eggs of Didyocaulus filaria when placed in water formed embryos. 
 Two moltings followed, the cuticle being retained and encapsulating the 
 larvae, and these when fed to sheep produced infection with the adult 
 worms. This would indicate direct development and infection by the 
 worms of this group. 
 
 Bronchial and Pulmonary Strongylosis of the Sheep and Goat 
 
 Three species of Metastrongylinse invade the respiratory tract of the 
 sheep and goat; a fourth, — Metastrongylus apri — described under 
 broncho-pneumonia of the hog, is exceptionally found in the sheep. 
 
 1. Dictyocaulus filaria (Strongylus filaria). Fig. 130. Meta- 
 strongylina? (p. 256). — The body is white, filiform, slightly tapering at 
 posterior extremity. The anterior extremity is obtuse, without wings; 
 mouth circular and without papillae. The bursa of the male is notched 
 in front; spicules short, thick, brown in color, and provided with mem- 
 branous wings. The caudal extremity of the female is straight and 
 conical; vulva somewhat posterior to the middle of the body. 
 
 Length of female, 5-10 cm. (2-4 inches); male, 3-8 cm. (1 1/8-3 1/8 
 inches). 
 
 The eggs are oval, 112-135 microns in length by 52-67 microns in 
 breadth. They contain developed embryos which are liberated in the 
 bronchi as the eggs are deposited. 
 
 The embryos are 540 microns long ]:)y 20 microns in diameter, tapering 
 to a blunt point behind. 
 
:\IETASTRONGYLIX.E ^.57 
 
 The worm is parasitic in the respiratory organs of the sheep, goat, 
 camel, and deer. 
 
 2. Synthetocaulus rufescens (Strongylus rufescens). Fig. 131. 
 INIetastrongyHnse (p. 256).— The body is thin and hair-hke, brownish 
 red in color. The mouth has three papilliform lips. The bursa of the 
 male is notched in front and has two small lateral indentations. The 
 spicules are striped transversely and rounded at their ends. The poste- 
 rior extremity of the female terminates in a blunt point; vulva imme- 
 diately in front of the anus at the base of a small pre-anal elevation. 
 
 B 
 
 Fig. 130. — Dictyocaulus filaria: a, female; b, male, 
 natural size; c, anterior extremitj-; d, eggs, — enlarged. 
 
 Length of female, 25-35 nun. (5/8-1 3/8 inches) ; male, 18-28 mm. 
 (3/4-1 1/2 inches). 
 
 The eggs are oval, 75-120 microns in length by 45-82 microns in 
 breadth. Segmentation has advanced at the time they are deposited, 
 after which the embryos develop rapidly and are liberated in the pul- 
 monary alveoli. From the alveoli the}' pass to the bronchi and trachea 
 from whence they are expelled to the outside where they have a strong 
 vitalitj' and are capable of resisting desiccation for a long time. 
 
 As found in the trachea and larger bronchi, the embryos measure 
 300-400 microns in length by 16-18 microns in breadth. 
 
 The worm is parasitic in the respiratory organs of the sheep, goat, and 
 rabbit. 
 
258 PARASITES OF THE DOMESTIC ANIMALS 
 
 3. Synthetocaulus capillaris (Strongylus capillaris). Metastrongy- 
 linse (p. 256). — This worm like the preceding is thin and brownish in 
 color. The mouth has six papillae and the caudal extremity is pointed. 
 The caudal extremity of the male is curled spirally; bursa small and sup- 
 ported by seven ribs; spicules dentate. The vulva of the female is just 
 in front of the anus. 
 
 Length of female, 20-22 mm. (7/8 of an inch); male, 14 mm. (9/16 of 
 an inch). 
 
 The eggs are brownish in color. The embryos develop after the eggs 
 are deposited and are liberated in the pulmonary alveoli and bronchi. 
 After depositing the eggs the adult worms invade the lung tissue where 
 they die and become encapsulated. 
 
 The worm is parasitic in the respiratory organs of the sheep and goat. 
 
 Bronchial and pulmonarj- strongylosis of sheep and goats is due to 
 the presence of these worms together with their eggs and larva) in the 
 air passages and alveoli. The affection is usually a broncho-pneumonia, 
 though the S3anptoms presented will be somewhat subordinate to the 
 infecting species. If the infection is with Dictyocaulus filaria, or this 
 dominates a pulmonary species coexisting in the same animal, the 
 bronchial si-niptoms will be the more prominent. On the other hand, 
 in an abundant infestation with Synthetocaulus rufescens the pulmonary 
 symptoms are likely to predominate. 
 
 Symptoms. — Bronchial strongylosis of sheep and goats is usually 
 due to the presence of adults of the species Dictyocaulus filaria in the 
 larger air passages, and in most all cases the pulmonarj^ form is asso- 
 ciated with it. In general, the symptoms are those of a bronchial 
 catarrh. There is a short dry cough which at first is at long intervals. 
 Later this is more frequent and may become paroxysmal and accom- 
 panied by distressing attacks of dyspnoea. The bronchial secretion 
 expelled through the mouth and nostrils is frequenth^ lumpy and usually, 
 though not always, contains the worms with their eggs and embryos, 
 the latter found by examination of the material with the microscope. 
 At first the liveliness and appetite of the animal are retained and there 
 is no appreciable loss of flesh. If the number of the parasites remains 
 small there will continue to be little or no manifestation of their presence. 
 Relative to the degree of infestation, the symptoms may pass through 
 the gradations above given to extreme difficulty in respiration, emacia- 
 tion, pallor, and edema of the larynx, muzzle, and ej^elids, the brisket 
 and other dependent parts of the body in some cases also becoming 
 edematous. Finally, in extreme weakness, the animal is unable to get 
 upon its feet and, in a condition of complete prostration, succumbs. 
 
 Symptoms occasioned by the presence of strongyles in the pulmonary 
 air spaces and alveoli are in themselves less prominent than those of 
 verminous bronchitis. Attentive percussion over the thorax may reveal 
 
METASTROXGYLIN.E 259 
 
 dullness in circumscribed areas, but as a rule it shows nothing abnormal. 
 Usually symptoms are only observed upon the appearance of cachexia 
 and weakness following the development of punalent areas in the lung 
 tissue, this finally bringing about the death of the anmial. 
 
 Course and Prognosis. — The duration of broncho-pulmonarj^ stron- 
 g3'losis varies according to the number of parasites present and the 
 toleration of the affected anmial. In the majority of unfavorable cases 
 the disease will run a course of two, three, or four months. In the very 
 young this period may be much shortened, the animal succumbing in a 
 few days from the first observation of sj-mptoms. Strong adult animals, 
 on the other hand, are likely, unless there is reinfection, to gradually 
 recover during a course of six to eight months. In any case where the 
 symptoms are well marked a fatal termination is to be looked for. 
 
 For Post-mortem Appearance, Development and Etiology, Control, 
 and Treatment, refer to pp. 262-265. 
 
 Bronchial axd Pulmonary Strongylosis op Cattle 
 
 Dictyocaulus viviparous (Strongylus micrurus). Fig. 132. ^Nleta- 
 strong3'hna3 (p. 256). — The body is long, slender, and attenuated at both 
 extremities. The head is rounded and without wings; 
 mouth circular and nude. The bursa of the male is 
 small, without lobes, and is supported by five ribs. 
 There are two short and strong spicules. The tail of 
 the female terminates in a sharp point; vulva near the 
 posterior sixth of the body. 
 
 Length of female, 6-8 cm. (2 3/8-3 1/8 inches); 
 male, 3.5-i cm. (1 3/8-1 5/8 inches). 
 
 The eggs are oval, 85 microns in length by 35 mi- 
 crons in breadth. Embryos are developed within the 
 body of the female and are liberated at the time the 
 eggs are deposited. 
 
 The liberated embiyos are 256 microns long by 25 
 microns in thickness. The}^ pass from the bronchi 
 to the trachea from which they are expelled to the 
 exterior. 
 
 Symptoms. — In light infestations no symptoms 
 may be observed save an occasional cough. When iQo_n- 
 
 the parasites are more numerous the cough becomes tyocaulus ' Vi-v-ipar- 
 more frequent and sonorous, and, in the further course, ous; male at right, 
 paroxysmal, the animal extending the head, protmding urTri^se^* ^^^*' °^*' 
 the tongue, and freely sahvating during the attacks. 
 The paroxysms are accompanied by dj'spnoea and suffocation, with 
 beating flanks, quickened pulse, and injected conjunctiva. In severe 
 
260 PARASITES OF THE DOMESTIC ANIMALS 
 
 cases with violent attacks occurring several times a day, the gasping 
 animal may fall prostrated and die from asphyxiation. 
 
 The mucus expelled by the coughing is frequently streaked with 
 blood and contains the worms which are often collected in masses. It 
 is to these masses obstructing the large bronchi that the suffocation is 
 due. 
 
 Course and Prognosis. — What has been said as to influences gov- 
 erning the duration and intensity of the malady in sheep will, in general, 
 apply to cattle also. The prognosis, especially in calves, is usually 
 unfavorable. Death is generally brought about in three to six months 
 by asphj^xia or extreme cachexia and exhaustion. 
 
 For Post-mortem Appearance, Development and Etiolog}^, Control, 
 and Treatment, refer to pp. 262-265. 
 
 Bronchial and Pulmonary Strongylosis of the Pig 
 
 Two strongyles are met with in the respiratory tract of the hog. 
 
 1. Metastrongylus apri (Strongylusapri; St. paradoxus). Fig. 133. 
 
 Metastrongylinse (p. 256).— The body is white or brown. The mouth 
 has six hps. The bursa of the male is bilobate, each lobe 
 sustained by five ribs. The spicules are slender and very 
 long, measuring about 4 mm. (3/16 of an inch) and each 
 terminated in a barb. The tail of the female terminates 
 b}^ a short hook-like process. The vulva is on a slight 
 eminence immediately in front of the anus. 
 
 Length of female, 2-5 cm. (3/4-2 inches); male, 1.2-2 
 cm. (1/2-3/4 of an inch). 
 
 The eggs are oval, 57-100 microns in length by 39-72 
 microns in breadth. They contain developed embryos at 
 the time they are deposited and these are liberated in 
 
 M?tastron'^us *^^® bronchi. 
 
 apri; male at The embryos at the time of their liberation measure 
 right, female at 220-250 microns in length and 10-12 microiis in thickness. 
 left, — natural rpj^^ worm is parasitic in the respiratory tract of do- 
 mestic and wild hogs, occasionally of sheep. 
 
 2. Metastrongylus brevivaginatus. Metastrongylina3 (p. 256). — 
 This species has for a long time been confounded with the preceding 
 under the name of Strongijlus paradoxus. It differs from it in the shape 
 of the bursa and in the spicules which are short, each terminating in 
 two barbs. 
 
 The worm is parasitic in the respiratory tract of domestic hogs. 
 
 Occurrence and Symptoms. — While the presence of strongyles in 
 the bronchi of pigs has been known for a long time, it is not as frequently 
 observed in these animals as in sheep and calves. Heav}'- infestations 
 
METASTRONGYLIX.E 261 
 
 with Metastrongylus apri sonietinies occur with high mortaHt}^ among 
 pigs. Such cases take a course similar to that in sheep and calves. In 
 the milder cases there ma}- be disturbances of nutrition and occasional 
 cough, though usually in light invasions nothing is observed to cause 
 suspicion of the presence of the worms which are onlv revealed on 
 examination of the respiratory passages after slaughtering. 
 
 For Post-mortem Appearance, Development and Etiology, Control, 
 and Treatment, refer to pp. 262-265. 
 
 Broxchial axd Pulmoxary Stroxgylosis of the Horse 
 
 Dictyocaulus arnfieldi (Strongylus arnfieldi). — ^Metastrongj'linse 
 (p. 256). — The body is white and filiform and the mouth is nude. The 
 bursa of the male is short, with faint lobulation. The spicules are 
 slightly arched, 200-240 microns in length, and have a net-like marking. 
 The tail of the female is short, slightly curved, and terminates in a 
 blunt point. The \T.ilva is situated somewhat posterior to the middle 
 of the body and is not prominent. 
 
 Length of female, 4.3-5.51 cm. (1 11/16-2 3/16 inches); male. 2.8- 
 3.6 cm. (1 1/8-1 7/16 inches). 
 
 The eggs are oval and measure 80-100 microns in length l)y 50-60 
 microns in breadth. The}- contain developed embryos at the time they 
 are deposited, and these are liberated in the respiratory passages of the 
 host. 
 
 The liberated embryos measure 400—490 microns in length and have 
 a thickness of 14-18 microns. 
 
 The worm is parasitic in the bronchi of the horse and ass. 
 
 Bronchial strongylosis of equines seldom occurs. Clinically it is 
 manifested by symptoms similar to those of verminous bronchitis in 
 other animals. 
 
 For Post-mortem Appearance, Development and Etiology, Control, 
 and Treatment, refer to pp. 262-265. 
 
 Cardio-Pulmoxary Stroxgylosis of the Dog 
 
 Haemostrongylus vasorum (Strongylus vasorum). ^letastron- 
 gylinie (p. 256). — The body is filiform, whitish or reddish in color, and 
 has longitudinal striations. The mouth is nude. The bursa of the male 
 has two lobes, each sustained by four ribs. The vulva of the female 
 is situated in front of the anus. 
 
 Length of female, 18-21 nun. (3,4-13/16 of an inch); male, 14-18 nun. 
 (9yl6-3/4of aninch). 
 
 The eggs are oval and measure 70-80 microns in length by 40-50 
 microns in breadth. Segmentation occurs after they are deposited. 
 
262 PARASITES OF THE DOMESTIC ANIMALS 
 
 When freed from the eggs the embiyos measure 300-360 microns in 
 length by 13 microns in thickness. 
 
 The worm Hves in the right heart and ramifications of the piihnonary 
 artery of the dog. 
 
 Cardio-puhiionary strongylosis of the dog is due to the presence of 
 these parasites, together with their eggs and embryos, in the right 
 ventricle of the heart and small ramifications of the pulmonary 
 artery. 
 
 Symptoms. — Symptoms in this form of strongylosis of the dog are 
 obscure, and generally the disease is not recognized until post-mortem 
 examination of the animal. Respiratory disturbances occur in some 
 cases, and there may be the development of ascites. The attacks of 
 respiratory difficulty may disappear after a few days, or the}^ may lead 
 to asphyxia and the death of the animal. 
 
 For Post-mortem appearance, refer to page 263. 
 
 Pulmonary Strongylosis of the Cat 
 
 Synthetocaulus abstrusus (Strongylus pusillus). Metastrongylinse 
 (p. 256). — The body is filiform and the mouth is without papillae. The 
 bursa of the male is short and slightly festooned. The spicules are slen- 
 der, long and recurved. The caudal extremity of the female terminates 
 in a blunt point; vulva immediately in front of the anus. 
 
 Length of female, about 10 mm. (3/8 of an inch); male about 5 mm. 
 (3/16 of an inch). 
 
 The eggs are oval or subglobular, 60-85 microns in length by 35-80 
 microns in breadth. Segmentation occurs after they are deposited. . 
 
 The liberated embryos are 370^50 microns in length by 16-18 
 microns in diameter. 
 
 The worm is parasitic in the lungs of the cat. 
 
 Symptoms. — Verminous pneumonia of cats produced by the ova and 
 embryos of this worm not infequently occurs without symptoms by 
 which it may be recognized. On the other hand, the animals may have 
 a frequent cough accompanied by vomiting. Where emaciation and 
 diarrhea follow upon such symptoms, death will usually result after a 
 course of two to three months. 
 
 Post-Mortem Appearance in Bronchial and Pulmonary 
 Strongylosis 
 
 Animals which have died as a result of strongyles in the respirator}^ 
 passages will, upon necropsy, show an abundant collection of mucoid 
 and mucopurulent material in the bronchial tubes which is frequently 
 streaked with blood and contains the adult worms, ova, and embryos. 
 
:\IETASTRONGYLIN.E 263 
 
 The worms may be in masses sufficient to obstruct the medium-sized 
 or larger bronchi which in places may present sac-like dilations con- 
 taining bundles of worms together with more or less purulent mucus. 
 The mucosa of the heavil}- infested bronchi is edematous and may show 
 hemorrhagic streaks. In the vicinity of bronchial dilations especially 
 there is proliferation of connective tissue, the air-containing tissue 
 being compressed and obliterated and at the periphery sometimes 
 showing localized pleuritic adhesions. 
 
 In pneumonia due to the presence of strongyles three forms have 
 been distinguished, viz: 1. A lobar pneumonia due to the presence of 
 the adult worms in the ramifications of the bronchi. 2. A diffuse pneu- 
 monia due to ova and embryos which invade the pulmonary tissue in 
 large numbers. 3. A nodular or pseudo-tuberculous pneumonia due 
 to the accumulation of eggs and embryos in circumscribed parts of the 
 lungs. The last is the most common form and is characterized by the 
 presence of small, hard, grajdsh yellow centers from the size of a millet 
 seed to that of a pea which may be more or less confluent. Most of 
 these nodules are found toward the periphery of the lungs, particularl}^ 
 at the margins and just beneath the pleura. Generally they adhere 
 closely to the surrounding tissue, var^'ing in color from yellow, grayish 
 yellow, reddish brown, violet, or black according to their age and the 
 character of the inflammatory process. All of the centers become caseous 
 and finally undergo calcareous infiltration. 
 
 In addition to the bronchial and pulmonary lesions there are presented 
 in severe cases the evidences characteristic of ansemia and cachexia, 
 involving subcutaneous edema and serous exudate in the cavities of the 
 body. 
 
 Dogs which have suffered from cardio-pulmonary strongjdosis will, 
 on necrops3% reveal adult worms {Hcemostromjylus vasorum) in the right 
 heart and branches of the pulmonary artery. The lungs at the bases of 
 their lobes show circumscribed granular areas in which the tissue is 
 gra\', compact, and heavier than water. The granules are hardly the 
 size of a pin's head, semi-transparent, and give a roughened aspect to 
 the surface. About the eggs and embryos lodged in the small arterioles 
 there are found small pseudo-follicles which, on histological examina- 
 tion, will exhibit three zones, — (1) a central consisting of a giant cell 
 containing a segmented egg or embryo; (2) a middle of epithelial cells; 
 and (3) a peripheral consisting of embryonal tissue elements disposed 
 circularly. Larger nodules may be found, usually in close relationship 
 to a clot in a branch of the pulmonary artery in the vicinity of which 
 there is an accumulation of adult strongyles. 
 
 Development and Etiology. — The lungworms deposit their eggs in 
 the respiratory passages of their host and the freed embr^'os are either 
 expelled directly with the bronchial secretion or, passing to the pharynx, 
 
264 PARASITES OF THE DOMESTIC ANIMALS 
 
 are swallowed and reach the outside with the feces. Further than this 
 little is known as to their life history. The larvae do not appear to pass 
 through any stages of development in the bronchi of their host, the first 
 phases of their existence probably requiring that they be expelled from 
 the animal. 
 
 Having reached the outside, if the larvae encounter sufficient warmth 
 and moisture, they molt and this is later followed by a second molting 
 after which they retain their coverings and in this condition may resist 
 desiccation for a long thne. It is probable that the larvae find their 
 way to a host with the wet grass and, especially in the case of sheep, 
 with collections of water upon the pastures which the animals drink. 
 The view as to direct development and infection is supported by the 
 investigations of Romanovitch and Slavine (p. 256), and it seems 
 probable that in all cases of bronchial and pulmonary strongylosis the 
 infection is direct. Some authors, however (Cobbold, Leuckart), be- 
 lieve that a portion of the larval stage is lived in an invertebrate host, as 
 an earthworm, larval insect, or mollusc. 
 
 The larvae are usually taken up by the host animals in the spring, 
 though it is probable that infection may occur at any time during the 
 pasture season." That infection cannot occur directly from animal to 
 animal has been demonstrated by Leuckart, Herms and Freeborn and 
 others who were not successful in bringing it about l^y the introduction 
 into the respirator3^ passages and stomach of bronchial mucus containing 
 numerous embryos. 
 
 The course of the larval worms in reaching the l^ronchi after natural 
 infection by way of the digestive organs has not been demonstrated. 
 Based upon the function of rumination and the peculiar susceptibility 
 of ruminating animals, the invasion of the air passages has been attrib- 
 uted to the regurgitation of contaminated food, the worms passing 
 from the pharynx to the larynx and trachea. But this hypothesis seems 
 to have no more than plausibility in its support, and certainly cannot 
 well apply to the case of the non-ruminating hog. 
 
 Control. — In districts where bronchial and pulmonary strongylosis 
 prevails, low, marshy and wet pastures or parts of pastures should not 
 be accessible to susceptible animals. Drainage and a liberal covering 
 of the ground with lime phosphates will do much to destroy the larvae. 
 Bearing in mind that young animals are more susceptible to attack than 
 older ones, it is advisable where the disease prevails to give them feed 
 and water each day before they are turned upon pasture. This will in a 
 measure prevent them from going to pools and marshy places for water 
 where they are likely to linger and graze unless their night's fast has 
 been previously somewhat broken. Where hogs and cattle are con- 
 cerned the pens, stables and drinking places should be repeatedly cleaned 
 and disinfected. Sputum, feces and bedding are not to be placed 
 
METASTRONGYLIN.E 265 
 
 with manure to be spread upon the fields, but should be collected and 
 burned as should also the infected respirator}?- organs of slaughtered 
 animals. 
 
 Treatment. — ^Treatment with a view to attacking the worms by way 
 of the digestive tract with remedies supposed to act by their excretion 
 through the lungs can at most be but mildly successful. Administered 
 in this way, a sufficient quantity of the anthelmintic to be effectual would 
 probably include the host in its destructive effect. 
 
 Fumigation with various substances has been recommended and 
 widely practiced. This procedure has more to reconnnend it than the 
 first mentioned in that the remedy reaches the worms directly, having 
 such a deleterious action upon them that the}' are more readity expelled 
 in the coughing induced by the irritant smoke and vapors. Again an 
 objection to the method is the intensity of application required for its 
 success, this demanding that the animals be subjected to the fumes until 
 they are dangerously close to asphyxiation. 
 
 AVhere the fumigation treatment is resorted to it should be carried 
 out in a tightly closed building to accommodate not more than fifty 
 lambs at a time. Among the various substances which have been used 
 to generate the fumes are tar, creolin, asafetida, horns,- hoofparings, hair 
 and the vapor of heated oil of turpentine. The intensity and duration 
 of the treatment should be governed by the size and vigor of the animals 
 and according as they become accustomed to it. At first it should not 
 be applied for more than a few minutes each day; later two or three 
 treatments of ten or more minutes duration each may be given daily. 
 During the fumigation the animals should l)e closol}' watched for evi- 
 dences of asphyxiation. 
 
 Of agents for creating the fumes, tar, sulphur and turpentine may l^e 
 mentioned as prol)ably among the best. These may be placed upon 
 hot coals contained in a pot suspended by a chain from the ceiling in 
 such manner that it will be just l)cyond the reach of the animals' heads. 
 The fumes should fill the entire enclosure and can be maintained by 
 adding more of the ingredients as required. 
 
 A more successful method of treatment is by tracheal injections of 
 liquids which will kill the worms or reduce their vitality to a sufficient 
 degree that they may be easily expelled. This procedure is espe- 
 cially to be reconmiended for calves and is equally effectual for lambs, 
 though where flocks of considerable size are involved, it is not so 
 practicable. 
 
 The measure of success attauied by such treatment will depend largely 
 upon the degree to which the worms and their larvae have penetrated to 
 the deeper parts of the respiratory organs. The solutions used must 
 reach their destination l)y gravity, aided somewhat In- the currents of 
 inspired air, so that ultimately they will probably pass no further than 
 
266 PARASITES OF THE DOMESTIC ANIMALS 
 
 to the anterior portions of the lungs, the more deeply lodged parasites 
 remaining unaffected. Furthermore, where an air passage is occluded 
 by a mucus plug and mass of worms, the remedy will not pass beyond 
 the obstruction and, therefore, cannot reach the further ramifications of 
 the passage. 
 
 Probably aqueous solutions for intratracheal injection have an ad- 
 vantage in more readily becoming diffused. Oily preparations do not 
 penetrate so deeply nor do they mix with the mucus. On the other hand, 
 it is to be said in their favor that they are not so readily absorbed as 
 aqueous solutions and remain in the air passages longer. The use of 
 both aqueous and oily mixtures conjointly might well be recommended. 
 
 Among the numerous formulae for intratracheal injection the following 
 may be mentioned; (1) Iodine two parts, iodide of potassium ten parts, 
 distilled water one hundred parts. Mix and inake into an emulsion with 
 equal parts of oil of turpentine and olive oil. Give one to two drams to 
 each sheep; calves three to four drams. Two injections with an interval 
 of two days may be sufficient. (2) One per cent, aqueous solution of 
 carbolic acid. Sheep one to one and a half drams, calves three to five 
 drams. Inject once daily for several successive daj^s. (3) Creolin five 
 parts, oil of tupentine and olive oil of each fifty parts. Sheep one to 
 one and a half drams, calves three and a half to five drams. Inject once 
 daily for three successive da5'^s. (4) Creosote twenty parts, oil of amyg- 
 dala one hundred parts. Calves one to one and a half drams. Inject 
 once daily for four days. 
 
 The intratracheal injections should be made slowly with a curved 
 needle of large caliber or with a curved trochar. Previous to the opera- 
 tion the wool should be shaved or closely clipped from the region. The 
 needle should enter between the tracheal rings, preferably after a small 
 incision has been made in the skin. 
 
 Based on experiments which they carried on for over one year (1914), 
 involving about two hundred and fifty animals, Herms and Freeborn 
 concluded that chloroform administered nasally is, under proper condi- 
 tions, a valuable method of treatment. The chloroform is introduced 
 first into one nostril, then into the other, with an all glass syringe or 
 medicine dropper in doses sufficient to nearly anaesthetize the animal, or, 
 in other words, until it becomes "groggy." The dosage required for 
 this will depend upon the animal's susceptibihty, and therefore cannot 
 be exactly given. It is stated as varying from twenty-three to forty-six 
 drops for angora goats, and from sixty to one hundred and sixty-five 
 drops for calves, one-half the quantity in each nostril. The treatment is 
 to be repeated at five or six day intervals until recovery, which, under 
 good conditions of food and shelter, should not require more than three 
 injections. Experiments by the investigators mentioned have shown 
 that, while the worms were not killed immediately, death and disin- 
 
METASTRONGYLIN^ 267 
 
 tegration of most of them occurs a few hours after the administration of 
 the chloroform when large numbers are expelled in coughing. 
 
 Whatever procedure maj^ be adopted in the treatment of bronchial 
 and pulmonary strongylosis, or if treatment is not attempted, it is highly 
 important that the animals receive plenty of nourishing food and that 
 they be well sheltered against cold and wet weather. 
 
CHAPTER XXII 
 NEMATODA. SUBFAMILY II. TRICHOSTRONGYLINiE 
 
 WOEMS OF THE StOMACH AND INTESTINE 
 
 Strongylidse (p. 255). — These strongyles are parasitic only in the 
 ahmentary canal. The mouth is simple and without a buccal capsule 
 (Fig. 135). The body is generally straight or it may be somewhat 
 curved. The eggs are generally segmented at the time they are de- 
 posited. Development is direct, and infection, so far as known, is only 
 b}^ ingestion. 
 
 Gastro-Intestinal Strongylosis of the Sheep and Goat 
 
 1. Haemonchus contortus (Strongylus contortus). Fig. 134. 
 Trichostrongylinse (p. 268). — The body is filiform, attenuated at the 
 extremities, and red or white in color. The integument is striated 
 transversely. Near the anterior extremity there are two lateral tooth- 
 like papillae directed backward. The bursa of the male has two long 
 lobes and a small lobe accessory to the right (Fig. 136); there are two 
 spicules. The tail of the female is acutely pointed; anterior extremity 
 more gradually attenuated ; vulva toward posterior fifth of the bod^'. 
 
 Length of female, 18-30 mm. (11/16-1 3/16 inches) ; male, 10-20 mm. 
 (3/8-3/4 of an inch). 
 
 The eggs are elongated oval and measure 70-95 microns long by 
 43-54 microns wide. According to Railliet they contain developed 
 embryos at the time of deposition. Hatching probably takes place in 
 water, the embryo at the time of its release measuring 300-400 microns 
 in length by 17-21 microns in breadth. Infection is probably b}' drinking 
 water and contaminated pasturage bearing the larvae. 
 
 The worm is parasitic in the abomasum and duodenum of sheep, 
 goats, and cattle. 
 
 2. Cooperia curticei (Strongylus ventricosus; St. curticei). Fig. 
 137. Trichostrongylinse (p. 268).— The anterior end of the body is 
 usually coiled spirally. The cuticle at the region of the head is striated 
 transversely; cuticle of remainder of the body exhibits fourteen to six- 
 teen longitudinal lines. The mouth is small and not well defined. The 
 bursa of the male has two lateral lobes and a small median lobe. The 
 spicules are short. The vulva of the female is close to the posterior end 
 of the body. Tail slender and acutely pointed. « 
 
TRICHOSTRONGYLIN.E 
 
 269 
 
 nv.l. 
 
 Fig. 136. — Hsemonchus contortus, — enlarged, 
 Posterior extremity of male, dorsal Aaew; d. 
 dorsal ray supporting the asymmetrically 
 situated dorsal lobe of bursa; e. d., externo- 
 dorsal ray; e. 1., externo-lateral ray; gub., 
 gubernaculum; 1. v., latero-ventral ray; m. 1., 
 medio-lateral ray; p. 1., postero-lateral ray; 
 sp., spicule; v. v., ventro-vcntral ray (after 
 Ransom, Bull. No. 127, Bureau An. Ind., U. S. 
 Fig. 134.— l:S::^^}^m, Dept. Agr.). 
 
 Hsemonchus con- i c c i i / / 
 
 tortus, female. Fig. i35.-Ha5mon- Length oi tcniale, about 6 mm. (1/4 
 *Vuiva. x5. (Af- chus contortus, an- of an inch); male about 5 mm. (3/16 
 
 ter Ransom, Bull, terior portion of 
 
 No. 127, Bu 
 An. Ind., U. S 
 Dept. Agr.). 
 
 body, — enlarged: c. 
 p., cervical papilla; 
 es., esophagus; int., 
 intestine; n. r., nerve 
 ring (after Ransom, 
 Bull. No. 127, Bu. 
 An. Ind., U. S. Dept. 
 Agr.). 
 
 of an inch). 
 
 The eggs are oval, 63-70 microns in 
 length by 30-32 microns in width, seg- 
 mented at time of deposition. 
 
 The worm is parasitic in the small 
 intestine, more rarely the abomasum, 
 of the sheep and goat. 
 3. Ostertagia marshalli. Fig. 139. Trichostrongylinae (p. 268). — 
 The mouth is small and surrounded b\' six indistinct papillae. The 
 cuticle has twenty-five to thirty-five longitudinal ridges appearing as 
 lines. Cervical papillae 340-415 microns from anterior end of the body. 
 The bursa of the male is bilobate; spicules short and similar, yellowish 
 brown in color. The tail of the female is slender, gradually tapering, 
 and rounded at the tip. The \ailva is a transverse slit located near the 
 tail extremitv. 
 
270 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. 137. — Cooperia curticei; male at 
 right, female at left. *Vulva. xl5. 
 (After Ransom, Bull. No. 127, Bureau 
 An. Ind., U. S. Dept. Agr.). 
 
 Fig. 139. — Ostertagia marshalli; male at right, female at 
 left, enlarged (after Ransom, Bull. No. 127, Bureau An. Ind., 
 U. S. Dept. Agr.). 
 
 m 
 
 Fig. 138.— Co- 
 operia curticei, 
 anterior portion 
 of body, lateral 
 view. x300. (Af- 
 ter Ransom, BuU. 
 No. 127, Bureau 
 An. Ind., U. S. 
 Dept. Agr.). 
 
TRICHOSTRONGYLIN.E 
 
 271 
 
 Length of female, 12-20 mm. (1/2-3/4 of an inch); male, 10-13 mm. 
 (3/8-1/2 an inch). 
 
 The eggs are oval, 160-200 microns in length by 75-100 microns in 
 breadth. 
 
 The worm is parasitic in the abomasum, rareh^ the small intestine, 
 of the sheep. It was first collected by Dr. H. T. Marshall and Prof. 
 V. K. Chestnut in Montana. 
 
 4. Trichostrongylus instabilis (Strongylus colubrif ormis ; St. in- 
 stabilis). Fig. 140. Trichostrongylina? (p. 2r)S).^The body is small, 
 slender, gradually attenuated forward from 
 posterior fifth; color reddish. Cuticle trans- 
 versely striated ; longitudinal lines and cer- 
 vical papilla3 absent. The bursa of the 
 male is large and laterally lobed; spicules 
 short, spatulate, and appearing as though 
 twisted. The body of the female is but 
 slightly thinner toward the anus; behind 
 the anus it suddenly narrows to form a 
 sharp tail; vulva near middle of posterior 
 half of the body. 
 
 Length of female, 5-6 mm. (1/4 of an 
 inch) ; male, 4-5 mm. (3/16 of an inch). 
 
 The eggs are oval, 73-76 microns 
 length by 40-43 microns in breadth. 
 
 The worm is parasitic in the duodenum 
 of sheep and goats of North Africa, Europe, 
 Japan, and United States. In Egypt it 
 has been observed in man. 
 
 Other species which may be found in 
 sheep and goats are Nematodirus filicollis 
 and Cooperia oncophora which are referred 
 
 to under gastro-intestinal strongylosis of som, Bull. No. 127, Bureau An. 
 cattle. Ind..U.S.Dept.Agr.). 
 
 Occurrence. — Gastro-intestinal strongylosis of sheep and goats is 
 generally caused by the presence of Hccmonchiis contortiis which may 
 be in association with one or more other species. This stomach worm 
 is recognized as one of the most serious of the numerous pests with 
 which the sheep raiser has to contend. Animals of all ages become 
 infected, but the most serious effects are observed in lambs and kids. 
 Occurring mostly in wet marsh}' districts and in seasons of frequent rain 
 — conditions favorable to the propagation of the lung as well as the 
 gastric worms — the affection is frequently associated with the respiratory 
 form of strongylosis. 
 
 In the United States the stomach worm of sheep, goats, and cattle 
 
 Fig. 140. — Trichostrongylus in- 
 stabilis; male at right, female at 
 left.—* Vulva. xl5. (After Ran- 
 
272 PARASITES OF THE DOMESTIC ANIMALS 
 
 is especially prevalent in the Mississippi Valley, in the region of rivers 
 tributar}^ to the Mississippi, and in the Gulf States. In parts of the 
 Middle AVest and South the parasite has been such a source of discour- 
 agement as to cause the sheep industry to be almost completely aban- 
 doned. 
 
 Pathogenesis. — Taken up as larvte with ingested plants or drinking 
 water, the worms attack the mucosa of the fourth stomach and feed 
 upon the blood of their host. The degree of disturbance which they 
 cause will be proportionate to their number. Heavy infestations are 
 accompanied by disorders of digestion and lead through loss of blood 
 to anemia, dropsy, and emaciation, the general morbid effect being 
 contributed to b}^ the toxins elaborated by the parasites. 
 
 Symptoms. — The symptoms are those of a pernicious anaemia. The 
 infected animal becomes dull and spiritless and there is arrested develop- 
 ment. The appetite is diminished and depraved, and the animal fre- 
 quently seeks water to quench an intense thirst. The anaemia is revealed 
 in the paleness of the skin and visible mucous membranes and in the 
 edematous swellings in dependent parts of the body, often under the 
 lower jaw. Later in the course of the disease a diarrhea appears with 
 Avatery dark discharge of putrid odor. In some cases the toxic disturb- 
 ances may be manifested by convulsions or paralysis. Finally, after a 
 course of several months, the animal dies in a state of extreme emacia- 
 tion and weakness. 
 
 The cause of these symptoms of a progressive anaemia can often be 
 no more than suspected, and, where the condition prevails in flocks, a 
 more certain diagnosis may be made by killing an affected animal and 
 examining the fourth stomach. 
 
 For Post-mortem Appearance, Development, Control, and Treat- 
 ment, refer to pp. 275-279. 
 
 Gastro-Intestinal Strongylosis of Cattle 
 
 Several species of strongyles may occur in the abomasum of cattle- 
 Of these the most important are Hcemonchus contortus, described under 
 gastro-intestinal strongylosis of sheep, and the encj^sted stomach worm, 
 Ostertagia ostertagi. 
 
 1. Ostertagia ostertagi (Strongylus ostertagi). Fig. 141. Tricho- 
 strongylinae (p. 268). — The body is filiform with attenuated extremities. 
 The mouth is small and surrounded by six indistinct papillae; cervical 
 papillae present. The cuticle has 25 to 35 longitudinal lines or ridges. 
 The bursa of the male is comparatively small and has two lateral lobes 
 united bj' a small median lobe (Fig. 142). The spicules are short, each 
 having two slender barbed processes coming off from the inner side in 
 the posterior half. The vulva of the female is a transverse slit covered 
 
TRICHOSTROXGYLIX.E 
 
 273 
 
 \n^ i-s/x 
 
 .p.bp. 
 
 Fig. 142. — Ostertagia ostertagi. 
 Posterior extremity of male with 
 bursa spread out: d, dorsal ray; e. d., 
 externo-dorsal ray; p. 1., postero- 
 lateral ray; m. 1., medio-lateral ray; 
 e. 1., externo-lateral ray; 1. v., latero- 
 ventral raj-; v. v., vontro-ventral ray; 
 p. b. p., pre-bursal papilla; sp., spi- 
 cules. xloO. (After Ransom, from 
 Railliet, Bull. No. 127, Bureau An. 
 Ind., U. S. Dept. Agr.). 
 
 b}' a prominent cuticiilar flap; it is located 
 close to the caudal extremity of the body. 
 The tail tapers gradually and ends in a slen- 
 der tip. 
 
 Length of female,, 8-10 mm. (5/16-3/8 of 
 an inch) ; male, 7-8 mm. (1/4-5/16 of an inch.) 
 
 The eggs are oval, 65-80 microns in length 
 by 30-40 microns in breadth. 
 
 The worm is parasitic in the wall and cavity of the abomasum of 
 cattle. 
 
 2. Nematodirus filicoUis (Strongylus filicoUis). Fig. 143. Tricho- 
 strongylinae (p. 268). — This is a white hair-like worm, very thin in front, 
 thicker behind. The cuticle has eighteen longitudinal ridges. The 
 bursa of the male is bilobate; there are two very long and slender spicules 
 united by a membrane posteriorly which forms a spatulate enlargement 
 at the tip. The \iilva of the female is a transverse slit located about 
 one-third of the length of the body from the caudal e.xtremity. At this 
 location the bodv has its maximum thickness which is suddenly reduced 
 
 Fig. 141. — Ostertagia oster- 
 tagi; male at right, female at 
 
 left, 
 som, 
 Ind. 
 
 * Vulva. xl5. (After Ran- 
 BuU. No. 127, Bureau An. 
 U. S. Dept. Agr.). 
 
Fig. 143. — Nematodirus filicollis; male in center, female at left. * Vulva. xl5. At 
 right, enlarged anterior portion of body. (After Ransom, Bull. No. 127, Bureau An. Ind., 
 U. S. Dept. Agr.). 
 
 Fig. 144. — Cooperia oncophora; male at right, female 
 at left. * Vulva. xl5. (After Ransom, Bull. No. 127, 
 Bureau An. Ind., U. S. Dept. Agr.). 
 
TRICHOSTRONGYLIX.E 275 
 
 just behind the vulva. The tip of the tail is truncate and bears a short 
 bristle-like process. 
 
 Length of female, 10-24 mm. (3/8-15/16 of an inch); male, 8-13 nmi. 
 (5/16-1/2 of an inch). 
 
 The eggs are elongated oval, 110-113 microns in length b}' 64-70 
 microns in breadth; segmented at time of deposition. The further 
 development is not known. 
 
 The worm is parasitic in the small intestine of cattle, sheep, and goats. 
 
 3. Cooperia oncophora (Strongylus oncophora). Fig. 144. Tricho- 
 strongylina' (p. 268). — The head is rounded, without well-marked papil- 
 lae; mouth cavity small and not well defined. The cuticle in the region of 
 the head is transversel.y striated; cuticle of remainder of body with 14- 
 16 longitudinal lines or ridges; cervical papillae absent. The bursa of 
 the male, when spread, is large and has two lateral lobes and a small 
 median lobe; border of median lobe incised. The spicules are short 
 and of comparatively simple structure. The vulva of the female is in 
 the posterior fourth of the body. At the region of the vulva the body is 
 much enlarged. The tail is slender with rounded tip; terminal portion 
 of tail marked with annular striations. 
 
 Length of female, 6-8 mm. (5/16 of an inch) ; male about the same. 
 
 The eggs are oval, 60-80 microns in length by 30 microns in width. 
 
 Inhabits the small intestine of cattle and sheep. 
 
 Occurrence and Symptoms. — Haemonchus contortus is frequently 
 found in the al)omasum of cattle. When the infestation is heav}', which 
 usually occiu's in young pastured animals, they bi'ing about the sjniip- 
 toms of a pernicious anaemia as descriljed in the infestation of sheep. 
 The cattle become infected ])y grazing upon pastures which are contam- 
 inated by the di'oppings of infected sheep, goats, or other infested cattle. 
 
 The s\Tuptoms caused by the presence of Ostertagia ostertagi, or the 
 cncj^sted stomach worm, are similar to those produced Ijj" Hcemonchus 
 contortus. It lives in small cysts in the mucosa of the abomasum and 
 is also found free in the contents of this organ. When numerous, they 
 cause a catarrhal condition and disturbances of digest-ion. 
 
 For Post-mortem Appearance, Development, Etiology, Control, and 
 Treatment refer to pp. 275-279. 
 
 Gastro-Intestixal Strongylosis. Post-AIortem Appearance 
 
 Examination of the contents of the abomasum and duodenum from 
 an animal which has been heavily infested with stomach strongyles 
 will reveal undulating movements of the fluitl produced by the active 
 wriggling a})Out of the worms. Large num])ers will also be found deeply 
 adhering to the mucosa which will show the lesions of a subacute or 
 chronic catarih. Further than this, the pernicious anaemia is evidenced 
 
276 PARASITES OF THE DOMESTIC ANIMALS 
 
 in the paleness of the body tissues, edematous swelHngs, exudate into 
 the serous cavities, and cachexia. 
 
 Where Ostertagia ostertacji are present in the abomasum of cattle they 
 will be found both free in the stomach contents and embedded in the 
 subepithelial tissue of the mucosa in small round cysts about the size 
 of a pin-head or slightly larger. When numerous, the same lessions are 
 shown as in the attack upon the mucosa of a heaw invasion with Hcemon- 
 chiis contortus. 
 
 Gastro-Intestinal Strongylosis. Development and Etiology 
 
 The eggs of Hoemonchus contortus passed in the feces of the host will 
 hatch in a variable time according to the conditions of temperature and 
 moisture. When these are favorable it may occur in a few hours, while, 
 under more adverse conditions, it may take several days or weeks. 
 Drj^ness or a freezing temperature kills the embryos and newly hatched 
 larvae in a short time. Upon hatching the larva feeds upon the fecal 
 matter with which it is surrounded. Later it becomes enveloped by a 
 chitinous sheath, in this condition probably receiving nourishment 
 from food material stored within its body. At this stage the larva can 
 survive freezing and drying for long periods and is motile at temperatures 
 above 40° F., becoming more active with increase in temperature. Where 
 there is sufficient moisture, as from dew or rain, it crawls upon a blade 
 of grass or other vegetation and gradually makes its way to a position 
 well removed from the ground. In this position it is taken up by the 
 grazing ruminant host and, reaching the abomasum, becomes mature in 
 two to four weeks. If the eggs or newly hatched larvce are ingested 
 they apparently do not undergo further development. It seems, there- 
 fore, that only the ensheathed larvae are infective. 
 
 Control. — As stated in the foregoing, moisture favors the develop- 
 ment of the embryos, while dryness kills them at their early stages. 
 High pasture ground, therefore, with good natural drainage greatly 
 reduces the chances of the larvae reaching the infective stage. Further- 
 more, larvae which have become infective are more motile in the presence 
 of moisture such as is supplied by the heavy dews and fogs occurring 
 over low land; crawling, then, out upon the wet blades of grass, the 
 worms are more likely to be taken up by the grazing animals. 
 
 If the temperature remains constantly at about 95° F. the infective 
 larval stage is reached in three to four days after the eggs have passed 
 from the body of the host. At 70° F. one to two weeks are required, 
 while three to four weeks are necessary at about 50° F. At temperatures 
 below 40° F. the eggs are dormant and the larvae remain inactive. Under 
 the usual climatic conditions of the northern part of the United States, 
 therefore, there is little possibility of new infection from placing in- 
 
TRICHOSTRONGYLIN^ 277 
 
 fectecl and noninfected animals together in clean fields from the first 
 of November until March. 
 
 During the warmer months the best means of controlling the parasite 
 seems to be by the rotation of pastures, keeping each pasture free from 
 sheep and cattle for at least a 3'ear, by which tmie the larvffi will be dead. 
 As to this method Ransom (U. S. B. A. I., Cir. No. 102) suggests the 
 following: "Infested and nonmfested sheep which have been kept to- 
 gether in clean fields from November to March or later, according to 
 weather, if moved then to another clean field may remain there nearly 
 the entire month of April before there is danger of infection. From the 
 first of Ma}' on through the summer the pastures become infectious much 
 more quickly after infested sheep are placed upon them, and during 
 May it would be necessary to move the sheep at the end of every two 
 weeks, in June at the end of everj^ ten days, and in July and August at 
 the end of each week, in order to prevent the noninfected sheep from 
 becoming infected from the worms present in the rest of the flock. 
 After the first of September the period maj^ again be lengthened." 
 
 The difficulties and inconveniences of this method consist in the num- 
 ber of small pastures and subdivisions of pastures which it requires; 
 furthermore, it imposes limitations upon the size of the flock. It is, 
 however, probably the most effective system thus far devised for the 
 eradication of this parasite. 
 
 Where it can be convenientl.y practiced, it is a good precautionarj^ 
 measure to burn over the pastures in the early spring or fall. This will 
 destroy most of the eggs and larvae which are lodged upon the grass or 
 upon the ground. 
 
 Treatment. — Experiences recorded with the use of drugs for the 
 expulsion of stomach worms are somewhat varied. The success attained 
 by such treatment has not equaled expectations based upon experiments 
 made with the agents upon worms outside of the bod}'- of a host. It is 
 probable that this is mainly due to the fact that drugs administered to 
 ruminants by the mouth do not pass directly to the abomasum, but must 
 first mix with the ingesta of the rumen and reticulum, passing from the 
 latter by way of the omasum to the abomasum and intestine. Hence, 
 before reaching the worms the drug become sufficiently diluted or mixed 
 with the bulky ingesta to greatly reduce its effectiveness. Treatment 
 for the expulsion of Hcemonchus contortus gives better promise for success 
 than that for the smaller stomach strongjdes, as Ostertagia ostertagi, 
 owing to the protected position of the latter within the nmcosa. 
 
 Animals which are to be treated should be taken up in the afternoon 
 of the day previous to treatment and all food withheld from them for 
 eighteen to twenty-two hours. The remedy should be given the following 
 morning either with a long-necked bottle or, better,, with a drenching 
 tube consisting of about three feet of one-half inch rubber tubing with 
 
278 PARASITES OF THE DOMESTIC ANIMALS 
 
 a funnel inserted at one end and a four to six inch piece of metal tubing 
 inserted in the other end, the metal tube to be placed in the animal's 
 mouth between the molar teeth. The funnel may be held by an assistant 
 or fastened to a post while receiving the liquid, the flow of which may be 
 controlled by pinching the rubber tube near the insertion of the metal 
 piece. The dosage for each sheep should be carefully measured accord- 
 ing to age, and care taken to lower the head at once upon entrance of 
 the liquid into the larynx, this often a result of holding the head too high 
 and indicated by coughing. 
 
 Among the remedies used for the expulsion of stomach worms may 
 be mentioned (1) copper sulfate, (2) gasoline, and (3) coal-far creosote. 
 An objection to the last named is its variable composition, the substance 
 not infrequently sold under the name of coal-tar creosote being quite 
 unreliable for the purpose here considered. Copper sulfate has received 
 high recommendation and is extensively used in the sheep flocks of 
 South Africa. It ma}^ be prepared and given as follows: 
 
 Dissolve 1/4 of a pound (avoirdupois) of clear blue crystals of copper 
 sulfate in one pint of boiling water, having first crushed the crystals in 
 a mortar to a fine powder. In making the solution use a porcelain or 
 enamel-ware vessel as the bluestone will corrode most metals. Add to 
 this solution enough cold water to make it up to three gallons, using 
 non-metallic receptacles. This will make an approximate one per cent, 
 solution, and, allowing for waste, will be enough for the treatment of 
 about one hundred adult sheep. 
 
 The dosage is to be graded according to age as follows : 
 
 Lambs 3 months to 1 year old 5 drams to 11/2 oz. (20-50 cc). 
 
 Sheep over 1 year old 2 to 3 oz. (64 to 96 cc). 
 
 Calves 3 to 4 oz. (96 to 128 cc). 
 
 Yearling cattle 6 oz. (192 cc). 
 
 The annuals should receive no water at any time during the day the^' 
 are dosed. 
 
 "NMiere the stomach worm exists in a fiock, it has been suggested as a 
 control measure to give 50 cc of a one per cent, solution of copper 
 sulfate every month or so except during the winter in climates where 
 the winter is freezing. 
 
 Gasohne has afforded a convenient remedy, but, for reasons which 
 need not be gone into here, the commercial gasoline of the present time 
 is unsuitable for this purpose. Under such conditions onty the official 
 purified gasoline (benzinum purificatum, U. S. P.) should be used. At 
 best, however, gasolme is probably less satisfactory for the purpose 
 than copper sulfate; furthermore, to be effectual, the gasoline treatment 
 must be repeated upon three consecutive days. 
 
 In the preparation for the administration of gasoline withhold water 
 
TRICHOSTRONGYLIN.E 279 
 
 as well as feed. The following morning give the gasoline in milk, linseed 
 oil, or flaxseed tea, mixing the dose for each animal according to age as 
 follows : 
 
 Lambs 2 drams (8 cc). 
 
 Sheep 4 drams (16 cc). 
 
 Calves 4 drams (16 cc). 
 
 Yearling cattle 1 oz. (32 cc). 
 
 Three hours later allow feed and water. At night again confine the 
 animals without feed and water. The next morning give the second 
 dose, the third morning the third dose, the treatment before and after 
 dosing being the same in each case. Gasoline should not be given in 
 water, nor should it be given soon after the animals have taken water. 
 
 Coal-tar creosote may be given in solution of one per cent, strength. 
 The solution is made by shaking together one ounce of coal-tar creosote 
 and ninety-nine ounces (6 pints and 3 ounces) of water. The doses of 
 this as recommended by Stiles are as follows: 
 
 Lambs 4 to 12 months old 2 to 4 ounces 
 
 Yearling sheep and above 3 to 5 ounces 
 
 Calves 3 to 8 months old 5 to 10 ounces 
 
 Yearling steers 1 pint 
 
 Two-3' ear-olds and above "... 1 quart 
 
 If a good qualitA' of coal-tar creosote is used, good results may l)e 
 obtained from a single dose of this one per cent, solution. 
 
 Other remedies, such as lysol and arsenic, have been recommended 
 by various authors, but probably the most effectual will come within 
 those which have been particularly mentioned. 
 
 The treatment should be administered to the entire herd, since an- 
 imals which may be but lightly infested will remain a source of reinfec- 
 tion to others. 
 
 The general condition of the animals should be built up and main- 
 tained by a generous supply of nourishing food and thoy should receive 
 a plentiful supply of salt. 
 
CHAPTER XXIII 
 NEMATODA. SUBFAMILY III. STRONGYLIN^ 
 
 Worms of the Large and Small Intestines; Other Strongyles 
 
 These worms are parasitic in the digestive tract, rarely in the respi- 
 ratory organs. The buccal capsule is present. The bursa of the male 
 is well developed and has one or two dorsal rays and two lateral ray 
 systems of six rays each. There are two spicules. The vulva of the 
 female is usually posterior to the middle of the body, but may be anterior 
 to the middle. There are two ovaries. 
 
 The eggs are segmented at the time they are deposited. The embryos 
 are rhabditiform. The development, so far as known, is direct. In 
 some forms the development is complex, involving a nodular phase or 
 larval migration. 
 
 Based mainly upon the formation of the bursal rays and the location 
 of the vulva, the Strongylinse have been grouped by Railliet and Henry 
 into five tribes, as follows : 
 
 Tribe I. OEsophagostomese 
 
 Tribe II. Strongyleae (Ankylostomese) 
 
 Tribe III. Bunostomese 
 
 Tribe IV. Cylicostomese 
 
 Tribe V. Syngameae 
 
 I. (Esophagostomeae. Strongyhnae (p. 280). — The bursa of the male 
 has two lateral lobes united by a smaller median lobe. In each lateral 
 lobe there are six rays. The ray of the median lobe divides into two 
 main branches, each of which again divides into two. The vulva of 
 the female is situated a short distance in front of the anus; uteri diver- 
 gent. The tribe includes three genera, as follows : 
 
 Genus I. (Esophagostomum 
 Genus II. Chabertia (Sclerostomum) 
 Genus III. Agriostomum 
 
 II. StrongyleaB. Strongylinse (p. 280). — The ventral and latero- 
 ventral rays of the lateral bursal lobes are close together and parallel. 
 The medio-lateral and postero-lateral rays are not close together and 
 parallel. The dorsal raj^ ends in tridigitate terminations. The vulva 
 of the female is situated in the posterior third of the body; uteri diver- 
 gent. The tribe includes four genera, as follows: 
 
 Genus I. Strongylus 
 
 Genus II. Ankylostoma 
 
 Genus III. Uncinaria 
 
 Genus IV. Characostomum 
 
STROXGYLIX.E] 281 
 
 III. Bunostomeae. Strongylinae (p. 280).— The ventral and latero- 
 ventral rays of the bursal lobes are close together and parallel. The 
 medio-lateral and posterolateral rays are not close together and are 
 not parallel. The dorsal ray ends in a bifurcation. The vulva of the 
 female is situated in the middle of the body or a httle anterior to the 
 middle; uteri divergent. The tribe includes four genera, as follows: 
 
 Genus I. Bunostomum 
 Genus II, Gaigeria 
 Genus III. Bathmostonunn 
 Genus IX. Grammocephalus 
 
 IV. Cylicostomeae. Strongyhnae (p. 280).— The ventral and latero- 
 ventral raj's of the bursal lobes are close together and parallel. The 
 medio-lateral and postero-lateral raj's are not close together and parallel. 
 The dorsal and externo-dorsal rays originate separately. The vulva 
 of the female is situated close to the anus; uteri convergent. The tribe 
 includes four genera, as follows: 
 
 Genus I. Cylicostomum 
 
 Genus II. Q^sophagodontus 
 
 Genus III. Gyalocephalus 
 
 Genus IV. Triodontophorus 
 
 Y. Syngameae. Strongylinse (p. 280). — The bursa is obhquely trun- 
 cated. The anterior and middle rays are cleft, the posterior tridigitate. 
 The vulva of the female is situated in the anterior quarter of the body; 
 uteri divergent. The tribe includes one genus — Syngamus. 
 
 XODULAR StROXGYLOSIS OF THE ShEEP AND GOAT. CEsOPHAGOSTO- 
 
 MIASIS 
 
 1. (Esophagostomum columbianum. Fig. 145. Strongylinse (p. 
 280). — The thickness of the body is nearly uniform over its greater 
 portion; attenuated toward ends. The anterior portion is usually 
 curved in the form of a hook. The cuticle surroimding the mouth is 
 inflated to form a collar which has ahnost the shape of a hemisphere. 
 Six circum-oral papillse penetrate this mouth collar. In front of the 
 middle of the esophagus there is a transverse groove with accompanying 
 cuticular fold extending around the body to the lateral lines. There are 
 two cervical papillae in front of the middle of the esophagus. Posterior 
 to the cervical groove are two lateral membranes which extend well 
 back along the lateral lines. The bursa of the male has two lateral lobes 
 united by a small median lobe. The spicules are 750-850 microns in 
 length, slender and pointed. The ^^lva of the female is naked, trans- 
 versely elongated, and situated a short distance in front of the anus. 
 
 The length of the female is 14-18 mm. (9/16-11 16 of an inch); male, 
 12-15 mm. (1 '2-19 '32 of an inch). 
 
28^2 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. 145. — -ffisophagostomum columbianum; male 
 at left, female at right. * Vulva. x5. (After Ran- 
 som, Bull. No. 127, Bureau An. Ind., U. S. Dept. 
 Agr.). 
 
 The eggs are oval, 65-75 microns in Fig. 146. 
 length by 40-45 microns in breadth, "'"'^i^^""^- 
 
 ffisophagostomum col- 
 Anterior extremity, 
 ventral view, — enlarged: c. g., cer- 
 
 Segmentation occurs while thej^ are within vical groove; c. p., cervical papilla; 
 
 the uterus. ^^•' esophagus; int., intestine; 1. m. , 
 
 mi i- 1 1 ^r>^ • lateral membrane; 1. p., lateral cir- 
 
 The freed embiyos measure 230 mi- eumoral papilla; m. c, mouth collar; 
 
 crons in length. n. r., nerve ring. (After Ransom, 
 
 Parasitic in the large intestine of the ?"ii- i^o- 127, Bureau An. Ind.. 
 
 , , ^ ^ U. S. Dept. Agr.). 
 
 sheep and goat. 
 
 2. CEsophagostomum venulosum. Fig. 148. Strongylina? (p. 280). 
 
 kJ^ — The thickness of the body is nearly uniform over its greater portion, 
 
 ' \.--' attenuated toward ends. The anterior end is usually straight. The 
 
 ^J^ height of the cuticular collar about the mouth is about one-third of its 
 
 diameter. The cuticle of the neck is inflated between the mouth collar 
 
 and the cervical groove. The lateral membranes extend well back but 
 
 .are very narrow. The bursa of the male has two lateral lobes united by a 
 
 small median lobe. The spicules are 1.1-1.5 mm. long. The vulva of 
 
 the female is naked and located just in front of the anus. From a short 
 
 distance in front of the vulva the body tapers, terminating in a sharply 
 
 pointed tip. 
 
 The female is 18-24 mm. (23/32-15/16 of an inch) in length; male, 
 12-16 mm. (15/32-5/8 of an inch). 
 
 The eggs are oval, 90 microns in length by 55 microns in breadth. 
 
STRONGYLIN^ 
 
 283 
 
 Fig. 147. — CEsophago.sto- 
 mum columbianum. En- 
 larged bursa of male viewed 
 from right side: d, dorsal 
 
 e. 1., extenio-lateral 
 1. v., latero-ventral 
 m. 1., medio-lateral 
 p. 1., postero-lateral 
 V. v., ventro-ventral 
 (After Ran.som, Bull. 
 
 No. 127, Bureau An. Ind., 
 
 U. S. Dept. Agr.). 
 
 raj'; 
 ray; 
 ray; 
 ray; 
 ray; 
 ray. 
 
 Fig. 150. 
 
 Fig. 148.— (Esopha- 
 gostomum venulosum ; 
 male at right, female 
 at left. * Vulva. x5. 
 (After Ransom, Bull. 
 No. 127, Bureau An. 
 Ind., U. S. Dept. Agr.). 
 
 Fig. 150. — GEsopha- 
 gostomum venulosum. 
 Enlarged bursa of male 
 viewed from right side: 
 d., dorsal ray; e. d., ex- 
 tcrno-dorsal ray; e. 1., 
 oxterno-lateral ray; m. 
 1., medio-lateral ray; 
 p. 1., postero-lateral ray; 
 sp., spicules; v. v., ven- 
 tro-ventral ray. (After 
 Ransom, Bull. No. 127. 
 Bureau An. Ind., U. S. 
 Dept. Agr.). 
 
 Fig. 149. — CEsopha- 
 gostomum venulosum. 
 Anterior portion of 
 body — enlarged, ventral 
 view: c. g., cervical 
 groove; c. i, cervical in- 
 flation; c. p., cervical 
 papilla; es., esophagus; 
 int., intestine; 1. m., 
 lateral membrane; 1. p., 
 lateral circumoral pa- 
 pilla; m. c, mouth col- 
 lar; n. r., ners'e ring. 
 (After Ransom, Bull. 
 No. 127, Bureau An. 
 Ind., U. S. Dept. Agr.) 
 
 Parasitic in the large intestine, more rarely in the small intestine, of 
 the sheep and goat. The species has been collected in Europe and in the 
 United States. It is much less common in this country than (Esophagos- 
 tomum columbianum. 
 
 Occurrence and Development. — Nodular disease of the intestines 
 of sheep caused by (Esophagosotomwn cohimhianum is common in the 
 
284 PARASITES OF THE DOMESTIC ANIMALS 
 
 United States. The nodules are due to the larvae which live embedded in 
 the connective tissue of the submocosa, to which they at once penetrate 
 after being taken up by the host. According to Marmotel, after six to 
 seven months of development in this location, they pass to the intes- 
 tinal lumen where they become sexually mature and the female, after cop- 
 ulation, deposits her eggs. The eggs pass from the host animal with the 
 feces and promptly hatch if they meet with favorable conditions of heat 
 and moisture. The further development outside of a host is not known. 
 
 Natural infection probably takes place by food and water from wet 
 marshy pastures. If it occurs during August and September the larvae 
 will pass from the nodules into the intestinal lumen during March and 
 April, here attaining maturity and copulating in July and August. 
 
 Post-mortem Appearance. — The nodules are most commonly found 
 in the wall of the cecum and colon, but they may occur in the small 
 intestine and at times on the liver and other abdominal organs. They 
 may be isolated, but are frequently massed in hundreds and thousands. 
 In size they vary from that of a pinhead to that of a pea, or they maj^ 
 be considerably larger. Their color varies from blackish in the smaller 
 ones to grayish white in the larger. The connective tissue capsule of 
 the nodule is thick, and, as the nodule increases in size, it becomes filled 
 with a greenish cheesy or purulent material, later becoming calcareous. 
 Only the younger noclules contain the larvae. 
 
 Symptoms. — Light infestations, with the presence of a few nodules, 
 are not, as a rule, accompanied by perceptible symptoms, the condition 
 in such cases being observed only after slaughtering. Relative to their 
 degree, heavier invasions may be accompanied by diarrhea without a 
 considerable loss of condition, or the diarrhea may be im controllable and 
 accompanied by progressive emaciation and anaemia. Such cases usually 
 terminate fatally after a course of two or three months, the animal 
 succumbing in a state of coma. The effect of the invasion will depend 
 considerably upon the age and vitality of the animals infested. 
 
 Importance. — The fact that many slaughtered sheep that were ap- 
 parently perfectly healthy show these nodules tends to lead to the im- 
 pression that they are of little importance and has perhaps caused them 
 to be overlooked as a primary cause of death. Cases of nodular disease 
 submitted to the laboratory of the Pennsylvania Bureau of Ani- 
 mal Industry indicate that the disease may assume an enzootic char- 
 acter of severe type occasioning numerous losses. Usually where 
 there is high mortality there is heavy infestation with large areas of 
 massed nodules, though there are several factors which render this un- 
 necessary to a fatal termination. Lighter invasions may have this 
 result when by worms with a relatively high degree of virulence; when 
 the invaded animal has a low degree of resistance, or when other worms 
 are present to contribute to the morbid effect. Furthermore, these 
 
STRONGYLTX.E 285 
 
 worms may infect the blood and lymph with organisms which cause 
 other diseases through acting as direct carriers in penetrating the in- 
 testinal wall, or by the wounds which they create affording portals of 
 entrance. In such cases a comparatively slight infestation with ffisopha- 
 gostomum would be sufficient for what might prove a fatal secondary 
 effect. 
 
 Treatment. — Xo effective curative treatment is known. Preventive 
 measures consist in keeping the sheep from low wet areas. Where the 
 disease is prevalent, lambs may be protected from serious infestation 
 by placing them in a dry uncontaminated lot and feeding and watering 
 them from racks and troughs sufficiently elevated that the contents 
 cannot be soiled by droppings from the nursing ewes. 
 
 Nodular Strongylosis of Cattle. Q^soPHAGOsTO\nAsis 
 
 CEsophagostomum radiatum «E. inflatum). Fig. 151. Stron- 
 g3'linse (p. 280). — The thickness of the body is nearh' uniform over its 
 greater portion; attenuated toward ends. The anterior portion is 
 usually curved in the form of a hook. The cuticular inflation about the 
 mouth (mouth collar) is disk-like, its height a little more than one- 
 fourth of its diameter. The mouth capsule is bordered by a circle of 
 numerous small triangular denticles. The cervical groove and fold are 
 well developed and the cuticle between it and the mouth collar is in- 
 flated. This inflation has a slight constriction at about one-third of the 
 distance from the cervical groove to the mouth collar. The lateral 
 membranes begin at the cervical groove and extend well back along the 
 bod}^; near their beginning are two cervical papillae. The bursa of the 
 male has two lateral lobes united by a small median lobe; spicules 700- 
 800 microns in length. The vulva of the female is transversely elongated 
 upon an eminence located just in front of the anus. From the vulva the 
 body i-apidly tapers, terminating in a tip which is usualh' somewhat 
 bent in a ventral direction. 
 
 The female is 16-20 mm. (5/8-3/4 of an inch) in length; male, 14-16 
 mm. (9/16-5/8 of an inch). 
 
 The eggs are oval, 75-80 microns in length by 38-43 microns in 
 breadth. Their segmentation occurs within the body of the female. 
 
 Parasitic in the small and large intestines of cattle. 
 
 While the nodular larval stage of CEsophagostomum columhianum of 
 sheep is usually found in the large intestine, that of CEsophagostomum 
 radiatum of cattle is often found in the small intestine, the nodules 
 usually occurring in the terminal portion with involvement of the region 
 of the ileo-cecal valve and the cecmu. 
 
 In other respects what has been said as to nodular disease of sheep 
 will, in its essentials, apply to that of cattle. 
 
28fi 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. 151. — ffisophagostomum 
 radiatum; male at right, female 
 at left. * Vulva. x5. (After Ran- 
 som, Bull. No. 127, Bureau An. 
 Ind., U. S. Dept. Agr.). 
 
 Fig. 152. — CEsophagostomum 
 radiatum. Enlarged anterior por- 
 tion of bodj% ventral view: c. a ., 
 annular groove surrounding cervical 
 inflation of cuticle; c. g., cervical 
 groove; c. i., cervical inflation; c. p., 
 cervical papilla; e. p., excretory pore; 
 es., esophagus; int., intestine; 1. m., 
 lateral membrane; m. c, mouth 
 collar; n. r., nerve ring. (After Ran- 
 som, Bull. No. 127, Bureau An. Ind., 
 U. S. Dept. Agr.). 
 
 Fig. 153. — ffisophagostomum radiatum. Enlarged 
 bursa of male, viewed from left side: d., dorsal ray; 
 d. h., dorsal projection of trunk of lateral rays at base 
 of postero-lateral ray; e. d., externo-dorsal ray; e. 1., 
 externo-lateral ray; 1. t., trunk of lateral rays; 1. v., 
 latero-ventral ray; m. 1., medio-lateral ray; p. 1., postero- 
 lateral ray; t. d., terminal branch of dorsal ray; v. v., 
 ventro-ventral ray. (After Ransom, Bull. No 127, Bu- 
 reau An. Ind., U. S. Dept. Agr.). 
 
STRONGYLIN.E 
 
 287 
 
 Nodular Stroxgylosis of the Hog. (Esophagostomiasis 
 
 CEsophagostomum subulatum (CE. dentatum). Strongylinfie (p. 
 280). — The body is straight and attenuated at both (wtreniities. The 
 circular mouth is surrounded by a horny ring furnished with a crown of 
 converging bristles. Upon a cutaneous ridge surrounding the crown of 
 bristles are six papillae. There are no lateral membranes. The bursa of 
 the male has two lateral lobes united by a small median lobe; spicules 
 slender. The vulva of the female is just in front of the anus and is sur- 
 rounded by a prominent ring. 
 
 The female is 12-15 nmi. (1/2-9/16 of an inch) in length; male, 8-12 
 mm. (5/16-1/2 an inch). 
 
 The eggs are oval, 60-80 microns in length by 35-45 microns in 
 breadth. 
 
 This species is found in submucous nodules and in the lumen of the 
 large intestine of the hog. Considerable numbers may be present with- 
 out causing serious disturb- 
 ance. If the infestation is 
 unusually heavy — especially 
 if associated with the thorn- 
 headed worm — there may be 
 diarrhea, loss of appetite, 
 and general unthrift. Such 
 cases may be given treatment 
 as reconnnended for other 
 roundworms of the intestines 
 of the hog. 
 
 Strongylosis of the Large 
 
 IXTESTINE OF THE ShEEP 
 
 AND Goat 
 
 Chabertia ovina ( Sclero- 
 stomum hypostomum ) . Fig. 
 154. Strongylina^ (p. 280).— 
 The body is almost uniform 
 in thickness. The head is 
 slightly globular and is ob- 
 liquely ti'uncated anteriorly, 
 the mouth facing antero-ventrally. The buccal capsule is large; l)order 
 of mouth armed with a double crown of small triangular denticles. Lo- 
 cated ventrally, just in front of the excretory pore, is a short transverse 
 cervical gi-oove. The bursa of the male is short and has an obliquely 
 cut-off appearance; spicules long and slender. The vulva of the female 
 
 Fiu. 1.54. — Chabertia oviiia; male at right, female 
 at left. * Vulva, xo. (After Ransom, Bull. No. 
 127, Bureau An. Ind., U. S. Dept. Agr.). 
 
288 PARASITES OF THE DOMESTIC ANIMALS 
 
 is situated a little in front of the anus. From in front of the vulva the 
 body gradually attenuates, the tail terminating behind the anus in a 
 sharply pointed tip which is bent dorsally. 
 
 The female is 17-20 mm. (11/16-3/4 of an inch) in length; male, 13- 
 14 mm. (1/2 an inch). 
 
 The eggs are oval, 90-100 microns in length by 50 microns in breadth. 
 They are segmented within the body of the female. The eggs have 
 similar characters to those of other sclerostomes, and it is probable that 
 the evolution external to a host is the same. 
 
 Occurrence. — Strongylosis of the large intestine of sheep due to this 
 species is probably more prevalent in Europe than in the United States. 
 In reference to the species, Hutyra and Marek state that it is often 
 found in the colon of sheep, goats, and deer, inducing in some cases 
 intestinal hemorrhage and diarrhea followed by anaemia and emaciation 
 which may cause considerable loss among the young animals. 
 
 Neveu-Lemaire speaks of strongylosis of the large intestine of sheep 
 as at times ravaging certain flocks in the form of an epizootic. 
 
 Ransom, in United States Bureau of Animal Industry, Bulletin No. 127 
 (1911), refers to Chahertia ovina as follows: "This species appears to be 
 comparatively harmless. Its food consists of the vegetable material in 
 the contents of the large intestine. The buccal capsule is commonly 
 found filled with such material." 
 
 Strongylosis of the Intestines of the Horse. Sclerostomiasis 
 
 1. Strongylus equinus (St. armatus; Sclerostomum equinum). 
 
 Fig. 155. Strongylinie (p. 280). — The body is straight, rigid, and finely 
 
 striated transversely; color gray or grayish brown, or 
 
 ^ r\ ^^ ^^^y ^-*^ shaded with red according to the amount 
 
 i 1/ o of ingested blood. The mouth is distended by several 
 
 chitinous rings the innermost of which are provided 
 with an armature of fine teeth, while the outermost 
 have six papillae. The buccal capsule has three teeth 
 at its base. The bursa of the male has two lateral 
 lobes between which is a smaller median lobe ; spicules 
 long and slender. The vulva of the female is located 
 near the posterior third of the body. The tail is obtuse. 
 The length of the female varies from 20-55 mm. (3/4 
 to 2 3/16 inches) ; that of the male from 18 to 35 mm. 
 
 T. 1.. .. (11/16 to 1 3/8 inches). 
 
 Fig. 155— Stron- ^ ' ' i „o • • i -i-i, i r < • 
 
 gylus equinus; male The eggs are oval, 92 microns m length by 54 mi- 
 at right, female at crons in breadth. Segmentation commences at the 
 left, — natural size ^- £ ^j j^. ^leposition. The hatched embryos meas- 
 
 (drawn from speci- . • i i 
 
 mens). ure 340-500 microns in length. 
 
STRONGYLIX.E 289 
 
 2. Strongylus edentatus (Sclerostomum edentatum). Strongylinae 
 (p. 280).— The head is globular. The Ixiccal capsule is goblet-like, and 
 teeth are absent. The bursa of the male is similar to that of Strongylus 
 equinus. The vulva of the female is near the posterior third of the body. 
 
 The female is 33-36 mm. (1 5/16-1 7 16 inches) in length; male, 23- 
 25 mm. (7/8-1 inch). 
 
 The eggs are oval and in dimensions about as in Stro7igylus equinus. 
 
 As adults these worms are parasitic in the cecum and colon of the 
 horse; as larvie in the abdominal and thoracic organs. 
 
 3. Strongylus vulgaris (Sclerostomum vulgare). Strongylinse (p. 
 280). — The buccal capsule is shallow and has a single tooth at its base, 
 prominent projections causing the tooth to appear as two. The bursa 
 of the male has three lobes, the median one overlapped by the two 
 lateral. The vulva of the female is near the posterior third of the body. 
 
 The female is 24 mm. (15/16 of an inch) in length; male, 15 mm. 
 (5/8 of an inch). 
 
 The eggs are as in the preceding species. 
 
 Parasitic as adults in the cecum and colon and in immature stages in 
 the mesenteric blood vessels of the horse. 
 
 4. Cylicostomum tetracanthum (Sclerostomum tetracanthum). 
 Strongylime (p. 280). — A white or reddish wiiitc worm, attenuated 
 antcriorl}', the mouth surrounded l)y a cuticular fold. The buccal 
 capsule is armed Avith a crown of triangular teeth. The vulva of the 
 female is just anterior to the anus. 
 
 The female is 10-18 mm. (3/8-11, 16 of an inch) in length; male, 8- 
 12 mm. (5/16-1/2 an inch). 
 
 The eggs are oval, 100 microns in length by 47 microns in breadth. 
 
 Parasitic in the cecum and colon of the horse. 
 
 Development. — The worms causing sclerostomiasis of the horse 
 were formerly grouped under the name Strongylus armafiis. According 
 to Looss (1902) it is the innnature stages of the species Strongylus vul- 
 garis (Looss, 1900) which are concerned in the production of verminous 
 aneurysms in the mesenteric arteries of the horse. M. Neveu-Lemaire 
 (Parasitologic des Animaux Domestiques, 1912) describes the worm 
 responsible for these lesions under the name Strongylus equinus. 
 
 This worm when mature lives in the cecum and colon where it firmly 
 attaches to the mucosa by its Ijuccal armature. In its agamous state it is 
 found in subnuicous cysts of these organs and in aneurysms of the 
 mesenteric artery. According to the investigations of Railliet the eggs, 
 which are deposited in the cecum and colon and expelled with the feces, 
 may develop in a few days if they meet with moisture at a temperature 
 of 12° to 25° C. (53° to 77° F.). The hatched embryos, if they continue 
 amid favorable conditions, grow, molt, and acquire a great vitality. It 
 is at this stage that they are ingested by the equine host with the drink- 
 
 l/ 
 
290 PARASITES OF THE DOMESTIC ANIMALS 
 
 ing water or perhaps with green forage. Reaching the intestines, they 
 penetrate the mucosa from which probably the majority of them reach 
 the circulatory system where the}^ become lodged in the visceral arteries, 
 as the trunk of the great mesenteric. After a variable time in this 
 location they again enter the blood stream and, reaching the cecum, 
 oecome encysted in the submocosa where their development proceeds. 
 Within the cyst they possess a buccal capsule and a caudal bursa, but 
 the generative organs are not as yet developed. 
 
 Finally they pass to the lumen of the bowel where they attach to the 
 mucosa and acquire all the characters of the adult. Copulation then 
 takes place, the eggs are deposited, and a new generation repeats the cycle. 
 
 Symptoms. — The symptoms brought about by the presence of these 
 worms — a condition generally known under the name of sclerostomiasis — 
 are not characteristic and vary according to the location of the parasites. 
 The presence of the adults upon the mucosa of the cecum, even in con- 
 siderable numbers, rarely .causes serious disturbance, diarrhea and 
 occasional attacks of colic resulting in exceptional cases. 
 
 Sclerostomiasis produced by the larvae is of a much more serious 
 nature. Their most frequent location in this state is in the large arteries 
 where they bring about the formation of verminous aneurysms, usually 
 at the origin of the great mesenteric. Fragments of the clot within the 
 aneurysm may be carried by the blood to form emboli in the arterial 
 ramifications leading to the intestines, that portion of the intestine 
 supplied by an artery in which an embolus is lodged being deprived of its 
 normal supply of blood. As a result there is suspension of secretion and 
 peristaltic movements in this section, the walls of a portion of which 
 become dark and tumified with the presence of hemorrhagic infarct. 
 One or more portions of the intestine may be thus affected, the arrested 
 contents fermenting and producing an abundance of gas, while in the 
 healthy portions of the intestines there are abnormally energetic con- 
 tractions which cause a severe enteralgia and may lead to invagination, 
 displacement, and even rupture. The rupture may be of the paralyzed 
 intestine, or it may be of the stomach or diaphragm, brought about by 
 the accumulation of gas generated from the stagnated and fermenting 
 intestinal contents, the violent movements of the animal often con- 
 tributing toward this termination. 
 
 Post-mortem Appearance. — The adult worms are fixed to the 
 mucosa, usually that of the cecum, where they nourish fi-om the blood of 
 their host and produce at their point of attachment a small dark prom- 
 inence. Immature worms may be found in submucous nodules of the 
 cecum, or of both the cecum and colon. These nodules vary in size from 
 that of a pinhead to that of a hazelnut and contain a small quantity of 
 pus or sero-purulent material in which the worm, if present, is rolled up. 
 The worms escape from the nodules by a central orifice to the lumen of 
 
STRONGYLIN^ 291 
 
 the intestine where they attach and are sexually mature, the sexes often 
 being found coupled in this location. Before their intranodular existence 
 the larval worms live in the blood-vascular system, having gained this 
 location through the intestinal wall innnediately after their ingestion. 
 It is at this stage that they produce the aneurysms as found in the vis- 
 ceral trunks of the posterior aorta. These aneurysms are usually some- 
 what elongate, with tunica media much thickened, and with fibrin 
 deposit upon the iiitima, on which a number of reddish tinted strongyls 
 are likely to be fixed. The aneurysm may, however, be entirely free 
 from worms, in which case they have probably passed with the blood- 
 current to the intestinal wall. 
 
 Where death has occurred from thrombo-embolic colic due to ver- 
 minous aneurysm, the most prominent alterations found are those which 
 have already been described in reference to this complication. The 
 intestines are usuallj' much distended bj^ gas, or, if rupture has occurred, 
 this, with more or less intestinal contents, will be in the abdominal 
 cavity. Extensive darkly discolored areas are usually observed in the 
 intestinal walls, and there are likely to be evidences of degeneration if 
 the course of the attack has been sufficiently prolonged. Owing to the 
 great engorgment of the mesenteric vessels, it is often difficult, without 
 the most searching examination, to discover the location of the embolus. 
 Rarely the immediate cause of death may be found to have been due to 
 rupture of the aneurysm and internal hemorrhage. 
 
 Treatment. — For the strongyles in the intestine the same treatment 
 may be employed as has been reconnncnded for the ascarids, though, 
 owing to the firm attachment of the former to the mucosa, their expul- 
 sion is difficult. Oil of turpentine has been recommended as particu- 
 larly valuable. It may be given in two to four ounce doses in oil. 
 
 In prophylaxis clean water is a main factor. This should be filtered or 
 quite pure and free from drainage contamination. , ^^ 
 
 Strongylosis of the Intestine of the Dog and Cat. 
 Ankylostomiasis 
 
 1. Ankylostoma canina (Dochmius trigonocephalus; Uncinaria tri- 
 gonocephala; U. canina). Fig. 156. 8trongylinae (p. 280). — The body 
 is whitish in color and slender; slightly enlarged at the anterior extremity. 
 On the ventral surface of the buccal capsule are two chitinous plates, 
 each having three recurving teeth. The bursa of the male is three-lobed, 
 two large lateral and a small median. There are two long and slender 
 spicules. The vulva of the female is situated near the posterior third 
 of the body. 
 
 The female is 10-20 mm. (3/8-3 4 of an inch) in length; male, 9-12 
 mm. (11/32-1/2 an inch). 
 
292 PARASITES OF THE DOMESTIC ANIMALS 
 
 The eggs are oval, 74-84 microns in length bj^ 48-54 microns in 
 breadth. 
 
 Parasitic in the small intestine of the clog and cat. 
 
 2. Uncinaria stenocephala (Dochmius stenocephalus ; Ankylosto- 
 mum stenocephalum) . Strongylinse (p. 280). — The body is very 
 slender, and the anterior extremit}'- is much narrower than in the pre- 
 ceding species, being somewhat attenuated. The buccal 
 capsule is conical and has two pairs of small teeth on the 
 ventral side. The bursa of the male is similar to that of the 
 preceding species. The vulva of the female is situated near 
 y the posterior third of the body. 
 
 Fig. 156— The female is 8-10 mm. (5/16-3/8 of an inch) in length; 
 Ankylostoma male, 6-8 mm. (1/4-5/16 of an inch). 
 
 malJ'atHght, ^^^ ^^gs are oval, 63-76 microns in length by 32-38 
 female at left microns in breadth. 
 
 (drawn from Parasitic in the small intestine of the dog. There is no 
 specimens), authentic report of its occurrence in this country. 
 
 Occurrence and Development. — Ankylostomiasis (dochmiasis; un- 
 cinariasis) is a severe affection of dogs caused by the presence of Ankylo- 
 stoma canina. The condition is analogous to ankylostomiasis or hook- 
 worm chsease of man, caused by the species Anktjlostoma duodenale. 
 
 The worms fix themselves to the mucosa of the small intestine where 
 they extract blood. Hunting dogs confined in kennels are those which 
 most often suffer, especially if their quarters are damp. Cats are not 
 often affected. 
 
 The development of the parasite is rapid. The eggs are segmented 
 within the body of the female and, when expelled to moist earth, develop 
 embryos in three to six days. These become encysted and, probably 
 through the medium of contaminated water, reach the intestine of the 
 dog where they mature. 
 
 Post-morten Appearance. — Necropsies upon dogs which have died 
 in the advanced stages of ankylostomiasis show the alterations of 
 anaemia and cachexia. The mucosa of the small intestine is thickened 
 and marked by numerous hemorrhagic areas. Small ulcerations are 
 present as a result of the irritation from the attachment of the worms, 
 and the intestinal contents may be hemorrhagic. 
 
 Symptoms. — The symptoms are those of anaemia, debility, and 
 emaciation. There is depression and indifference, and hunting dogs 
 lose their zest. The skin becomes dry and scaly and the coat harsh 
 and lusterless. The legs swell intermittently at first, later the edema 
 is greater in extent and becomes permanent. There is a muco-purulent 
 discharge from the nostrils and this may be streaked with blood. Later 
 there may be attacks of nasal hemorrhage. There is at first constipation, 
 later a dysenteric diarrhea. Emaciation and general debility progress, 
 
STROXGYLIX.E 
 
 293 
 
 and the SAnnptoms are finalh' terminated bj- death in a state of coma or 
 it may be in conAiilsions. 
 
 Treatment. — As the disease usually attacks hunting packs in ken- 
 nels, and there is constant reinfection, treatment is, as a rule, not suc- 
 cessful. It is most important that care be exercised as to cleanliness of 
 the kennel. Where possible, the sick should be removed to other quar- 
 ters. Water and food should be given from buckets or troughs which 
 are thoroughly flushed out after each meal, and the j-ards should be 
 kept free from pools and nmd. As medicinal treatment, the usual 
 vermifuges reconunended for dogs may be tried. 
 
 Other Strongylinae. — Two other strongylines occasionalh' found in 
 sheep and cattle may be mentioned. 
 
 1. Bunostomum trigonocephalum (Uncinaria cernua; Dochmius 
 cernuus). StrongyliniP (p. 280). — Yellowish or reddish in color; 
 cuticle transversely striated. The 
 buccal capsule has a long dorsal tooth 
 projecting forward. The mouth is 
 surrounded by six papillae; cephalic 
 extremity curved dorsall}-. The 
 vulva of the female is near the middle 
 of the body. 
 
 The female is 20-28 mm. (3/4-1 1 '8 
 inch) in length; male, 15-18 mm. 
 (5/8-11/16 of an inch). 
 
 Para.sitic in the small intestine of 
 rimiinants, particularh' sheep and 
 goats. 
 
 2. Bunostomum phlebotomum 
 (Uncinaria radiata; Dochmius radi- 
 atus). Fig. 157. Strongylime (p. 
 280).— Dark in color. The dorsal 
 buccal tooth is short; two ventral 
 buccal teeth and two subventral 
 buccal teeth or lancets. The cephalic 
 extremity is curved. 
 
 The female is 24-28 mm. (15/16-1 1/8 inch) in length; male, 10-16 mm. 
 (3/8-5/8 of an inch). 
 Parasitic in the small intestine of cattle. 
 
 Fig. 157. — Bunostomum phlebotomum; 
 male at right, female at left. * Vulva. 
 x5. (After Ransom, Bull. No. 127, Bu- 
 reau An. Ind., U. S. Dept. Agr.). 
 
 Teacheal Strongylosis of Chickens. Syngamosis 
 
 Tm-o species of strongylines invade the trachea and bronchi of fowl, — 
 Syugamus trachealis and Syn. bronchialis. The last named is somewhat 
 the larger and inhabits the air passages of water fowl. 
 
294 PARASITES OF THE DOMESTIC ANIMALS 
 
 Syngamus. Strongyliiifie (p. 280).^ — Members of this genus have a 
 slender bod}' of reddish color. The month is surrounded by a strong 
 chitinous capsule. The female is much larger than the male and is 
 usually found with the male firmly attached at the vulva which is sit- 
 uated near the anterior quarter of the body. This permanent coupling 
 gives to the pair a forked appearance from which the worm has derived 
 its common name of "forked worm" (Fig. 158). The attachment of 
 male and female is less constant with the species Syn. hronchialis. 
 
 The female of Syngamus trachealis is 5-20 mm. (3/16-3/4) of an inch 
 in length; male, 2-6 mm. (1/16-1/4 of an inch). 
 
 The eggs are elliptical, measuring 85 microns in length by 50 microns 
 in breadth. In the uterus of the female they undergo a variable degree 
 of development, containing when freed a segmented mass or 
 a developed embryo. The eggs are not laid but escape from 
 the body by its rupture, which ordinarily occurs from decom- 
 position, though, according to Railliet, eggs contained in 
 the vagina may pass through the \ailva and from under the 
 bursa of the male to the outside. 
 
 Occurrence and Development. — The condition produced 
 
 Fig. 158. in fowl by syngami is commonly known in England and the 
 
 —Syngamus United States as gapes. It is widely prevalent, practically 
 
 male (at- all of our domestic birds and many wild birds, especially 
 
 tached at those in captivity, suffering from it. 
 
 malef " ^^' ^ peculiar feature in the evolution of Syngamus trachealis 
 is the fact already noted that, due to the covering of the 
 vulva by the permanent attachment of the male, the eggs cannot be 
 extruded and are only liberated by the rupture or disintegration of the 
 mother worm. This may occur within the air passages or after the 
 worm has been expelled. If the eggs meet with water or moist earth 
 the embryos develop and are hatched in seven to forty da3'S according 
 to temperature. Birds may become infested by ingesting eggs or em- 
 bryos, often by eating the worms expelled by infested members of the 
 flock. From the digestive tract the larvse migrate to the air passages 
 where they mature. 
 
 Lesions. — The worms are generally found covered with mucus and 
 in greatest number near the division of the trachea into bronchi. The 
 mucosa, to which they are firmly fixed by their buccal capsule, exhibits 
 at each point of attachment a small purulent tumor, or there may have 
 developed an abscess sufficiently large to obstruct the trachea. The 
 number of coupled worms present may be three or four or twenty to 
 thirt}'-, the smaller numbers being quite sufficient to cause death by 
 asphyxiation, though this will be influenced somewhat by age and the 
 diameter of the trachea. 
 
 Symptoms. — Young birds suffer most from syngamosis, those in 
 
STRONGYLIX.E 295 
 
 good condition being equally susceptible with others. A typical symp- 
 tom of the affection is a peculiar stretching of the neck accompanied 
 by a yawn-like opening of the beak from which movement the disease 
 derives its name "gapes." The birds repeatedly shake their heads, 
 sneeze, and expel tenacious masses of mucus which may contain one 
 or more pairs of the worms. The appetite, at first voracious, diminishes, 
 and the birds become dull and inactive with feathers erect and lusterless. 
 
 Emaciation progresses, the mouth is filled with frothy saliva, respira- 
 tion becomes increasingly difficult, and the animal dies from exhaustion, 
 or it raaj' be from asphyxia before such advanced symptoms are reached. 
 Recovery is rare in young l)irds. Older ones sometimes survive if the 
 infestation is light. 
 
 Treatment. — A method of treatment commonh' practiced is to strip 
 a feather of its barbules to within a short distance of its tip and inserting 
 this into the trachea with a rotary movement, attempt to detach and 
 elevate the worms. Only such worms as are not firmly fixed to the 
 mucosa are removed by this process and, in view of the danger of its 
 causing suffocation, it is a questiona])le procedure unless as an urgent 
 palliative measure. 
 
 A better treatment is to give with the food certain substances of strong 
 odor eliminated in the respiratory passages and having a deleterious 
 effect upon the parasites. As such agents garlic and asafetida have 
 been employed with success. According to Neumann, Megnin has had 
 good results with a mixture of equal parts of asafetida and powdered 
 gentian root incorporated in a cake and given in the proportion of eight 
 grains per bird each day. 
 
 Another method reconnnended is the injection into the trachea of 
 about fifteen drops of a five to eight per cent, solution of salicylic acid. 
 The injection should be made slowly with a small syringe and canula. 
 
 Fumigations with such agents as sulphurous acid or tobacco smoke, 
 resorted to by some, involve such risk of accident from suffocation as 
 to make their use unadvisable. 
 
 As prevention, affected birds and those apparently health}- should 
 be removed to clean and separate quarters and the infested yards 
 cleaned and sprinkled with a one to one thousand solution of sulphuric 
 acid. The bodies of dead birds are to be buried deeph' or burned. 
 Food and water should be fresh, given from clean utensils, and not per- 
 mitted to stand about. As an aid in prevention the addition of fifteen 
 grains of salicylate of soda to the quart of drinking water has been 
 recommended. 
 
 The Kidney \\'orm of the Hog 
 
 Stephanurus dentatus. StrongyHdse (p. 255). — This worm is at 
 present of somewhat uncertain position in the classification of the 
 
296 PARASITES OF THE DOMESTIC ANIMALS 
 
 strong3des. The body is thick, cyHndrical, and has a mottled appear- 
 ance, due to the intestine and reproductive organs showing through 
 the semi-transparent integument. Both extremities are somewhat 
 blunted; the mouth terminal with six small teeth. The bursa of the male 
 is formed of five tongue-like parts united by a membrane; there is but 
 one spicule. The obtuse caudal extremity of the female is curved; 
 ^^ilva near the middle of the body. 
 
 The length of the female is 30-40 mm. (1 3/16-1 9/16 inch); male, 
 22-30 mm. (7/8-1 3/16 inch). 
 
 Parasitic in fat surrounding abdominal viscera, especially that of the 
 sublumbar region in the vicinitj^ of the kidneys. 
 
 The kidney-worm is found in hogs of the United States — especially 
 those of the South — and in South America, the species being first dis- 
 covered in Brazil. Its presence may cause the formation of cysts up 
 to the size of a pigeon's egg in the adipose tissue, these on incision usually 
 revealing one or two of the worms and a small amount of pus. Rarely 
 the worms penetrate the capsule of the kidney or enter the suprarenals. 
 Indurated fistulous tracts, liver lesions, and peritoneal effusion have 
 been observed as a result of the presence of these parasites, though it 
 may be said of them that they rarely cause perceptible disturbance 
 unless in unusual locations in the abdominal cavity. 
 
 Due to their location, treatment can be of no value. 
 
 FAMILY VL EUSTRONGYLID.E 
 
 EUSTRONGYLOSIS 
 
 This is a condition produced by a giant nematode, — Diocioplujme 
 renale (D. visceralis; Eustrongylus visceralis; Eu. gigas), which is some- 
 times met with in the kidney and peritoneal cavity of dogs and other 
 domestic animals. It has also been reported in man. 
 
 Diodophyme r-enale (Nematoda, p. 217) is of somewhat uncertain 
 position among the nematodes. It has been commonly placed with the 
 family Strongylidae, but it does not conform to all of the characteristics 
 of this family. Neveu-Lemaire describes the genus Eustrongylus under 
 the separate family Eustrongylidse. 
 
 The worm is the largest of all the nematodes, the female attaining 
 a length of one meter (39 inches) and a thickness of a centimeter (3/8 
 of an inch); the males a length of forty centimeters (15 inches). The 
 body is blood-red in color, somewhat thinner toward the anterior ex- 
 tremity than posteriorly. The bursa of the male is collar-like, entire, 
 and without rays. Within its base is located the anus. There is a single 
 slender spicule (Fig. 159). The tail of the female is obtuse. There is a 
 single ovary; vulva near the mouth. 
 
EUSTRONGYLID^ 
 
 297 
 
 The eggs are 64-68 microns in length by 40-44 microns in width. 
 They are brownish in color and have numerous round depressions on 
 their surface. The}^ develop in a moist medium. 
 
 The embryos are tapering at the extremities and about 240 microns 
 in length by 40 microns in breadth. They have a 
 great vitalitj^ and may survive within the eggs for 
 a year or more. 
 
 Attempts at direct infection have been unsuc- 
 cessful. An intermediate host is evidently re- 
 quired, and the fact that the worm is found para- 
 sitic in the seal and otter points to the probability 
 that it lives a portion of its life in a fish. 
 
 The eustrongyle is much more frequent in Car- 
 nivora, especially the dog, than in other animals, 
 but it is rareh' met with. In the Journal of the 
 American Veterinary Medical Association, June, 
 1917, Hall states that from Riley's and his own 
 record of cases reported it appears that this worm 
 has been found at least forty or fifty times in the 
 United States. How and in what form it finds its 
 wa}^ into the body of its host is not known. It is 
 most frequentl}^ found in the pelvis of the kidney 
 where it grows to an enormous size, producing a 
 purulent inflammation from which destruction of 
 the renal tissue follows. Eventually the kidney 
 becomes a mere thick-walled cyst containing a 
 bloody purulent material within which the worm 
 is coiled up. But one kidney is invaded, usually- 
 by a single worm, though in rare cases two have 
 been found in the kidney pelvis. The uninfestcd 
 kidney is usually found to have undergone a com- 
 pensatory hypertrophy. The worm has been 
 met with in other parts of the urinary organs, as 
 in a part or the whole of the lu'eter and in the 
 bladder. Where it is found outside of the urinary 
 organs, as in the peritoneal cavity', it is probable 
 that it did not reach such location until after 
 primary development in the urinary passages. 
 
 Symptoms. — The symptoms are not characteristic and in some cases 
 may not be observed. Horses and cattle especially are said to show 
 little disturbance from the presence of the worm, while dogs, on the 
 other hand, suffer severe pain, are restless, and sometimes exhibit a 
 lateral curvature of the vertebral column, the concavity corresponding 
 to the affected side. ^Nlicturation may be painful and with effort, and 
 
 Fig. 1.59.— Diocto- 
 phyme renale; male, — 
 natural size (after Rail- 
 liet). 
 
298 PARASITES OF THE DOMESTIC ANIMALS 
 
 the urine may be purulent and bloody. An exact diagnosis can only 
 be made in the living animal by finding the characteristic eggs of the 
 eustrongyle in the urine. 
 
 In view of the location and size of the worm, treatment is imprac- 
 ticable. 
 
chapter xxiv 
 xe:\iatoda. family vii. trichixellid.e 
 
 Xematoda (p. 217j. 
 
 The nematodes of this faniil}' have a very slender and elongated 
 anterior portion of the body, containing only the esophagus. The pos- 
 terior portion is more or less enlarged and is occupied h)y the intestine 
 and reproductive organs. The mouth is rounded and nude. The anus 
 is terminal or nearly so. The males have a single testis and but one 
 spicule or the spicule may be absent. The females have a single ovary. 
 The vulva is located at the junction of the smaller with the larger por- 
 tion of the bodj'. They are oviparous (Trichuris) or ovoviviparous 
 (Trichinella). 
 
 The worms of this group to be described come under two genera, — 
 Trichuris and Trichinella. Of those but one species, — Trichinella 
 spiralis, is of pathologic importance. 
 
 Trichuris ovis fTrichocephalus affinisj. Fig. IGO. Trichinelhdse 
 (p. 299). — The esophageal portion of the body is very long and slender; 
 the posterior portion, containing the reproductive organs, much thicker. 
 The head is sometimes provided with two transparent wing-like en- 
 largements. The posterior extremity is more or less blunt and rounded. 
 The body is transversely striated. The posterior portion of the body 
 of the male is rolled dorsally in a spiral. The spicule is verj- long, 
 measuring 5-7 mm. (7/32-9/32 of an inch) and terminating in a sharp 
 point. 
 
 The female is 50-70 mm. (2-2 3/4 inches) in length, the esophageal 
 portion constituting about two-thirds of the total length. The male is 
 50-80 mm. (2-3 1/8 inches) in length, the esophageal portion in the 
 same proportion to the total length as in the female. 
 
 The eggs are lemon-.shaped, 70-80 microns long, and have an opercular 
 plug at each end. Development is direct. 
 
 This species is a common para.site in the large intestine of ruminants, 
 particularly the sheep and goat. Leuckart has demonstrated that it 
 develops directly from the egg without intermediate host and without 
 a free hving stage. When the eggs are taken into the intestine of the 
 nmiinant host the embr>'OS are freed and attain their adult development 
 in about sixteen daj's. They are usually found attached firmly to the 
 mucosa, but apparently cause littlo if any trouble. 
 
 Trichuris crenatus ' Trichocephalus crenatus). Trichinellidae (p. 
 299). — The esophageal portion of the body is very slender, the posterior 
 
300 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 Fig. Itil. — Trichuris ovis. Egg. 
 x600. (After Ransom, Bull. No. 127, 
 Bureau An. Ind., U. S. Dept. Agr.). 
 
 Fig. 160, 
 at left. * Vulva, xo 
 tice, Bull. No. 127, 
 Dept. Agr.). 
 
 portion enlarged. The female 
 measures 35-50 mm. (1 3/8-2 
 inches) in length, the anterior 
 slender portion constituting 
 about two-thirds of the total 
 length. The length of the male 
 is 33-40 mm. (1 5/16-1 9/16 
 inch), the anterior part about 
 five-eighths of the total. 
 
 The eggs are 52-56 microns 
 in length. 
 
 The worm lives in the large 
 intestine of domestic and wild 
 hogs. Infestation occurs as in 
 the preceding species. Ap- 
 parently little disturbance is 
 caused by its presence. 
 
 Trichuris depressiusculus 
 ( Trichocephalus depressiuscu- 
 lus). Trichinellidse (p. 299).— 
 The male and female are 45- 
 75 mm. (1 3y^4-3 inches) in 
 length, the slender esophageal 
 portion constituting the ante- 
 Trichuris ovis; male at right, female rior three-quarters. The spe- 
 
 (After Ransom, from Cur- 
 Bureau An. Ind., U. S. 
 
 cies resembles Trichuris ovis of 
 ruminants and Tr. dispar of 
 man. The spicule of the male 
 
 may reach the length of 10 mm. (3/8 of an inch) and terminates in a 
 
 sharp point. 
 
 The eggs are 70-80 microns in length. The development is similar 
 
 to that of the preceding species. 
 
 This parasite inhabits the large intestine, usually the cecum, of the 
 
 dog. Eggs taken up by dogs release their embryos within the digestive 
 
 tract where they attain full development. The worms are often found 
 
TRICHINELLID^ 
 
 301 
 
 in the cecum of clogs suffering from ankylostomiasis, but have an in- 
 significant secondary part to Ankylostoma canina as a cause of this 
 affection. 
 
 Trichinosis 
 
 Trichinella spiralis (Trichina spiralis). Fig. 162. Trichinelhdse 
 (p. 299). — A veiy small worm with bod}' somewhat thicker posteriorly, 
 but without abruptly demarcated fila- g 
 
 mentous anterior as in the Trichurinae. 
 The mouth is round and unarmed. The 
 esophageal portion extends to about one- 
 half of the length of the body, the esoph- 
 agus embedded in a chain of single cells. 
 The portion of the body posterior to the 
 esophageal contains the intestine which 
 ends in a terminal anus. The single 
 testis of the male originates posteriorly- 
 and extends forward to the esophagus 
 where it turns back and becomes the 
 seminal vesicle which terminates at the 
 anal aperture. The cloaca thus formed 
 has on each side of its opening two pro- 
 jections which serve to clasp the female, 
 the cloaca being extmded in copulation. 
 There is no spicule. The single ovary 
 of the female begins posteriorly and, ex- 
 tending forward for a short distance, be- 
 comes the uterus. The vulva is about 
 one-fifth of the length of the body from 
 the anterior end. 
 
 The female is 3-4 mm. (1/8-5/32 of an 
 inch) in length; male, 1.4-1.6 mm. (1/16 
 of an inch). 
 
 The embrs^os are developed within the 
 uterus and are hatched there by breaking 
 through the delicate membrane sur- 
 rounding the egg. From the uterus and 
 vagina they pass from the bod}' of the 
 mother worm through the vulva. The 
 hatched embryos are 100-160 microns 
 long by 9 microns thick, the anterior end 
 somewhat thicker than the posterior. 
 
 Parasitic as adults in the small intestine and as larvae in the muscula 
 ture of hogs, rats, mice, and other mammals, including man. 
 
 Fig. 162. — Trichinella spiralis; 
 male at left, female at right, — 
 much enlarged. 
 
30^ 
 
 PARASITES OF THE DOMESTIC AXi:\L\LS 
 
 Life History. — When flesh containing encapsulated living trichinae 
 is taken into the stomach of a suitable animal, the capsule is digested 
 and they are liberated within eighteen to twenty-four hours. The 
 larvae then enter the small intestine and are sexually mature in two to 
 five daj-s. The females with the males are pressed into the crypts of 
 Lieberkijhn where, a week to ten days after the infection, the female 
 deposits living embryos. There is at first an equal number of males 
 and females in the intestine; later the males gradually disappear, so 
 that ten to fourteen daj's after infection almost all of the worms will be 
 females. These live five to eight weeks, a single female, according to 
 Leuckart, depositing not less than fifteen hundred embryos; according 
 to Braun, the nmnber may reach ten thousand. 
 
 From Lieberktihn's glands the embryos penetrate the mucosa and, 
 reaching the lymphatics, are probably carried to the blood by wa}^ of 
 the thoracic duct. With the blood they are distributed to various parts 
 of the body, passively in greater part, though it is 
 probable that their ultimate lodgment is influenced 
 somewhat by their activity. Embryos deposited by 
 capillary blood in striated muscle with sarcolemma 
 are amid conditions favorable to their further develop- 
 ment. From the capillaries the trichinae force their 
 way through the sarcolemma and into the plasma of 
 the muscle-fiber, where, at first actively motile, they 
 pass to a state of rest and proceed to develop into 
 the larval stage at which, if ingested, they may infect 
 other animals. 
 
 In about three weeks after the occurrence of the 
 infection the larvae in their muscular location have 
 attained a length of eight-tenths to one millimeter, 
 and their growth is completed. At this time they 
 are usual Ij' curved in the form of a sickle, later becom- 
 ing coiled spirally (Fig. 163), from which characteristic 
 they derive their specific name, though they may be 
 found in various looped and curved forms. The an- 
 terior portion of the larva is now the thinner; the pos- 
 terior thicker and rounded at its extremity. 
 As a result of this invasion the muscle-fibers undergo certain changes; 
 the transverse striation is lost, there is degeneration of the sarcoplasm, 
 and the nuclei increase in number and size, each becoming surrounded 
 by a granular mass. The irritation to the surrounding tissues caused 
 by the presence of the parasites results in the formation of cysts which 
 enclose the trichinae and are fulh' developed at the end of the thu'd 
 month. The long axis of the capsule is parallel to that of the muscle- 
 fiber. The capsules are usually oval in shape and more or less drawn 
 
 Fig. 163.— Tri- 
 chinella spiralis. 
 Encysted larva in 
 muscle (after Leuc- 
 kart). 
 
TRICHINELLID^ 303 
 
 out at the i^oles, giving them somewhat the shape of a lemon. Their 
 dimensions vaiy with the thickness of their walls. In general, they 
 are about four-tenths of a millimeter in length by twenty-five one- 
 hundredths of a millimeter in })readth, but their length may be from 
 three-tenths to eight-tenths of a millimeter and their breadth from 
 two-tenths to four-tenths of a millimeter. After the formation of the 
 cysts they are often made more recognizable to the unaided eye by the 
 deposition of fat cells innnediately around their poles. Within each 
 cyst there is usuallj- one, more rarely two or more, larva?. 
 
 Tabular Review of Life History of Trichinella Spiralis 
 
 Mature Womis. — In intestines of hog, rat, etc. Period of 
 I intestinal trichinosis. 
 
 Embrvos. — In intestinal crvpts of same. 
 
 Embryos. — In lymph and blood currents after pene- 
 
 I trating intestinal wall. 
 
 Embryos. — ]\Iigrating within fibers of voluntary mus- 
 
 I cle. Period of muscular trichinosis. 
 
 Encysted Larvae. — ^At rest within voluntary muscle- 
 
 I fibers. 
 
 Larvae. — Freed from C3^sts after ingestion by hog, rat, 
 
 I man, etc. 
 
 Mature Worms. — In intestines of same. 
 
 Degeneration. — After a varj-ing jx'riod of time the trichina cyst 
 undergoes fatty and calcareous degeneration. In the first there api)ear 
 within the cyst cells small fat granules which rapidly increase in number 
 and are soon set free to invade the whole of the C3'st. Later there is a 
 deposition of carbonate and phosphate of lime, the calcification involving 
 the capsule and the tissues of the trichina, though the latter often es- 
 capes the process, and perfectly intact trichinae ma}' be found in cysts 
 entirely calcified and opaque. 
 
 Calcification of the capsule begins about the seventh month after in- 
 fection and is completed in from fifteen to eighteen months, though ex- 
 ceptions give to these periods but a general application. Ostertag 
 states that completely calcified trichina capsules were found in two 
 hogs nine and twelve months old, and, according to the same author, 
 Dammann reported a case in which after eleven years the trichina cap- 
 sules were not completely calcified and contained trichina still capable 
 of producing experimental trichinosis. 
 
 Location. — Encysted trichinae are found in striated muscle in which 
 the fibers have a sarcolemma. Thev are not found in the muscle- 
 
304 PARASITES OF THE DOMESTIC ANIMALS 
 
 fibers of the heart. Certam muscles are pecuharly liable to invasion 
 by the parasites, and these in the order of frequency may be listed as 
 follows, — pillars of the diaphragm, muscles of the larynx and tongue, 
 abdominal and intercostal muscles, psoas muscles, and muscles of the 
 back. They are usually found in greatest number toward the extrem- 
 ities of the muscles in the neighborhood of tendons, a fact probabh' to 
 be accounted for in the arrest offered by these locations to their migra- 
 tions. 
 
 The nmuber of cysts which an infested individual may harbor is 
 
 capable of reaching an enormously high figure. Neumann states that 
 
 Leuckart has counted between twelve hundred and fifteen hundred in a 
 
 gram (15.43 grains) of muscle, while Fielder, 
 
 jJBHIIjjHj according to the same author, estimated the 
 
 ^^^^B^^^H number found in the body of a young woman 
 
 ^^HflH^^^S as ninety-four million. 
 
 l^^^^^^^^B^ Occurrence. — Adult trichinae are only found 
 J^^H^^^^^ in the intestines, especially the upper part of 
 ^^i^H^^l^J^^JI the small intestine, of mammals and birds which 
 ^^^ Wm^ have recently- eaten flesh containing the en- 
 ^ I cysted larva?. In fishes and other cold-blooded 
 
 Fig. 164. — Trichinella vertebrates the trichina cysts are not acted 
 spiralis. Cyst in human ^jpon by the digestive canal and thev pass 
 
 muscle (from micropho- . , i • , i , i r^t- l^ • i" 
 
 tograph by Hoedt). through Without change. Ui the animals com- 
 
 monly used for human food only the hog harbors 
 muscle trichinae by natural infection, and trichinosis of man is usually 
 acquired by eating the trichinosed flesh of this animal. Rats are peculiarly 
 susceptible to trichina, and probably one of the most frequent sources 
 of the infection of hogs is by eating trichinous rats. Transmission to 
 herbivorous animals, as cattle, sheep, and horses, is difficult. After 
 experimental feeding of flesh containing the cysts to these animals 
 there is usually a development of intestinal trichinae but no muscle 
 trichinae. Intestinal trichinae have been experimentalh^ developed in 
 birds, but birds do not harbor the encysted larvae. 
 
 Only encysted living larvae are capable of producing trichinosis in 
 their suitable hosts. Ingested larvae which are unprotected b}^ a cyst 
 are destroyed in the stomach by the direct action of the gastric juice. 
 
 Symptoms in Hogs. — Sj'mptoms of trichinosis by natural infection 
 are rarely observed in hogs, though where a considerable quantity of 
 the cysts have been ingested it is probable that such s\anptoms follow, 
 their true cause being unrecognized. Feeding experiments have shown 
 that after massive infestation intestinal trichinosis is manifested by 
 the third to the eighth day. There is then depression, loss of appetite, 
 grinding of the teeth, and a disposition to remain crouched in the 
 bedding or to stand about with back arched and abdomen retracted. 
 
TRICHIXELLID.E 305 
 
 A persistent diarrhea follows whicli is at first liunp\-, then watery and 
 of bad odor. With these symptoms there may also be those of colic. 
 In general the symptoms are those of an entero-peritonitis and they 
 continue over several weeks during which time the animal may die. 
 
 In from one to two weeks the larvae are penetrating the muscular 
 tissue, and muscular trichinosis has set in. The animal now lies upon its 
 side, or, if it moves about, it is in a stiff, halting, and painful manner. 
 The respiration is superficial, the voice husky, and chewing and swallow- 
 ing difficult. 
 
 With the coming to rest and encapsulation of the larvie the animals, 
 in most cases, gradually' recover. Where there has been exceptionally 
 heavy infestation edema may appear in various parts of the body; 
 such a development is usually followed by death. 
 
 Prophylaxis. — IVIost all cases of infection of man with trichina are 
 from eating trichinosed pork, the swine usually becoming infected by 
 eating the trichinous flesh of other swine or that of affected rats and 
 mice. Knowing these facts, prevention is made relatively simple. 
 Places where hogs are kept should be freed from rats, and the flesh of 
 animals subject to nuiscular trichinosis should not be fed to hogs un- 
 less it has been thoroughh- cooked. According to Leuckart, trichinae 
 are killed at a temperature between 62° and 70° C. (143°-158° F.). 
 These degrees of heat nuist be continued sufficiently to penetrate the 
 entire piece of meat, a white or light gray cut surface indicating that the 
 cooking has been sufficient. 
 
 Treatment.— Treatment is ineffectual. In the case of such an ex- 
 tremely rare occurrence as the early diagnosis of intestinal trichinosis, 
 the administration of anthelmintics followed ])y purgatives might be 
 of some value, but the deep location of the mature worms in the crypts 
 of the mucosa affords them a high degree of protection against such 
 agents. 
 
CHAPTER XXV 
 
 THE THORN-HEADED WORM. THE LEECHES 
 
 Order II. Acanthocephala. Nemathelminthes (p. 216). — Essential 
 differences separating this order from the Nematoda are the absence of 
 a digestive tube and the possession of a protractile rostrum provided 
 with hooks. The body cavity contains a fluid in which are the sexual 
 organs. The sexes are separate. 
 
 One species is of suflficient pathologic importance for consideration. 
 This is the large intestinal roundworm of the hog, Gigantorhynchus 
 hirndinaceus of the family Gigantorhynchidge, more commonly described 
 under the name Echinorhynchus gigas. 
 
 Gigantorhynchus hirudinaceus (Echinorhynchus gigas). Fig. 165. 
 Acanthocephala (]3. 306). — The body is white, cylindrical, transversely 
 wrinkled, and often expanded at several points. The rostrum is almost 
 globular, retractile, and has five or six rows of backward-curving hooks 
 (Fig. 166). The caudal extremity is somewhat tapering. The males 
 are smaller and thinner than the females and have a bell-shaped caudal 
 bursa. The caudal extremity of the female is rounded. 
 
 The female is 20-35 cm. (8-13 inches) in length by 4-9 mm. (5/32- 
 11/32 of an inch) in breadth. The male is 6-10 cm. (2 3/8-4 inches) in 
 length and in breadth 3-5 mm. (1/8-7/32 of an inch). 
 
 The eggs are oblong, measuring 87-100 microns. When developed 
 they are surrounded by three envelops. The embryos are formed within 
 the body of the female. 
 
 The adult worm is parasitic in the small intestine of the hog; excep- 
 tionally it occurs in man. The larva lives encA'sted in the white grub 
 of the May-beetle and probably some other invertebrates. 
 
 The eggs of Gigantorhynchus, discharged to the ground with the 
 feces of the hog and eaten by the larva of the May-beetle, are hatched 
 in the digestive canal, and the embryos, by burrowing through the in- 
 testinal wall, find their way into the bod3'-cavity where they become 
 encysted. In this state they may continue to live through the larval 
 and pupal stages and even after the maturity of the insect. If the hog 
 eats the May-beetle in any of these stages containing the cyst, the cyst 
 Avail is digested away and the freed larval worm attaches by its cephalic 
 hooks to the intestinal mucosa whei'c it attains full development. 
 
 Occurrence, Pathogenesis and Symptoms. — The giant intestinal 
 worm of the hog is quite common in the United States, especially so in 
 
THE THORN-HEADED WORM. THE LEECHES 307 
 
 the southern portion. The miplantation of the worms upon the in- 
 testinal wall b}' means of their hooked rostrum causes limited infiam- 
 mator}' areas of red or 3'ellowish color. The 
 tumifaction of the wall causes the serosa to 
 be pushed out in the form of nodules which 
 may be of yellowish color and somewhat 
 tubercular in appearance. Exceptionally it 
 has been observed that the parasite has bored 
 through the walls of the intestine and given 
 rise to a purulent peritonitis. 
 
 As applies to helminthiasis in general, the 
 disturbances which these worms produce will 
 be in proportion to their number. Pain may 
 be evidenced b}' continual grunting and rest- 
 lessness, and there is the general derangement 
 of digestion and the unthrift usual to hea\y 
 invasion of the intestines by worms. Young 
 pigs suffer most and, in these particularh', 
 there may be nmscular twitchings and epilep- 
 tiform seizures, such s\nuptoms usually l^eing 
 followed by death. 
 
 Treatment. — Due to the 
 firm attachment of the 
 worms, little or nothing can 
 be accomplished by treat- 
 ment. If this is attempted, 
 
 the same remedies may be used as recommended for the 
 ascarids (p. 241). 
 
 Fig. 165. — Gigantorhynchus 
 hirudinaceus, — natural size 
 (drawn from specimen). 
 
 Class II. Annelida 
 
 Fig. 166. — 
 Armed cephalic 
 extremity of Gi- 
 gantorhynchus hi- 
 rudinaceus, — en- 
 larged. 
 
 Coelhelminthes (p. 216). — The annulated worms differ 
 from those of the class Nemathelminthes in having a 
 segmented body cavity with corresponding ringing or 
 annulation of the body wall. The earthworm is usually 
 taken for type study of the group. 
 Order Hirudinea. Annelida (p. 307). — This order includes the 
 leeches which differ in many respects from typical annelids. The body 
 is flattened doiso-ventrally and lacks the appendages for locomotion 
 (setae) characteristic of other forms. Locomotion is accomplished by 
 two suckers, one at the posterior end, used only for locomotion and 
 attachment, the othei- surrounding the mouth, used for locomotion 
 and attachment and also for sucking the food. In moving from place 
 to place the head end is thrust forward and attached by the sucker. 
 The hind sucker is then released and brought close to the anterior sucker 
 
308 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 by a looping up of the bod}-, the anterior sucker being again advanced 
 and the process repeated. They can also swim freely by snake-like 
 movements in the water. The body surface i? transverseh' striated, 
 gi^dng the appearance of a large number of segments. The striations, 
 however, are in excess of the true segmentation representing the somites, 
 the primitive segment rings being divided bj^ secondary- striations. 
 The alimentary canal has a nmnber of paired sac-like protuberances 
 var3'ing in number according to species. When the leech gorges itself 
 these sacular pockets are filled with blood upon which the animal maj^ 
 live for some time before again feeding. The bod}- cavity is reduced by 
 the connective tissue and musculature to a number of tubular sinuses. 
 
 The leeches are hermaphroditic and copulate reciprocal^ (cross 
 fertihzation). As in the earthworms, certain of the somites at the time 
 of reproduction develop into a clitellum which secretes porous cocoons 
 in which the eggs are deposited. 
 
 The leeches to be considered come under one family, the Gnathobdel- 
 lidse, which have the pharynx provided with three semicircular chitinous 
 plates or jaws, each armed on its free edge 
 with numerous teeth. The Rhynchobdellidse 
 are without jaws. This family contains species 
 which attack fishes and invertebrates and occa- 
 sionally water fowl. 
 
 1. Haemopis sanguisuga. The horse leech. 
 (Fig. 167). Hirudinea (p. 307).— Dorsally this 
 leech is greenish brown or sometimes reddish 
 in color; ventrally dark gray, reddish gray, or 
 black. Generally the body has four to six longi- 
 tudinal rows of closely set dark points which 
 may be somewhat indistinct. The body is 
 widest in the middle, gradually narrowing an- 
 teriorly, and is composed of ninety-five to 
 ninety-seven segments. It is rounded dorsally, 
 flattened ventrallj^, soft, viscid, and capable of 
 great extension and retraction. The oral sucker 
 is slightly concave, having at its center the 
 mouth which is in the form of a three-rayed 
 star (Fig. 167). Each of these ray-like sHts 
 permits the passage of a jaw, the teeth of which wound the mucous 
 membrane and thus enable the leech to suck blood while it holds on 
 by means of the oral sucker. There are ten indistinct eyes located 
 anteriorly on the dorsal surface. The \"ulva is a transverse slit located 
 five rings behind the male orifice, or between the twenty-ninth and 
 thirtieth rings. 
 
 In fecundation two individuals come together l^v their ventral sur- 
 
 FiG. 167. — Haemopis san- 
 guisuga. Oral sucker of 
 same at right. 
 
THE THORN-HEADED WORM. THE LEECHES 309 
 
 faces in opposite directions, each having the part of male and female. 
 After the cross fertilization is accomplished there forms around the part 
 of the body where the sexual organs are located a clitellmn Avhich is a 
 sort of girdle secreting the capsules with which the eggs become sur- 
 rounded. The leeches then bury themselves in damp ground where the 
 eggs are deposited and incubation proceeds, this process occupying 
 about twenty-eight days. 
 
 2. Hirudo medicinaiis. The medicinal leech. Hirudinea (p. 307).— 
 This species is a little smaller than the horse leech. The dorsal surface 
 is darker than the ventral and is usually marked with six longitudinal 
 reddish stripes. The ventral surface is usually olive green and may 
 be more or less spotted. 
 
 This leech was once extensively employed in medical practice for the 
 abstraction of blood. 
 
 All of the domesticated animals and man are attacked by Haemopis, 
 probably the horse most frequently. The leeches live in ponds and 
 springs where the animals are likety to drink and are conveyed to the 
 mouth with the water. Those taken up are usually the young ones, 
 these keeping near the surface of the water, while the adults usually 
 lie in the mud at the bottom. Having thus gained access to the nmcous 
 membranes, they fix upon the lips, cheeks, pharjmx, or other parts of 
 the mouth. They may enter the nasal cavities through the nostrils 
 direct, or they may attach to the eyelids. While holding fast in these 
 positions by their oral and caudal suckers, the leeches lacerate the 
 mucous membrane with their cutting jaws and become gorged with 
 blood. They then detach and pass from their host, or they may attach 
 to another part of the mucous membrane and renew their feeding. 
 
 The effect of the infestation will depend upon the number of leeches 
 present, and this is extremely variable. It is estimated that a single 
 leech when engorged will hold about eight cubic centimeters (two drams) 
 of blood. The host suffers an additional loss from the fact that there is 
 considerable hemorrhage from the wounds after the engorged leeches 
 have become detached. Heavy invasions, therefore, are capable of 
 bringing about considerable depletion with evidences of anaemia, as 
 paleness of visible mucous membranes, edemas, and emaciation. A 
 fatal asphyxia may develop from edema of the pharynx which may be 
 contributed to by the mechanical obstruction offered by the leeches in 
 this location. 
 
 Treatment. — AVhere exploration of the mouth or nasal passages 
 reveals the presence of leeches, those which are accessible may be re- 
 moved by forceps or with the hand wrapped in a towel. Vinegar, or a 
 strong solution of common salt repeatedly applied with a view to causing 
 them to release their hold, is recommended by some, but the effective- 
 ness of such treatment can only apply to the leeches with which the liquid 
 
310 PARASITES OF THE DOMESTIC ANIMALS 
 
 comes in contact, many of which maj'^ be so far back in the passages as 
 not to be reached. 
 
 A method which is probably better than the syringe in the appHca- 
 tion of this treatment consists in firmly attaching a small sponge to 
 the end of a probe, such as a piece of rigid rubber tubing. The sponge 
 is saturated with salt solution and, preferably with the use of a mouth 
 speculum, passed back over the soft palate and pharynx. In the same 
 manner it may be apphed deeply into the nasal passages, the tube being 
 inserted slowly and with a rotary movement. 
 
 n 
 
PART III 
 THE PATHOGENIC PROTOZOA 
 
 CHAPTER XXVI 
 
 PHYLUM IV. PROTOZOA 
 
 This division includes the most primitive organisms belonging to the 
 animal kingdom. While some can be detected b.y sharp eyes as tiny 
 swinmiing specks, most all are so small that they can only be seen with 
 the aid of the microscope. The individual animal is constituted by a 
 single cell, which, with a difference in development, characteristicall}^ 
 distinguishes the Protozoa from other animal groups. In most cases 
 they live independently of each other, but not rarely a number are 
 associated in colonies. Each individual in such a colony is, as a rule, 
 physiologically complete, that is, performing within itself all of the 
 functions necessary to its life and reproduction. The colonization, 
 however, tends to a degree of differentiation and interdependence, and 
 in certain cases there are morphological and physiological differences 
 among the individuals so grouped, these usually being related primarily 
 to the functions of nutrition and reproduction. 
 
 The protozoan colony may be said to differ from the metazoan in that 
 each cell of the colony represents an animal which may live unassociated 
 with other cells, while in the metazoan the individual is comprised l\v 
 the aggregation of cells among which there is a morphological differentia- 
 tion corresponding to special functions which are distributed among 
 adaptively specialized cell-groups; the bod\'-cells are not capable of free 
 existence and they can only live as integral parts of the metazoan. 
 The Protozoa being single-celled animals, there is a further fundamental 
 difference in their development, since it essentially follows that there is 
 no formation of germ layers as occurs in all Metazoa. The division or 
 budding of the protozoan cell results directlj' in a new generation and 
 not in the development of germinal tissue layers, though the new cells 
 may remain aggregated to form a colony. 
 
 While the Protozoa are referred to as the most simple rejiresentatives 
 of the animal kingdom, they present, nevertheless, considerable differ- 
 ences in form and modification of the cytoplasm, the functions of mo- 
 tion, alimentation, excretion, and reproduction being performed by a 
 
312 PARASITES OF THE DOMESTIC ANIMALS 
 
 much greater specialization in some than in others. While a nucleus is 
 not easily demonstrable in certain of the Protozoa, most have one or 
 more distinct nuclei, in this, as in other respects, possessing the essential 
 parts of a typical cell. 
 
 Ameba. — A simple representative of the Protozoa is the Ameba 
 (Fig. 168) which may be found in .most any still water, most readily in 
 the ooze ujion the bottom or adhering to leaves or other submerged 
 
 Fig. 168. — -Ameba proteus (after Crawley, from Doflein; Cir. 
 No. 194, Bureau An. Ind., U. S. Dept. Agr.). 
 
 objects. Search of such material under the low power of the microscope 
 will reveal this organism as a minute protoplasmic particle which slowly 
 changes its shape and location by a peculiar flowing and extension of 
 the cytoplasm at one or more points, forming irregular, often finger-like, 
 projections, — the pseudopodia. These may be withdrawn or the whole 
 substance of the animal may appear to flow into one of the projections; 
 by this manner of locomotion it may slowly pass out of the microscopic 
 field. Close study of the organism will reveal two distinct regions, an 
 outer hyaline, — the ectoplasm (ectosarc), and a central more granular 
 and less transparent part, — the endoplasm (endosarc) . Within the latter 
 may be seen the food vacuoles which are rounded or oval, of varying 
 
PROTOZOA 313 
 
 size, and inclose granules of food material. At intervals clear globules 
 may be seen to gradually form within the cytoplasm and then suddenly 
 contract and disappear. These are the contractile vacuoles which on 
 contracting empty their fluid contents to the exterior. They are rudi- 
 mentary cell organs for the elimination of injurious substances and differ 
 from the food vacuoles in having a definite place in the cell as well as in 
 their approximately constant number. Young amebae usually have 
 within the endoplasm a single nucleus but they may early become 
 multinucleate. All of the vital functions appear to be under the con- 
 trol of the nucleus; experimental removal of the nuclei has shown that 
 Protozoa thus treated cannot properly perform their functions and soon 
 perish. 
 
 In feeding the ameba merel}^ flows around the ol)jcct which it is to 
 use as food; becoming thus inclosed in the cj'toplasni the nutritive 
 elements are digested and assimilated. Circulation is limited to the 
 streaming movements of the cj'toplasm, and respiration is carried on by 
 absorption of oxygen from the surrounding water. 
 
 Reproduction in ameba is by fission or budding. Before division of 
 the cell changes occur in the nucleus involving a separation of the 
 nuclear parts with the formation of two distinct nuclei. These separate 
 and during the process the cell constricts, finally dividing completely 
 with each part inclosing one of the new nuclei. In some cases the cell 
 becomes spherical and secretes a protecting mem])rane around itself 
 before division; the outer membrane becomes hard and adapted to re- 
 sist drying and extremes of temperature, the organism assuming in this 
 condition a resting or encysted stage. Encysted individuals usually 
 divide into more than two; there may be four, eight, or even hundreds 
 of small amebae resulting from the reproductive process. In multi- 
 nucleate forms it frequenth' happens that the division is into as many 
 parts as there are nuclei. 
 
 Parasitism of the Protozoa 
 
 In 1881 Laveran, a phj'sician in the French army, distinctively 
 directed attention to the Protozoa as a cause of disease in animals by 
 his discovery that the cause of malaria in man is a protozoan which, 
 entering the red blood cells, destro^vs them and in this way causes the 
 anaemia characteristic of the disease. Later it was demonstrated that 
 this malarial organism is transmitted b}^ a mosquito and that this is the 
 only way that the disease can be acquired. This discovery served to 
 indicate lines of research looking to insects and other arthropods as 
 essential carriers of other forms of pathogenic Protozoa, in which field 
 much has already been accomplished. 
 
 Theobald Smith, in 1892, found that Texas fever of cattle is caused 
 
314 PARASITES OF THE DOMESTIC ANIMALS 
 
 by a protozoan which, though not identical with it, is allied to the 
 malarial parasite, and, like it, enters and destroys the red blood cells. 
 In this case the infecting organism has been found to be conveyed from 
 animal to animal by a certain species of tick {Margaropus annulatus, 
 p. 144), and it is now known that the presence of the tick is essential to 
 such transmission. 
 
 Trypanosomes were first studied in mammahan blood by Lewis in 
 1877, who observed them in the blood of a rat. Three years later 
 Trypanosoma evansi was studied as the cause of surra, a disease of horses 
 of Asiatic countries, the transmitting agent of which is thought to be a 
 blood sucking fly (Tabanus, p. 332). 
 
 Bruce, in 1894, demonstrated that a trypanosome {Trypanosoma 
 hrucei) was the specific organism causing the fatal nagana or tsetse 
 fly disease of horses and other domestic animals of Africa. He showed 
 conclusively that blood-sucking invertebrates, mainly the tsetse flies 
 (Glossina, p. 44), are responsible for its transmission from the blood of 
 wild immune to the blood of susceptible domesticated animals. 
 
 The relationship of the tsetse fly to human trypanosomiasis was shown 
 in much the same way as that followed in the researches of Bruce. 
 African sleeping sickness of man was originally confined to the West 
 Coast; it has spread eastward and is now a serious menace to the develop- 
 ment of Central Africa. In 1902 the infecting organism of this fatal 
 disease was discovered to be a trypanosome {Trypanosoma gambiense) 
 carried from host to host mainly by a tsetse fly. Students of protozool- 
 ogy have since shown that mosquitoes, lice, and leeches may carry 
 trypanosomes, and that piercing flies, therefore, may not alone be 
 responsible for the spread of the diseases which are caused by these 
 Protozoa. 
 
 The instances above cited will serve to direct attention to the im- 
 portance of the Protozoa from the viewpoint of their pathogenicity both 
 in its economic relation and as regards disease in man. Up to the present 
 time the Protozoa as disease-producing organisms have not received 
 the attention in the United States that has been given them by inves- 
 tigators in Africa and Europe. This is probably due to the fact that, 
 though this country is not free from pathogenic trypanosomes, it has 
 thus far escaped the ravages of the trypanosomiases of Africa, Asia, 
 and South America, to which countries sleeping sickness, kala-azar 
 (leishmaniasis), nagana, surra, and mal de caderas have to the present 
 time confined their plague. A sHght acquaintance with the subject, 
 however, is sufficient to dispel a feeling of security based upon the 
 erroneous impression that these diseases are restricted to tropical 
 countries or that their spread depends upon the presence of a certain 
 kind of fly. It has already been noted that the African trypanosomiases 
 may not depend wholly upon the tsetse flies for their existence and 
 
PROTOZOA 315 
 
 spread; surra and mal de caderas certainly do not, as these are diseases 
 of Asia and South America respectively, and tsetse flies are not found in 
 either of these countries. There is, in fact, no reason to doubt that any 
 blood-sucking fly can transmit trypanosomes from the blood of one 
 host to that of another. In view of this the horse and stable flies, so 
 common in North America, would, in the presence of trypanosomiasis, 
 amply supply the means for its sprej^d. 
 
 In recent years important advances have been made in the study 
 of the role of arthropods in the spread of disease. Common knowledge 
 as to its powers for carrying bacterial infection has condemned the 
 fly to the swat, but it is as essential hosts, and not as purely mechanical 
 carriers, that these invertebrates furnish the greatest field for research. 
 Much has already been accomphshed in working out the life histories 
 of the parasites of insects and ticks, including parasites which have no 
 api^arent connection with diseases of higher animals, for these, po- 
 tentialh' at least, may not be so harmless to higher animals as may at 
 first appear. Change of habitat, as from one part of the body to another 
 in the same host, or from a host of one species to that of another, fre- 
 quently leads to great alteration in the mode of life of an organism 
 which, relatively harmless in the insect, may in the vertebrate evolute 
 into more harmful parasitism with the development of pathogenicity'. 
 The newer a parasite is to the animal harboring it, the less it is in har- 
 mony with its environment. Protozoa which produce acute forms of 
 disease have less adaptation to their environment than those producing 
 a chronic type of malady. This discord between parasite and host is 
 manifested by acute disturbances which maj' result in the death of the 
 infected animal. Such parasitic diseases of a chronic course are usually 
 correlated with a greater degree of adaptation of the parasite to its 
 host and also with acquired resisting powers of the host to the specific 
 action of the parasite. 
 
 The scale of evolution through the saprophytic, parasitic, and patho- 
 genic is thus exhibited by certain groups. The Spirochetida, long, 
 delicate Protozoa with a corkscrew-formed body, may be found as in- 
 habitants of the body-cavities, of normal mucous surfaces, of inflamed 
 mucous surfaces, as parasites which have penetrated the tissue, and as 
 blood parasites. This series is sufficient to show how parasitism may 
 evolute by various gradations from harmless commensalism to distinct 
 parasitism and pathogenicity, ^^^len the habit of living in inflamed or 
 ulcerated tissues is reached the power of penetrating healthy tissues 
 soon follows which, with the multiplication of the spirochetes in such 
 situations, causes destruction of invaded tissue and local disturbances. 
 The products of this tissue destruction, together with those coming from 
 the dead bodies of the parasites, form toxins which, getting into the 
 blood, produce the general toxemic symptoms. The final stage of 
 
316 PARASITES OF THE DOMESTIC ANIMALS 
 
 malignant parasitism is reached when the spirochetes acquire the habit 
 of Uving in the blood. In this case it is evident that, except under cer- 
 tain conditions of contact, the transfer from host to host cannot be direct, 
 but that the intervention of an intermediate host is necessary. This must 
 be a blood-sucking invertebrate, and, in certain known cases of spiroche- 
 tosis of domestic animals, has been found to be a tick, as the tick Argas 
 miniatus, the carrier of Spirocheta galUnarum which causes a spiroche- 
 tosis in fowls, and the cattle tick Boophilus decolomtiis, the inter- 
 mediate host of Spirocheta theileri, the cause of a disease among South 
 American cattle. 
 
 The malaria parasites afford stud}- in the evolution of pathogenicity 
 of other Protozoa. These organisms indicate in their morphology' and 
 development that they are closely allied to the Coccidia, which are 
 protozoan cell parasites attacking and entering tissue cells, especially 
 epithelimii, of arthropods and vertebrates. There is little doubt that 
 the malaria parasites were originall}' Coccidia of insects that, with 
 change of hal3itat, developed increased pathogenicity toward the new 
 host. 
 
 Granting this, we have, then, in the malaria parasites an example 
 of the evolution of disease m the past, while disease in the making is 
 evidenced to-day more especiall}' in the case of certain parasitic flag- 
 ellates of the genus Herpetomonas. 
 
 The introduction of herpetomads into vertebrates by the latter 
 swallowing infected insects, or b}' the wa}' of wounds of the skin, has 
 been shown to result in pathogenic effects in the vertebrate host. A 
 series of experiments extending over some six years (Fantham and 
 Porter, Journal of Parasitology, June, 1916) have shown that certain 
 herpetomads normally parasitic in insects, when introduced into ver- 
 tebrates will produce a condition resembling kala-azar, an infectious 
 disease of man common in certain regions of India, China, and countries 
 bordering on the Mediterranean, caused by the herpetomad Leishmania 
 (Herpetomonas) donovani. The sjinptoms developed and the mor- 
 phology of the parasite found in the vertebrate host show that here at 
 least are examples of kala-azar in process of evolution. 
 
 Plate III. — Evolution- of the Parasite of Kala-Azar. Figs. 1 to 5. Parasites of 
 kala-azar. 1. Isolated parasites of different forms in the spleen and liver. 2. Di%asion 
 forms from liver and bone marrow. 3. Mononuclear spleen cells containing the parasites. 
 4. Groups of parasites. 5. Phagocjiiosis of a parasite by a polynuclear leucocyte. Figs. 
 (3 to 15. Parasites from cultures. 6. First changes in the parasites. The protoplasm has 
 increased in bulk and the nucleus has become larger. 7. Further increase in size. Vacuoli- 
 zation of the protoplasm. S. Di%-ision of the enlarged parasite. 9. Evolution of the 
 flagella. 10. Small piriform parasite showing flagellum. 11. Further development and 
 division of the parasite. 12. Flagellated trj-panosome-like form. 13, 14. Flagellated 
 forms dividing by a splitting-off of a portion of the protoplasm. 15. Narrow flagellated 
 parasites which have arisen by the type of division shown in Figs. 13 and 14. (After Craw- 
 ley, from Mense's "Handbuch," after Leishman, Cir. Xo. 194. Bu. An. Ind., U. S. Dept. 
 Agr.). 
 
^ f% ^ 
 
 ? i % ^ I 
 
 2 
 
 
 • f 
 
 
 ''^' ® • Ik 
 
 
318 PARASITES OF THE DOMESTIC ANIMALS 
 
 A brief review of these conclusions, drawn from the results of ex- 
 perimental research, will be sufficient to direct attention, not only to 
 the powers which insects have as carriers of disease, but to their poten- 
 tial powers in the making of disease as well. 
 
 Methods of Reproduction. — Sexual and asexual methods of repro- 
 duction alternate in free forms of Protozoa, but the asexual method is 
 usually limited to simple division or budding. Parasitic forms, on the 
 other hand, have acquired a more prolific means of multiplication, the 
 simple division and budding being replaced by asexual spore formation 
 as exemplified among the Sporozoa. In the parasitic Protozoa, there- 
 fore, two kinds of spores may be present, the one occurring asexually 
 during the vegetative life in the host and giving rise to auto-infection 
 in the same host, the other sexual, occurring at the end of the vegetative 
 life of the parasite, preparing its germs to withstand the unfavoral^le 
 conditions of an external environment, and giving rise to infection of 
 new hosts. 
 
 The asexual method of multiplication, taking place during the veg- 
 etative life in the host, is termed schizogony or schizogenesis, while the 
 term sporogony or sporogenesis has been given to reproduction by the 
 sexual method. The first is sometimes referred to as the multiplicative, 
 the second as the propagative cycle. 
 
 Life History of the Malaria Organisms. — AVith a view to an ele- 
 mental conception of these reproductive and infective processes in the 
 Sporozoa, the life history of the organisms producing malaria in man 
 affords a clear example for stud3^ 
 
 Malaria was the first of the human diseases in which it was proved 
 that a protozoan is the direct cause, and by 1901 the disease was as 
 thoroughly understood as perhaps any other due to a germ. The malaria 
 parasites belong with the genus Plasmodium, so named from their early 
 supposed resemblance to some of the plasmodia-forming fungi. They 
 are usually considered under three forms with which three well-marked 
 types of malaria are associated. These may be briefly summarized as 
 follows : 
 
 1. Plasmodium vivax. — Cause of tertian fever; paroxysms occur every 
 forty-eight hours; incubation period about two weeks. Temperate cli- 
 mates, also in tropics and subtropics. 
 
 2. Plasmodium falciparum (P. prcecox). — Cause of estivo-autumnal 
 fever; paroxysms every twenty-four hours; incubation period usually 
 from ten to twelve days. Tropics and subtropics. 
 
 3. Plasmodium malarice. — Cause of quartan fever; paroxysms every 
 seventy-two hours; incubation period about three weeks. Tropics and 
 subtropics. 
 
 Two distinct cycles are involved in the life history of the malaria 
 organisms. The first takes place in the blood of the human patient and 
 
PROTOZOA 319 
 
 is known as the asexual or schizogonic cycle, during which the plasmodia 
 niultipty by the asexual method or schizogony. The second occurs in 
 the body of a mosquito and is the sexual or sporogonic cycle, involving 
 reproduction b}' the sexual method or sporogony. A third phase is to 
 be recognized during which the female gametocj'tes sporulate without 
 fertilization. This is referred to as the parthenogenetic cycle. It is' 
 passed within the body of the human host and explains the recurrence 
 of malaria after more or less prolonged periods of latency. 
 
 The Schizogonic or Asexual Cycle. — The asexual cycle begins with 
 the infection of the human })lood with the sporozoites by the bite of a 
 mosquito of the genus Anopheles (p. 26). The sporozoite is spindle- 
 shaped and on entering the blood at once penetrates a red corpuscle 
 where it takes a ring-like form, referred to as the signet ring stage, Liv- 
 ing at the expense of the corpuscle, the organism grows rapidly until it 
 more or less fills the corpuscle. At this stage it is known as the schizont, 
 which is the period of its ameboid movement and highest vegetative ac- 
 tivity. As the schizont matures its nucleus breaks up into a number of 
 daughter nuclei, each becoming surrounded by a spherical portion of 
 protoplasm to form a small reproductive element. — the merozoite, or 
 asexually formed spore. Finally the corpuscle is broken down and the 
 swarm of merozoites is liberated in the ])lood-plasma. Coming from the 
 same original brood, the parasites all sporulate and become liberated in 
 the blood at the same time; this results in the constantly increasing 
 number of merozoites l)eing li))erated at stated intervals with corre- 
 sponding intervals of paroxysm in the host. The general toxic effect 
 upon the malaria patient is contributed to by the accumulated waste 
 products of the parasite's metabolism which pass into the plasma with 
 the liberation of the merozoites. Each liberated merozoite now enters 
 another corpuscle, and the asexual cycle is repeated in from twenty- 
 four to seventy-two hours according to the species of the infecting or- 
 ganism. 
 
 This process of multiplication may continue for an indefinite tune 
 or, by analogy with other parasitic Protozoa, until the vitality is ex- 
 hausted. Asexual merozoites are greatly in the majority, but certain of 
 them are potentially sexual and i-equire a longer time to fully develop 
 into males and females when they are known as male and female game- 
 tocytes. Up to this time they are still intracorpuscular and, in the 
 estivo-autumnal or pernicious type of fever, appear as large crescents. 
 The female crescent (macrogametocyte) has numerous pigment gran- 
 ules collected in the center; the male (microgametocyte) is the mother 
 cell of the male reproductive elements (microgametcs). The nucleus 
 of the male cell divides into a number of daughter nuclei which migrate 
 to the periphery and become the nuclei of the flagelliform microgametes. 
 These bodies are constantlv in the l)lood after the first few paroxysms. 
 
320 PARASITES OF THE DOMESTIC ANIMALS 
 
 If the blood is now di-awn by an anopheline mosquito further changes 
 take place-. 
 
 The Sporogonic or Sexual Cycle. — In the intestine of the mosquito 
 the female gametocyte undergoes certain nuclear changes preparatory 
 to fertilization; the cell becomes rounded or oval in form, and is now 
 known as the macrogamete. From the male gametocyte there are ex- 
 truded from three to six fiagelliform filaments corresponding in number 
 to the peripheralh' disposed daughter nuclei. These filaments detach 
 from the mother cell to become the actively motile microgametes, which 
 are analogous to the spermatozoa of higher animals. Thus the flag- 
 ellated parent body maj' be referred to as a microgametoblast; produc- 
 ing the male sexual elements or microgametes. 
 
 Fertilization of the macrogamete is brought about by its penetration 
 by one of the microgametes. The fertihzed macrogamete now becomes 
 the ookinete or zj-gote, in which stage it passes by a vermiform move- 
 ment into and through the epithelium of the mosquitoe's mid-intestine 
 and comes to rest just beneath the outer lining membrane. Here it 
 rapidly grows, the nucleus divides, and by the third to the fifth day it has 
 formed a cyst in which there are many nuclei, each to become the nucleus 
 of a minute body, — the sporoblast. The sporoblasts, by division, form a 
 number of germs, — the sporozoites, spindle-shaped, nucleated bodies 
 which are mature after a period of ten to fourteen days in the body of 
 the mosquito. On reaching maturity, the sporozoites are liberated into 
 the body cavity of the insect where they are carried about b}^ the body 
 fluids, collecting eventual^ in the salivary glands. From here they 
 pass to the piercing proboscis from which, with the next bite of the mos- 
 quito, many may pass into the blood of another human victim to begin 
 the asexual cvcle. 
 
 Plate IV.^ — Life Cycle of the Malaria Parasite. 1. Free sporozoite, either in 
 salivary glands of the mosquito or in blood of man. 2. Penetration of the sporozoite into a 
 red blood corpuscle. 3 to 6. Growth of trophozoite. 7, 8. Division of trophozoite which 
 brings about destruction of the blood corpuscle and the release of the merozoites in the 
 blood stream. The free merozoites then enter new blood corpuscles, and this cycle may 
 be repeated many times. Finally, however, the sexual cj'cle is initiated as follows: 9a to 
 12a. Growth and differentiation of female cell. 9b to 12b. Growth and differentiation of 
 male cell. 1.3a, 13b. The male and female cells are swallowed by a mosquito. 14a. Matu- 
 ration of female cell. 14b. Formation of microgametes. 15b. Free microgamete. 16. 
 Fertilization. 17. Ookinete. 18, 19, 20. The ookinete attacks and penetrates a cell of 
 the intestine of the mosquito, and passes completely through the epithelium, coming to 
 rest in the peri-intestinal tissue. (There is not, in life, the reduction in size indicated by 
 the figure.) 21 to 25. Stages in the development of the cyst and formation of the sporozo- 
 ites. 26. Migration of the sporozoites. 27. Sporozoites in the salivary glands of the 
 mosquito. 13c to 17c. These figures portray the cycle which is supposed to account for 
 cases where malaria is latent for a longer or shorter period. Ordinarily, unless removed Ijy 
 a mosquito, the differentiated male and female cells (12a and 12b) die, but under certain 
 conditions the latter may continue to live in the blood, to give rise to a renewal of the 
 disease. (After Crawley, from Mense's "Handbuch," after Grassi and Schaudinn, Cir. 
 No. 194, Bu. An. Ind., U. S. Dept. Agr.). 
 
3^22 PARASITES OF THE DOINIESTIC ANIMALS 
 
 In the parthenogenetic phase, which occurs in the human host, the 
 female gametocyte sporulates without fertiHzation. After months of 
 latency these spores may pass into the blood current and enter the 
 corpuscles, bringing about a recurrence of malaria after its apparent 
 cure. 
 
 It should be noted in the sexual cycle that the formation of the spo- 
 roblasts is similar to the formation of corresponding reproductive cen- 
 ters of the Coccidia, which pass a portion of their cj^cle external to a host 
 and which are elsewhere referred to (p. 337). The sporoblasts of the Plas- 
 modia, however, differ from those of the Coccidia in having no protect- 
 ing membrane or capusle, in the absence of which protection, the spo- 
 rozoites are unfitted for existence outside the body of a host animal. 
 
 Classification. — Accorchng to their mode of life, Calkins divides the 
 parasitic Protozoa into the following groups. The arrangement is not 
 a natural one and is merely for descriptive purposes: 
 
 1. Enterozoic. — Living in the lumen of the digestive tract. 
 
 2. Coelozoic- — Living in the coelomic cavities of the body. 
 
 3. Cytozoic. — Living throughout the vegetative period as intracel- 
 lular parasites. 
 
 4. Caryozoic. — Passing into the cell to find lodgment in the cell nu- 
 cleus. 
 
 5. Hematozoic. — Living in the blood plasma. 
 
 In some cases the parasite may pass through a number of these modes 
 of life. Thus the plasmodia of malaria are hematozoic in the blood 
 current, cytozoic in the blood corpuscles, enterozoic in the digestive 
 tract of the mosquito, and coelozoic w^hen they pass as sporozoites into 
 the body cavit.v of this insect. 
 
 In the arrangement of the classification of the Protozoa which follows, 
 only those groups containing species of parasitic importance are given. 
 
 Classification of Paeasites of the Phylum Protozoa 
 
 Phylum IV. Protozoa. P. 311. 
 Class A. Phizopoda. P. 324. 
 Order 1. Lobosa. P. 324. 
 Genus and Species: 
 
 Ameba meleagridis. Host, turkey. P. 325. 
 Entameba histolytica. Host, man. P. 326. 
 E. coli. Host, man. P. 326. 
 Class B. Flagellata. P. 326. 
 Order 1. Spirochetida. P. 327. 
 Genus and Species: 
 
 Spirocheta gallinarum. Host, fowl. P. 327. 
 Order 2. Trypanosomatida. P. 328. 
 
PROTOZOA 323 
 
 Genus and Species: 
 
 Trypanosoma theileii. Host, cattle. P. 329. 
 
 T. brucei. Hosts, equines, cattle, etc. P. 330. 
 
 T. evansi. Hosts, equines, camel. P. 332. 
 
 T. equinum. Host, equines. P. 332. 
 
 T. equiperdum. Host, equines. P. 333, 
 
 T. americanum. Host, cattle. P. 330. 
 
 Trvpanoplasma. P. 329. 
 Class C. Sporozoa. P. 336. 
 Order 1. Coccidia. P. 337. 
 Genus and Species: 
 
 Eimeria stiedse. Host, rabbit. P. 342. 
 
 Diplospora bigemina. Host, dog. P. 342. 
 
 Coccidium zurni. Host, cattle. P. 343. 
 
 Eimeria avium. Host, chicken. P. 345. 
 Order 2. Hemosporidia. P. 347. 
 Genus and Species: 
 
 Piroplasma bigeminum. Hosts, cattle, tick. P. 347. 
 
 Plasmodium vivax. Hosts, man, mosquito. P. 318. 
 
 PI. falciparum. Hosts, man, mosquito. P. 318. 
 
 PI. malaria. Hosts, man, mosquito. P. 318. 
 Order 3. Sarcosporidia. P. 350. 
 Genus and Species: 
 
 Sarcocystis miescheriana. Host, pig. P. 351. 
 
 S. tenella. Host, sheep. P. 351. 
 
 S. blanchardi. Host, cattle. P. 351. 
 
 S. bertrami. Host, equines. P. 351. 
 
CHAPTER XXVII 
 
 THE PROTOZOAN SUBGROUPS. DISEASES DUE TO 
 PROTOZOA 
 
 Class I. Rhizopocla. Protozoa (p. 311). 
 
 The Protozoa of this group lack permanent structures for locomotion 
 and nourishment, these functions being performed by the undifferen- 
 tiated protoplasm. For this reason they are considered to be the lowest 
 in position of the Protozoa. The class name — Rhizopoda — has ref- 
 erence to the extension of the cytoplasm in root-like processes or feet, — 
 the pseudopodia or false feet. It is in this manner that the anmial flows 
 over and engulfs its food, the movements serving for locomotion as well. 
 This type of locomotion is known as ameboid, it having been first 
 accurately studied in the Ameba. It differs from that of higher Pro- 
 tozoa in that it is not accomplished by constant cell organs, as ciha and 
 fiagella. A pseudopodium is formed when the cytoplasm streams to a 
 point of the body, the process extending more or less beyond the gen- 
 eral body surface; the body may then be drawn after it or appear 
 to flow into it, the protrusion disappearing and new pseudopodia being 
 formed at other points. By repetition of this process a slow change 
 in the position of the organism occurs, and if particles of nourish- 
 ment are encountered in such wandering they are engulfed by 
 the cytoplasm within which they become surrounded by a certain 
 amount of liquid, presumably of a digestive nature, to form the food 
 vacuole. 
 
 The form of the pseudopodia varies, and this serves as a factor in the 
 separation of the rhizopods into different groups. In the Ameba (Fig. 
 168) they are thick and finger-like, while in certain other forms they are 
 of such delicacy as to appear like fine threads. 
 
 Reproduction in Rhizopoda may be accompanied with the formation 
 ■of flagellate spores, the ameboid method of motility being exchanged 
 for that of the flagellated Protozoa. In this stage the body becomes 
 oval and the flagellum develops at the end containing the nucleus, 
 where it persists during the spore stage. 
 
 The parasitic Rhizopoda belong with the order Lobosa which is the 
 only one considered here. The characteristics of this group have been 
 sufficiently referred to in the description of the type genus Ameba 
 (p. 312). There are but few parasitic species known, and these are 
 included in the two genera Ameba and Entameba. 
 
THE PROTOZOAN SUBGROUPS 325 
 
 Lnfectious Entero-Hepatitis of Turkeys 
 
 This disease — connnonly known as blackhead — has l^een attributed 
 to an organism found by Theobakl Smith in the necrotic Hver of affected 
 turkeys and named by him Ameba meleagridis. That this is an ameba, 
 however, has been questioned. Certain other investigators consider 
 the organism described by Smith as a form in the development of in- 
 testinal Coccidia, the acceptance of which conclusion would place the 
 disease among the coccidioses. 
 
 The term "blackhead" has been used to designate a numl)er of dis- 
 eases of fowls, among which, in addition to entero-hepatitis, are 
 cholera, helminthiasis, intestinal coccidiosis, and, in general, any dis- 
 ease which may be accompanied by dark discoloration of the comb and 
 wattles. 
 
 Symptoms. — It has been shown that entero-hepatitis can be trans- 
 mitted directly from diseased to healthy turkeys, natural hifection prob- 
 ably taking place through food and water contaminated with the 
 droppings from the affected animals. At the expiration of the incuba- 
 tion period, which is usually within one month, the disease is initiated 
 by loss of appetite and a drooping listlessness which is soon followed 
 by diarrhea, the fluid discharge l)eing yellowish in color and of exceed- 
 ingly offensive odoi\ Weakness and emaciation have already set in, 
 and the comb and wattles show th(> blackish discoloration from which 
 the disease takes its name, — blackhead. 
 
 Death usually occurs after a course of from five to eight days. The 
 mortality is highest in young animals, among which it is estimated to 
 be eighty to ninety per cent. Adults are more likely to recover, though 
 usually only after a long period of emaciation duiing which there may 
 be a relapse. 
 
 Post-mortem Appearance. — The changes observed on necropsj^ are 
 those of necrotic degeneration of the cecal mucosa and liver. The walls 
 of the ceca are thickened, the nmcous membrane ulcerated and covered 
 with fibrous memljranes and exfoliating necrotic tissue. The liver is 
 much enlarged and shows on its surface numerous yellowish areas with 
 the centers softened. These areas may be quite small or up to 15 mm. 
 (5/8 of an inch) or more in diameter. Other portions of the digestive 
 tract are not affected. 
 
 Examination in hanging drop of enuilsified tissue of the cecal mucosa 
 and the necrotic foci of the liver will reveal the amebae. The organisms 
 found in the liver occur as rounded or oval cells measuiing 6-14 microns 
 and having a comparatively small nucleus. Smith concluded from his 
 investigations that the parasites were not intracellular but lived in the 
 tissue spaces. In the liver they are thought to occupy the spaces of the 
 necrosed and disappearing liver cells. 
 
826 PARASITES OF THE DOMESTIC ANIMALS 
 
 Control. — The sick animals should be at once separated from those 
 which are apparenth' not infected and the pens and runs subjected to 
 thorough cleaning up and disinfection as recommended in other forms 
 of poultry parasitism. It is important that the yards be kept dry and 
 that the droppings be promptly removed and so disposed of that thej^ 
 cannot be a source of reinfection. 
 
 Treatment is of little value. As paUiative, intestinal antiseptics, as 
 eucalyptus or listerine, may be tried. 
 
 Amebic Dysentery in Man. — This is a disease occurring in tropical 
 and subtropical, and at times in temperate regions, the cause of which 
 is regarded bj' pathologists to be an ameba, — Entamha histolytica. Ar- 
 tificial production of amebic dysentery has been brought about in dogs 
 and cats by rectal introduction of human feces containing the amebae. 
 It has been shown in such cases that the parasites invade the glandular 
 crypts of the intestinal mucosa from which they penetrate to the sub- 
 mucosa and give rise to a hemorrhagic enteritis. In its further course the 
 affection is accompanied by thickening and destructive ulceration of the 
 mucosa. 
 
 The diagnosis of amebic dysentery is by demonstration of the ame- 
 bae in the stools. They may be differentiated from Entameba coli, an 
 intestinal species which is considered to be a harmless commensal, by 
 their definite and relatively firm ectoplasm which gives a rigid character 
 to the pseudopodia, enabling the parasites to force their way between 
 the epithelimn of the crypts and into the more deeply lying tissues. The 
 nucleus of E. histolytica varies in shape and position with the activities 
 of the cytoplasm; it has little chromatin, and no nuclear membrane is 
 apparent. The nucleus of E. coli is usually spherical and shows little 
 change in position. 
 
 Class II. Flagellata (Mastigophora) 
 
 Protozoa (p. 311). 
 
 As has been stated, there are certain forms among the Rhizopoda in 
 which the pseudopodia disappear from time to time to be replaced by 
 one or more flagella; in other cases there maj^ even be permanent fla- 
 gella contributing to the pseudopodia in their function of locomotion and 
 prehension. Such flagellate rhizopods are transitional to the Flagellata 
 and serve to prevent the drawing of a sharp line of demarcation between 
 the two groups based upon the possession of flagella. In general it maj^ 
 be said of the Flagellata that they are permanently flagellate, the fla- 
 gella serving for locomotion and feeding. Thej' exhibit a great diversity 
 of form which is to a large extent correlated with the number and loca- 
 tion of the flagella. A degree of complexity' is exhibited by some free- 
 living forms in the possession of a mouth and cytopharynx. but all par- 
 
THE PROTOZOAN SUBGROUPS 
 
 327 
 
 asitic forms, and most of those which are free-hving, obtain their nour- 
 ishment by absorbtion through the general surface of the body. 
 
 The parasitic flagellates come within two orders. — Spirochetida and 
 Trypanosomatida . 
 
 Order I. Spirochetida 
 
 Flagellata (p. 326). 
 
 The spirochetes are of somewhat uncertain position because of in- 
 complete knowledge of their flagella and life history. They multiply by 
 longitudinal di\'ision, or it may be by transverse division as do bacteria, 
 and many wiiters have placed 
 them with the latter organisms. 
 They range from one to two 
 hundred microns in length, and 
 the body is filamentous and 
 spiral in form (Fig. 169). Deli- 
 cate flagella may be present at 
 one or both ends. Nuclei can- 
 not be distinctly demonstrated ; 
 the nuclear material is prob- 
 ably distributed as granules 
 throughout the protoplasm as 
 in bacteria. Motility is exhib- 
 ited by rotatory movements, 
 and the progression may be in 
 either direction. 
 
 Excepting in poultry, the spirochetes are not, so far as known, seriously 
 pathogenic in the domestic animals. The extreme pathogenicity of 
 certain spirochetes in man, however, indicates the disease-producing 
 possibilities of the group and rates it, potentially at least, as a dangerous 
 one to all higher animals. 
 
 l-'iu. IG'.).— Spirocheta pallida (after Craw- 
 ley, from Doflein, after Sohaudinn, Cir. No. 194; 
 Bu. An. Ind., U. S. Dept. Agr.). 
 
 Spirochetosis of Fowls 
 
 This disease was first described Ijy Marchoux and Salimbeni who, 
 working in Brazil, noted that special varieties were more susceptible 
 and suffered more severely from the attack than common fowls. The 
 condition was originalh- termed fowl septicemia, or Brazilian septicemia 
 of fowls, and is now considered to be due to the presence of the spirochete 
 Spirocheta gallinanim (S. marchoiixi) which lives in the l)lood. is 15-20 
 microns in length, and is carried from host to host l)y the tick Arqas 
 miniatus. 
 
 The investigators above mentioned distinguish an acute and chronic 
 form of the disease, the former characterized by emaciation, drooping. 
 
3^28 
 
 PARASITES OF THE DOMESTIC ANIMALS 
 
 diarrhea, and anaemia. Toward the end weakness has so far advanced 
 that the affected birds are completely helpless and lie with their heads 
 upon the ground. Those which survive are said to be immune to fur- 
 ther attack. The spiroochete sometimes penetrates the red blood 
 cells; it has also been found in the eggs and in the embryonal epithelium 
 of the chick. 
 
 It is not known with certainty that the disease exists in this country. 
 It is not unlikely, however, that some of the as yet obscure diseases 
 
 Fig. 170. — Hen suffering from acute spirochetosis (after Crawley, from Balfour, Cir. 
 No. 194, Bu. An. Ind., U. S. Dept. Agr.). 
 
 of poultry may be found to be due to members of the spirochete group, 
 — a sufficient reason for mentioning the Brazilian spirochetosis here. 
 
 Order II. Trypanosomatida 
 
 Flagellata (p. 326). 
 
 A number of classifications have been proposed for these organisms, 
 Salmon and Styles placing them in the order Monadida (Moore, 1906). 
 Calkins (1909) classifies them as follows: Subphylum Mastigophora; 
 class, Zoomastigophora; subclass, Lissoflagellata; order, Trypanosoma- 
 tida; typical genera, Tiypanosoma and Trypanoplasma. The same 
 author thus describes the order in tabulation: "Organisms of elongate, 
 usually pointed form, and of parasitic mode of life; with one or two 
 flagella arising from a special "motor" nucleus, and with an undulating 
 membrane provided with myonemes running from the kinetonucleus 
 to the extremity of the cell; one of the flagella is attached to the edge 
 
THE PROTOZO.IN SUBGROUPS 329 
 
 of this membrane throughout its length, and may terminate with the 
 membrane or be continued beyond the body as a free lash." 
 
 All species of the genus Trypanosoma show a general morphologic 
 similarity. In general thej^ may be said to measure from 15-45 microns 
 in length, including the flagellum, and 1-5 microns in thickness. As 
 typical of the group, T. theileri, living exclusively in the blood of cattle, 
 may be taken for brief description. The body is spindle-shaped, more 
 or less serpentine, and pointed at the ends, from one of which there pro- 
 jects a vibratile flagellum. The flagellum is continued as a marginal 
 cord toward the opposite end of the body where it takes origin in a 
 minute granule (blepharoplast). In close relation to this granule is a 
 deeply staining body which, because of its connection with the motile 
 elements of the cell, has been designated the kinetonucleus. Arising 
 from the kinetonucleus, the flagellum passes along the body on the 
 border of a delicate protoplasmic membrane — the undulating mem- 
 brane--toward its free extremity. Centrally located is the tropho- 
 nucleus, the nucleus concerned with the vegetative processes of the cell. 
 This is clearly defined and usualh' has the chromatin in the form of 
 granules of definite number. The endoplasm is granular and may 
 appear vacuolated. Reproduction in the blood of the vertebrate host 
 is by longitudinal division following division of the blepharoplast, 
 kinetonucleus, and trophonucleus. In some cases the daughter cells 
 remain together for a longer or shorter time in a sort of rosette forma- 
 tion. 
 
 The members of the genus Trypanoplasma (Cryptobia) have two 
 flagella. They are mostly parasitic in fishes; so far as known there are 
 no species which attack higher animals. 
 
 Transmission. — The Trypanosoma are parasites of the blood, 
 IjTuph, or cerebrospinal fluid of vertebrates, and, with one known ex- 
 ception, their transfer is accomplished by the intervention of an inter- 
 mediate carrier which is either essential and indirect, or mechanical 
 and direct. In the former case a blood-sucking fly becomes infected 
 by feeding upon the blood of an animal harboring the trypanosomes. 
 In the body of the fly the trypanosomes undergo certain changes, 
 probably of a revitalizing nature, and for a period of time the fly remains 
 noninfective. When this period has elapsed the tiypanosomes within 
 the fly resume their ability to infect any host whose blood is reached by 
 the piercing mouth parts of the fly. Furthermore, such flies remain 
 infective for an indefinite period, probably for the remainder of their 
 lives. 
 
 By the direct or mechanical method of transfer the fly, after having 
 bitten an infected animal, very shortly afterward visits a healthy one 
 and may inoculate it directly with its contaminated proboscis. If the 
 fly draws the blood of a sick animal and then successively visits two 
 
330 PARASITES OF THE DOMESTIC ANIMALS 
 
 healthy ones, the second of the latter will not usualty contract the 
 disease. This is due to the fact that the proboscis of the fly, charged 
 with the trypanosomes from the blood of the sick animal, becomes 
 cleaned of the organisms in biting the first of the healthy ones. Any 
 biting arthropod may transmit by the direct method; the abilit}'^ to 
 infect is usually limited to a few hours from the time of biting an in- 
 fected animal, though under experimental observation it has been re- 
 tained for a considerably longer time (see Glossina, p. 44). 
 
 Nagana 
 
 The fundamental work upon this disease was carried on in Zululand 
 by Bruce who, in 1895, discovered that nagana, or the so-called tsetse 
 fly disease, was caused by a trypanosome which, after its discoverer, 
 has been named Trypanosoma brucei. 
 
 "Nagana, or fly disease," Bruce writes, "is a specific disease which 
 occurs in the horse, mule, donkey, ox, dog, cat, and many other animals, 
 and varies in duration from a few days or weeks to many months. It 
 is invariably fatal in the horse, donkey, and dog, but a small percentage 
 of cattle recover. It is characterized by fever, infiltration of coagulable 
 Ijaiiph into the subcutaneous tissue of the neck, abdomen, or extrem- 
 ities, giving rise to swelling in these regions, by a more or less rapid 
 destruction of the red blood corpuscles, extreme emaciation, often 
 blindness, and the constant occurrence in the blood of an infusorial 
 parasite." 
 
 Nagana is a Zulu word which, according to Bruce, refers to the state 
 of depression and weakness characteristic of the disease. 
 
 Nagana exists, particularly in low and humid regions, throughout 
 Africa with the exception of Tunis, Algeria, and Morocco, and most of 
 the countr.y south of the Tropic of Capricorn. The disease is supposed 
 to be transmitted mainly the by the tsetse fly Glossina morsitans, though 
 other species probably play an equal part in this respect. Etiologic 
 reference to nagana has already been made in the review of the work of 
 Bruce under the suljject of Glossina (p. 44) and need not be repeated 
 here. 
 
 Plate V. — Variou.s Species of Trypanosoma. 1. Trypanosoma lewisi, of the rat. 
 2. Trypanosoma lewisi, multiplication rosette. 3. Trypanosoma lewisi, small form re- 
 sulting from the disintegration of a rosette. 4. Trypanosoma brucei, of nagana. 5. 
 Trypanosoma equinum, of caderas. 6. Trypanosoma gambiense, of sleeping sickness. 
 7. Trypanosoma gambiense, undergoing division. 8. Trypanosoma theileri, a harmless 
 trypanosome of cattle. 9. Trypanosoma transvaliense, a variation of T. theileri. 10. 
 Trypanosoma avium, a bird trypanosome. 11. Trypanosoma damonioe, of a tortoise. 
 12. Trypanosoma solese, of the flat fish. 13. Trypanosoma granulosum, of the eel. 14. 
 Trypanosoma rajae, of the skate. 15. Trypanosoma rotatorium, of frogs. 16. Cryptobia 
 borreli, of the red-eye (a fish). (After Crawley, from Laveran and Mesnil; Cir. No. 194, 
 Bu. An. Ind., U. S. Dept, Agr.) 
 
5 ^^ 6 
 
 of ^n 
 
 
 
332 PARASITES OF THE DOMESTIC ANIMALS 
 
 Surra 
 
 This name has been given to a disease of horses, camels, and dogs of 
 Asia caused by Trypanosoma evansi, which in 1880 was found by Evans 
 in the blood of affected horses. Surra occurs in Southern Asia, the 
 East Indies, the Philippines, Korea, Australia, and among the drome- 
 daries in Northern Africa where it is known under the name of mbori. 
 
 Symptoms. — In its constant and progressive anaemia and cachexia 
 the disease closely resembles nagana. At its outset there is a rise of tem- 
 perature which in some cases may be followed by an urticarial eruption. 
 Edema appears under the skin of the belly and limbs, and the eyelids 
 become puffy with conjunctiva congested. The appetite is usually re- 
 tained, but in spite of this there is loss of flesh and strength. Later the 
 appetite is lost, there is great weakness, and the wasted and enfeebled 
 animal may fall and be unable to again get upon its feet. 
 
 Course. — Horses invariably die in from one to several months after 
 the onset of the disease, though in some cases death may occur suddenly 
 in the early stages. In camels the disease runs a much longer course. 
 Cattle, though they may harbor the parasites in their blood, generally 
 resist the disease. 
 
 Infection. — A specific carrier of the organism causing surra is not 
 known. Tsetse flies are not found in Asia, but it has been determined 
 that the stable fly {Stomoxijs calcitrans) and the horsefly (Tabanus stri- 
 atus) of Asiatic countries can transmit the disease by their bite. It is 
 believed by some that the horsefly is the principal carrier. So far as 
 known the flies carry the disease from animal to animal directly by means 
 of contaminated mouth parts, and are unable to infect for more than 
 one or two days after having drawn the blood of an infected animal. 
 
 Mal De Caderas 
 
 Mai de caderas (disease of the hip) is a trypanosomiasis occurring in 
 horses throughout the greater part of South America, caused by Ti^y- 
 panosoma equinum, which was discovered by Elmassian in the blood of 
 horses in Argentina in 1901. The occurrence of the disease by natural 
 infection is almost exclusively among horses and mules, the former of 
 which are the more susceptible. A number of other mammals may be 
 successfully inoculated, among them the hog, rabbit, guinea pig, rat, and 
 mouse. 
 
 Symptoms. — Following a statement that, owing to its great ravages 
 in certain parts of South America, cattle have to be used for riding purpo- 
 ses, Laveran and Mesnil (Trypanosomes and Trypanosomiases, Eng- 
 hsh edition) describe the symptons of the disease as follows : 
 
 "The first sign of the disease in horses is wasting, which rapidly pro- 
 
THE PROTOZOAN SUBGROUPS 333 
 
 gresses in spite of a good appetite. The temperature is often raised to 
 104° to 105.8° F. After a varible time it is noticed that the hind quar- 
 ters are weak, and that the animal drags its legs, the hoofs grazing the 
 ground. These sj-mptons increase and become characteristic, so that 
 when the animal is made t > walk it staggers along, the hind quarters 
 swaying from side to side. On account of this sympton the name liial 
 de caderas, or disease of the hind quarters, has been given to the disease. 
 There comes a time when the animal is unable to stand; if in the stable, 
 it leans up against a wall or seeks other support; if in the open, it stag- 
 gers and falls. After thus falling to the ground an animal may still live 
 for several days if it be fed; otherwise the inevitably fatal end is 
 hastened bj' inanition." 
 
 Infection. — The mode of natural infection is not as yet known. The 
 observed fact that horses separated from affected animals only by a 
 fence remain healthy in spite of the presence of piercing flies, would indi- 
 cate that these insects are not the transmitters. Until something definite 
 is established as to the transmitting agent, no certain preventive meas- 
 ures can be adopted. 
 
 DOURINE 
 
 Dourine is an infectious disease of the horse and ass affecting prima- 
 rily the genital tract. It is due to Trypanosoma equiperdum, transmitted 
 from animal to animal in the act of copulation. The disease is vari- 
 ously^ named "maladie du coit," " el dourine," or " dourine," according 
 to the country in which it is found, dourine, which is from the Arabic for 
 "unclean," being the term most commonly employed for it in the United 
 States. It is supposed to have been introduced into Continental Eu- 
 rope early in the nineteenth century by horses imported for breeding, 
 especially those from the Orient where the disease has long existed. 
 
 In the United States dourine first appeared in Illinois where it was 
 recognized b}^ Dr. W. L. Williams in 1886. The source of the infection 
 was found to be imported Percheron stallion, and it had been dissemi- 
 nated for some time before the true nature of the malady became known. 
 By the application of rigid preventive measures, the disease was eradi- 
 cated from Illinois in 1888, but it had been carried by a stallion to Ne- 
 braska, where an investigation of an outbreak in 1892 by an inspector of 
 the Bureau of Animal Industry revealed that upward of two hundred 
 mares and stallions in the northwestern part of that state were aflfeeted 
 with the disease. Measures taken by the federal authorities brought this 
 outbreak under control for a time, but a few 3'ears later the infection 
 again appeared in the same part of the state. In 1901 there was an out- 
 break in the Pine Ridge and Rosebud Indian Reservations of South 
 Dakota, and in 1903 the disease was reported in Van Buren County, 
 Iowa. It was again found in Taylor County. Iowa, in 1911. Thus dour- 
 
334 PARASITES OF THE DOMESTIC ANIMALS 
 
 ine has appeared at various times within certain Hmits in the United 
 States. 
 
 Infection. — Dourine is a pecuhar trypanosomiasis in that there is 
 no intermediate carrier of the trypanosome specifically responsible for 
 it. Like the spirochete of human syphilis, it is inoculable by contact, the 
 infection usually occurring during the act of copulation, though reported 
 cases of the disease in geldings and in mares which have never had the 
 stallion would indicate that its transmission is not entirely by copulation. 
 It may be artificially transmitted to horses and to other susceptible 
 animals, as dogs and rabbits, by inoculation with blood from animals 
 affected. Sexual intercourse is, however, by far the most common means 
 of natural infection, the trypanosome reaching the blood by penetrat- 
 ing the intact mucosa of the genital tract. 
 
 Symptoms. — The symptoms of dourine as given by John R. Mohler 
 (Bureau of Animal Industry, Bulletin No. 142, 1911) are, with some 
 omissions, here quoted. 
 
 "There are many variations in the symptoms of dourine, and this is 
 particularly true of the disease as it occurs in this country. Two dis- 
 tinct stages may be noted which vary somewhat from those described 
 in textbooks, but probably no more than could be expected when 
 differences of climatic conditions and methods of handling are taken 
 into consideration. 
 
 "The first stage chiefly concerns the sexual organs, and therefore 
 differs somewhat in the male and female. In the second stage symptoms 
 indicating an affection of the nervous system are more prominent and 
 are not dependent on the sex of the animal. 
 
 "Following a variable period of incubation of from eight days to two 
 months, there is seen in the stallion an irritation and swelling about 
 the penis first noticed in the glans. This swelling extends throughout 
 the organ, and the penis may be continually protruded and frequent 
 ei-ections noticed. The edematous swelling also involves the groin, 
 with enlargement of the adjacent inguinal glands, and extends forward 
 along the abdomen. In a few days small vesicles or blisters appear on 
 the penis, which break, discharging a yellowish serous fluid and leaving 
 irregular raw ulcers. Where primary ulcers are in proximity to each 
 other there is a marked disposition to coalesce, a large raw surface with 
 irregular border resulting. The ulcerative process may form a wound 
 extending almost entirely around the penis. The ulcers show a tendency 
 to heal rapidly, leaving white cicatrices which are permanent. In some 
 cases the urinary meatus is very red and swollen, and according to some 
 observers, especially European, more or less thick catarrhal exudate 
 is discharged from its oriface. This condition, however, has been rarely 
 seen in cases in this country, a more or less continuous dripping from 
 the urethra of a yellowish serous-like discharge alone being present. 
 
THE PROTOZOAN SUBGROUPS 335 
 
 The stallion retains his full genetic instinct and becomes veiy amorous 
 when brought in the vicinity of mares. If allowed access to mares in 
 season, service is often impossible, due to the fact that a complete 
 erection of the penis does not occur. The testicles may be involved and 
 tender to pressui'e, and abscess formation may occur with sloughing. 
 
 "In the mare the first s>nnptoms may be so slight as not to be noticed 
 by the owner. The disease being the result of copulation, begins with 
 swelling and inflannnation of the vulva and vagina. The labia are 
 continuall}' everted, exposing the clitoris, which is constantly in a state 
 of erection. There will also be a muco-purulent discharge like that 
 coming from the penis of the male, which may be slight or profuse in 
 quantity. The mare will switch the tail, appear uneasy, and urinate 
 frequently. Shortly papules and vesicles appear on the external vulva, 
 as well as on the mucosa of the vulva and vagina. These vesicles soon 
 rupture, but before doing so the contents undergo a change from a 
 transparent to a purulent fluid. The rupture of these pustules is the 
 initial stage in the formation of deep, angry ulcers. These ulcers show 
 a tendency to heal rapidly, but invariably leave a cicatrix. On the dark 
 skin of the external vulva the scars will always be white. This de- 
 pigmentation is permanent. 
 
 '"Sometimes, especially in the mare, the above-described lesions tend 
 to disappear gradually, and in case the mare is not served again the 
 disease may remain in abeyance for months or a j-ear. The apparent 
 recovery, however, is not permanent, and any excessive work or excite- 
 ment may set up the disease anew. In case an affected mare conceives, 
 she is liable to abort at any time during her term of pregnancy. When 
 the fetus is carried to full term, it occasional^ is a weak or imperfectly 
 developed foal, but in this country many fine colts have been born to 
 affected mares. 
 
 "The nervous or constitutional disturbances of the second stage may 
 not come on for months or even a year after the appearance of the local 
 lesions, and are similar in both male and female. They consist of a 
 general nervous disorder with staggering, swaying gait, especially in 
 the hind limbs. The animal becomes extremeh' emaciated, particularly 
 in the hind quarters, and the abdomen assumes a "tucked-up" appear- 
 ance. The first indication of paralysis will be noted in traveling, when 
 the animal fails to pick up one of the hind feet as freely as the other. 
 There is a tendency to drag the foot partially. This condition may 
 shift from one hind foot to the other, or both may become affected 
 simultaneously. Twitching of the superficial muscles has been noticed 
 in several instances. Urticarial eruptions or plaques may break out 
 over various parts of the body, and there may be noticed pruritus of 
 the skin, which causes the animal to rub itself frequently. The tem- 
 perature of the animal seldom goes above 101° or 102° F. When the 
 
336 PARASITES OF THE DOMESTIC ANIMALS 
 
 paralysis of the hind Hmbs starts to appear, it usually progresses rapidly, 
 the horse goes down, is unable to rise, and dies in a short time from 
 nervous exhaustion." 
 
 Control. — As dourine is transmitted and spread only by copulation, 
 its eradication is a less difficult problem than in trypanosomiases which 
 may be carried by flies. So little benefit is to be derived from medicinal 
 treatment that in this country, where the disease has appeared only 
 in restricted areas, it is not advisable. While cure may be possible, 
 an apparently cured animal may carry the trypanosomes for months 
 in the sexual organs, and relapses are likely to occur. In areas where 
 the disease appears measures of eradication must be based upon the 
 prevention of infected animals from breeding. 
 
 To confine the losses to the minimum, therefore, the prompt castration 
 of affected stallions and the destruction of diseased mares is essential. 
 Spaying of such mares is not a sufficient precaution from the fact that 
 they may be sold and an attempt made to breed them, thus infecting 
 the stallion and through this source spreading the disease. Restrictions 
 in the movement of horses in infected districts and frequent reinspection 
 are further state and federal measures for confining an outbreak so far 
 as possible to its original limits. 
 
 Trypanosoma americanum. — This trypanosome is found in cultures 
 of blood from healthy American cattle. It deserves mention here on 
 account of its common occurrence, though it appears to be harmless. 
 A report by Crawley upon his extended study of this organism will be 
 found in Bureau of Animal Industry Bulletin No. 145 (1912). 
 
 Class III. Sporozoa 
 
 Protozoa (p. 311). — The Sporozoa are all parasitic. Though without 
 motile organs, they are capable of moving from place to place, in some 
 cases by means of pseudopodia. Reproduction is mainly by spore 
 formation, either asexual or sexual. There are a number of forms, 
 however, in which simple reproduction occurs, and the group comprises 
 organisms with life histories as yet not fully known. The Sporozoa, 
 therefore, is a division to be regarded as provisional, containing at pres- 
 ent organisms which when their life histories are fully made out may 
 be more accurately placed with other divisions of the Protozoa. 
 
 Based upon the belief that the Sporozoa are polyphyletic; that is that 
 all have not the same ancestral history, they have been placed in two 
 divisions, — Telosporidia and Neosporidia, the former regarded as 
 descended from the flagellates, the latter from the rhizopods. Of the 
 Telosporidia but two orders are to be considered here, — Coccidia and 
 Hemosporidia. The Neosporidia has one order, — Sarcosporidia, con- 
 taining parasites of domestic animals. 
 
THE PROTOZOAN SUBGROUPS 337 
 
 Order I. Coccidia 
 
 Sporozoa (p. 336). — The Coccidia are cytozoic or cell-infesting para- 
 sites, attacking epithelium of in\-ertebrate and vertebrate animals. Re- 
 production is by schizogony and by sporogony, the asexual and sexual 
 generations alternating in the life cycle. In species parasitic to domestic 
 animals the fertilized cell produces sporoblasts covered by a sporo- 
 cyst membrane. 
 
 Life History. — The life cycle is similar to that of the malaria organ- 
 isms except that no arthropod intermediate host is required for the 
 sexual reproduction. Infection with Coccidia is with the encysted stage 
 (oocj'st) by way of the mouth. Hence the parasites are almost exclu- 
 sively found in the epithelium of the aliment ry canal and organs con- 
 nected with it. Reaching the stomach and duodenum, the oocyst is 
 acted upon by the digestive juices and the sporozoites contained in the 
 cyst are hberated. These enter the epithelial cells of the mucosa. Within 
 the cells they lose their spindle form and enter the stage of the tro- 
 phozoite in which they grow to a size depending somewhat upon that 
 of the invaded cell. By the process of schizogony the trophozoite di- 
 vides into a number of small protoplasmic masses which are the mero- 
 zoites or asexually formed spores. These invade other cells and in the 
 same manner grow into another generation of merozoites. Bj^ many 
 repetitions of this cycle a large number of cells are invaded and de- 
 stroyed, and the death of the host animal may follow as a result. After 
 a number of asexual cycles some of the merozoites do not grow and di- 
 vide into another generation of merozoites, but develop into stages which 
 begin the sporogonous or sexual cycle. In this process the female tro- 
 phozoite instead of dividing develops into an egg or macrogamete. The 
 male trophozoite, by division, forms minute male repi-oductive elements 
 or microgametes. By their motility the microganietes reach and fer- 
 tilize the macroganietes which, becoming surrounded by a resistant 
 membrane, arrive at the stage of the oocyst. Within the oocj'st a num- 
 ber of spores may be formed, each inclosed in a protecting membrane 
 and constituting a sporocyst. By division each sporocyst forms two 
 or more sporozoites, and thus the sexual cycle is completed. Where the 
 parasites are in the epithelium of the alimentary tract or its comaiiu- 
 nicating organs, the oocysts pass to the exterior with the feces. In other 
 cases it may be that they can only reach the outside after the death and 
 disintegration of the host. 
 
 The effect of coccidiosis upon the animal is brought about by the ex- 
 tensive destruction of cells resulting from the repeated production of 
 merozoites by schizogny. This progressive reproduction and cell de- 
 struction would in every case result in the death of the animal were it 
 not that the number of schizogonous generations is limited. The cell 
 
Plate VI, Fig. 2. 
 
Plate VI. — Fig. 1. — Percheroii stallion, showiiifi condition at the time of purchase. 
 Fig. 2. Same stallion after dourine luul developed. Spot.s on side and croup give location 
 of plaques. (After Mohler, Bui. Xo. 142, Bu. An. Ind., U. S. Dep Agr.). 
 

 1 
 
 1 
 
 p 
 
 ■ 
 
 ■ 
 
 I 
 
 ■ 
 
 w 
 
 ■ 
 
 ■ 
 
 ■ 
 
 5^ 
 
 a 
 
 n 
 
 hHF^ j 
 
 
 
 1 
 
 i 
 
 i 
 
 II 
 
 h 
 
 i 
 
 
 
 f j 
 
 
 =i 
 
 
 
 
 
 ^ 
 
 1 
 
 
 -- 
 
 J 
 
 1 
 
 
 
 \:- 
 
 r 
 
 m^ 
 
 K^ 
 
 
 
 iS 
 
 i 
 
 £ 
 
 
 
 iaaia 
 
 Mi 
 
 
 ifJI^^BPff'-^'.^^v ' 
 
 
 i 
 
 1^ 
 
 
 ~T^ 
 
 ^ 
 
 k H^ 
 
 ■w 
 
 
 ""^^ 
 
 m 
 
 
 
 Plate VII, Fig. 
 
 Plate VII, Fig. 2. 
 
Plate VII. — Fig. 1. — Perclicron marc, showing chronic dourinc. Observe the "tucked 
 up" abdomen and emaciation, the mare having lost over 700 pounds in the previous four 
 months. Fig. 2. — A mare in the last stage of dourine. Notice the position of the off hind 
 foot and the straightened hock joints. (After Mohler, Bui. No. 142, Bu. An. Ind., U. S. 
 Dept. Agr.). 
 
342 PARASITES OF THE DOMESTIC ANIMALS 
 
 destruction ceases with the beginning of the sporogonous C3'cle, and, if 
 the acute stage of the disease is survived, the animal tends to recover, 
 the destroyed cells being replaced more or less completel}^ by newlj' 
 formed ones. Thus it maj^ be said that the disease is self-limiting. 
 Eimeria stiedae. — Coccidia (p. 337). — This coccidian, also known 
 as Coccidium oviforme and C. cuniculi, is the species commonlj^ found 
 in the Hver of domestic rabbits. Most frequently it attacks the epithe- 
 lium of the bile ducts where it causes destruction of cells and pathologic 
 changes in the Uver by which the secretion of bile is reduced. The con- 
 dition affects rabbits seriously and deaths occur as a result of it. 
 
 Eimeria stiedce is considered by some authors as a cause of coccidiosis 
 in man. 
 
 Diplospora bigemina (Isospora bigemina). Coccidia (p. 337). — In 
 a report upon their work with this coccidian Hall and Wigdor (Journal 
 of the American Veterinary Medical Association, April, 1918) state that 
 in two hundred dogs examined at Detroit, Michigan, it was found in 
 fifteen, or slightly over seven per cent. From this finding they suggest 
 that the parasite may be more common in American dogs than our pres- 
 ent lack of information would indicate. 
 
 In reference to the pathogenesis of Diplospora bigemina, these au- 
 thors may be further quoted from the same article as follows : 
 
 "As regards the pathological significance of D. bigemina, we have 
 but Httle information, but the following notes may serve some purpose: 
 Dog No. 130 presented a clinical picture of distemper and died of pneu- 
 monia, probably due in part to distemper and partlj' to an accident 
 in drenching. The small intestine showed diffuse hemorrhagic points, 
 most pronounced in the ileum, especially the lower ileum near the valve. 
 Scrapings of the mucosa showed the coccidia to be most abundant in the 
 ileum, less so in the jejunum and least so in the duodenum. These 
 findings of increasing numbers of coccidia with increasing severity 
 of lesions may be correlated, but in the absence of sections indicating 
 the relation of the coccidia to the hemorrhage, we do not care to hazard 
 a definite opinion. Dog No. 173 showed numerous fine petechiae in the 
 intestinal mucosa, and these were especally numerous in the Peyer's 
 patches, giving these a uniformly dark appearance. No sections were 
 made and this dog had shown no oocysts in the feces for fortj^'-five days. 
 Dog No. 127 showed innumerable pinpoint petechiae in the ileum, but 
 it would be unsafe to draw conclusions based on this one dog, as the 
 animal figured in other experiments. The intestine of dog No. 223 was 
 macroscopically normal except for the presence of hook-worm petechiae. 
 In view'of the fact that coccidia are destructive to epithelial tissue and 
 that some species fairly closel}^ related to D. bigemina are known to be 
 highly pathological, it would seem reasonable to suppose that D. big- 
 emina might be distinctly pathological at times, though the apparent 
 
THE PROTOZOAN SUBGROUPS 343 
 
 ?i;ood health and lack of post-mortem lesions in other do^s makes it cer- 
 tain that it often does no visible damage." 
 
 Coccidium zurni. Coccidia (p. 337). — Red dysentery of cattle is 
 attributed to this coccidian. The disease occurs in Europe, generally 
 among young animals as an enzootic. The attack of the parasites upon 
 the cells of the intestinal mucosa causes extei^sive hemorrhage, the red 
 diarrhea resulting fi-om the mixture of the blood with the feces. Mild 
 cases, particularly in adult animals, ma\' soon recover. Severe cases, 
 occurring particularly in young animals, may run a hyperacute course 
 and terminate fatally within two da\'S, or an acute course of five to ten 
 days may precede this termination. 
 
 In the report of the Committee on IVIedicine and Surgery submitted 
 at the meeting of the Pennsylvania State A'eterinary ^Vledical Associa- 
 tion, held in January, 1918, Dr. W. J. Uentz, of the University of Penn- 
 sylvania, called attention to cases of intestinal coccidiosis of cattle 
 which had come under his ol:)servation in the State of Delaware. His 
 report as published in the Journal of the American \'eterinary ]\Iedical 
 Association for November, 1918, follows: 
 
 "Was asked to consult with a vetermarian on an interesting condition 
 in a herd of grade Holsteins. Owner had lost four or five heifers over a 
 period of about two weeks, ranging in age from six months to eighteen 
 months. All presented similar s\anptoms. There was first noticed a 
 serous, fetid, black diarrhea. Fever was rarely in evidence at any time. 
 The diarrhea after a few days changed to mucus, with the passage of 
 blood clots with the mucus and feces from time to time. Straining was 
 very marked. Appetite somewhat impaired but. nevertheless, partook 
 of some food, but finally, in about six to eight days, became very dull, 
 refused food, emaciated rapidly, rectum became relaxed, temperature 
 subnormal, pulse hardly perceptible, and these sjnnptoms of collapse 
 were soon followed by death. On arrival at the farm found six to eight 
 calves and one adult cow presenting some of the s\nnptonis mentioned, 
 and, inasmuch as one was about to die, it was destroyed and posted. 
 Lesions were confined to the large intestine. No apparent pathological 
 change in anj- other organ. The mucous membrane of the large in- 
 testine, which was almost empty, was red brown in color, soft and 
 spong}', and everywhere coated with a bloody nmcus. The back of the 
 knife, after the intestine was slit open, was passed over the mucous 
 surface and the bloody mucus scraped off, when it was noticed that 
 large superficial ulcers, white in color, and about the size of one's palm, 
 were present throughout the whole extent of the large intestine from 
 the cecum to the anus. Some of the mucous patches were scraped off 
 and collected in a bottle, also some of the blood and feces. On micro- 
 scopic examination, coccidia were detected. A diagnosis of "intestinal 
 coccidiosis," or "red dvsentery," was therefore made. Treatment 
 
*c^^>^k^ 
 
 20 21 .'JB/Q 
 
 Uy& 
 
 ® 
 
 ^' 
 
 m 
 
 
 Platp: VIII, Fiu. 1. 
 
 Id I 
 
 . ;.'.-. 
 
 51. "~ 
 
 S*-' Ci 
 
 r^^^i 
 
 '"*f .W' ^^ ^'®^^W/:e^ 
 
 
 fif ^ ® 
 
 
 
 
 8^ 
 
 *<^^ 
 
 \ 4^^ ''A* 
 
 1+K® 
 
 
 ■^^ 
 
 10'' 
 
 %C 
 
 r.9'' 
 
 Plate VIII. Fig. 2. 
 
THE PROTOZOAN SUBGROUPS 345 
 
 Plate VIII. — Coccidian Life Cycle. — Fig. 1. 1. Sporozoite released in intestine of 
 host. 2. Penetration of sporozoite into epithelial cell. 3, 4. Growth of sporozoite into 
 trophozoite. 5, 6, 7. Schizogonous cycle. Nuclear division, followed by division of 
 entire trophozoite into a large number of merozoites. 8. Free mcrozoites, which for an 
 indeterminate number of generations merely repeat the schizogonous cycle, behaving 
 precisely as do the sporozoites. Eventually, however, the sporogonous cycle is initiated, 
 which proceeds as follows: 9a. Undifferentiated female cell. 9b. Undifferentiated male 
 cell. 10a. Differentiated female cell. 10b. Differentiated male cell. 11, 12. Formation 
 of the microgametes, one male cell producing many microgametes. 13a. Macrogamete. 
 One female cell produces but one macrogamete. 13b. Ripe microgamete. 14. Fertiliza- 
 tion. 15, 16, 17. The zygote. 18. Beginning of spore formation. 19. Completion of 
 spore formation. 20. Formation of the sporozoites within the spores. 21. Release of the 
 sporozoites in the intestine of the host. Fig. 2. — Introduced for comparison with the 
 more typical cycle shown in Fig. 1. Here the parasite penetrates and comes to rest in the 
 nucleus instead of the cytoplasm, and there is se.xual differentiation in the schizogonous 
 cycle as well as in sporogony. (After Crawley, from Mense's "Handbuch," after 
 Schaudinn, Cir. No. 194, Bu. An. Ind., U. S. Dept. Agr.). 
 
 suggested: Pearson's creolin well diluted with milk or water, also large 
 doses of camphorated tincture of opium, and rectal injections, using 
 garden hose and funnel, of a two per cent, creolin solution, alternating 
 night and morning with a one per cent, alum solution. A week later 
 received word that all were doing nicely and no deaths." 
 
 In Europe outbreaks of red dysentery similar to that of cattle have 
 occurred in sheep. 
 
 CocciDiAL Enteritis of Chicks 
 
 The use of the name "white diarrhea" for this coccidiosis tends to its 
 confusion with bacillary white diarrhea, which is a fatal septicemia of 
 chicks caused by Bacterium pulloruni. Coccidial enteritis or coccidiosis 
 of chicks is caused hyEimeria avium (Coccidium tenelhim), which attacks 
 the epithelium of the intestinal mucosa, usually that of the ceca. Occa- 
 tionally the infection is found in other organs. The disease is usually 
 seen in chicks from two to ten weeks old. 
 
 Symptoms. — The symptoms are merely suggestive of coccidiosis as 
 they do not materially differ from those of some other diseases of poul- 
 try. The affected chicks droop and are inclined to stand about by them- 
 selves with eyes closed and feathers ruffled. In most all cases there is a 
 diarrhea with whitish-colored discharge which stains and mats the 
 feathers below the vent; a bloody diarrhea gives evidence of coccidial 
 infection. If the discharge is examined under the microscope large 
 numbers of circular or slightly oval oocysts may be found. Death usually 
 occurs after a course of three to four da3'S. 
 
 Post-morten Appearance. — Post-mortem examination reveals the 
 ceca much enlarged. Their contents may be normal or they may be 
 packed with a yellowish white or bloody semiliquid material. The 
 conclusion that the chicks are not infected with coccidia should not be 
 made from the absence of enlarged ceca, as occasionally there is no 
 
346 PARASITES OF THE DOIMESTIC ANIMALS 
 
 enlargement of these organs nor abnormal appearance of their contents. 
 Not infrequently the enteritis involves the entire length of the intestines. 
 For a positive diagnosis microscopical examination of the intestinal 
 contents or of the sectioned intestinal wall is necessary. Spreads of 
 scrapings from the cecal mucosa examined under the microscope will 
 reveal epithelial cells much distended by the development of the par- 
 asites within them. It is as a result of this invasion that the cells finally 
 break down and separate from the underlying stroma to become a part 
 of the pasty catarrhal exudate which characterizes the fecal discharge. 
 
 Infection. — Though the fatalities are usually among the young 
 chicks, the coccidian which causes the disease may be found in chickens 
 of all ages and it ma}^ be spread from this source. Infection is by food 
 and ingested soil or water contaminated by droppings which contain 
 the cysts. It has been demonstrated that the cysts may remain infective 
 for a year or more, therefore chickens may become infected if allowed 
 access to yards where those harboring the parasites were kept the year 
 previous. 
 
 Control. — There are no drugs which have been found to be of value 
 in treating the disease, therefore control is the essential consideration in 
 contending with it. Morse states (Bureau of Animal Industrj^ Cir- 
 cular No. 128, 1908) that this must begin with the eggs used for hatching. 
 "These," he writes, "should be thoroughly and antiseptically cleaned 
 bj^ wiping in ninety-five per cent, alcohol. If artificial incubation is 
 used (and in this method lies the great hope of success), the incubator, 
 if used before, should, previous to receiving the eggs, be carefully washed 
 with antiseptic solutions and exposed to the sun. The egg tray should 
 be scalded or flamed. The floor of the nursery should be movable, so 
 that it may be taken out and sterilized, and if made of burlap the old 
 piece should be torn off and a new piece mounted on the sterilized frame. 
 The same precautions should be used with the brooders. The soil to 
 which the chicks have access should be well covered with lime, dug up, 
 and exposed to the drying effects of the sun and air. If natural in- 
 cubation is practiced the hen for a week or two before being set should 
 be treated with one-quarter to one-half grain doses of sulphate of iron 
 daily, with occasionally an active purgative, such as calomel, one grain, 
 or castor oil, one-half teaspoonful containing five to ten drops of tur- 
 pentine. The eggs, cleansed as directed above, should be placed in a 
 perfectly fresh nest, which may be sprinkled from time to time with a 
 little hme. After hatching, the hen with her chicks should be placed 
 upon ground that has been thoroughly sterilized, as described above, 
 and at least every few days moved to fresh ground which has been 
 treated in the same way and from which all chickens have been de- 
 barred." 
 
 Further preventive measures are the removal of visibly sick chicks 
 
THE PROTOZOAN SUBGROUPS 347 
 
 from the flock, either keeping them isolated or killing and burning them. 
 It is better to put all of the chickens on new ground if possible, other- 
 wise the ground should be covered with lime and spaded so that it may 
 be exposed to the drying effect of the sun and air. All litter and nesting 
 should be burned and a thorough cleaning up of the quarters followed 
 by the application of a strong disinfectant solution. After drying, 
 the floors may be protected from rccontamination somewhat b,y covering 
 them with shavings, chopped bedding, or other absorbant material, 
 which is to be cleaned up and burned dail}'. Boards should be placed 
 beneath the roosts to receive the droppings for convenient daily removal. 
 Contamination of feeding and drinking vessels can in a measure be pre- 
 vented b}^ elevating them somewhat from the grountl. They should at 
 all times be kept clean; daily treatment with scalding water or flaming 
 followed by exposure to the sun will do much to eliminate the soiu'ce 
 of the infection. 
 
 Order II. Hemosporidia 
 
 Sporozoa (p. 336). — The Hemosporidia are Sporozoa which dwell in 
 the blood where they invade the corpuscles, hence are cytozoic. Flag- 
 ellated stages appear in their life history, and many protozoologists 
 suspect that the entire group has been evolved from the flagellated 
 Protozoa. Comparing the life history of the malaria organisms (p. 318) 
 with that of the Coccidia (p. 337) a distinct difference will be noted in 
 the method of infection, the hemosporidian, as is true of others of the 
 group, being transmitted from the blood of one animal to that of an- 
 other by means of a known intermediate host, while the Coccidia infect 
 directly, usually by food or water bearing the cysts. In diseases caused, 
 by Hemosporidia, the infection, due to the activities of the intermediate 
 host, is more widel}^ disseminated, and large numbers of animals may 
 be seriously and fatally attacked. As blood parasites, therefore, the 
 Hemosporidia may be rated with the tiypanosomes in pathologic im- 
 portance. 
 
 Texas Fever 
 
 Tick fever. Splenic fever. 
 
 Smith and Kilbourne in 1893 foimd small parasites in the red blood 
 corpuscles of cattle suffering with Texas fever. Due to their frequent 
 occuri-ence in pairs, the}' were given the specific name higeminum, and the 
 genus was named Pyrosoma. The later generic name Piroplasma was 
 derived from their often assuming a pear-like form, and the name now 
 generalh' used for the hemosporidian causing Texas fever is Piroplasma 
 higeminum (Fig. 171). 
 
 The medium by which the organism is transmitted is the cattle tick 
 Margaropus annulafus. which crawls upon its host as a larva, attaches, 
 
348 PARASITES OF THE DOMESTIC ANIMALS 
 
 and here undergoes its complete development. (Ref . Margaropus annul- 
 atus, Life History, p. 148.) For a number of days following her fer- 
 tilization the female tick engorges with the blood of her host and then 
 drops to the ground where a few clays later she deposits her eggs and, 
 having completed her cycle, soon dies. The parasites contained in the 
 blood upon which the tick has fed reach the eggs and 
 are present in the larval ticks when these are hatched. 
 Thus the larvae have the power to infect any susceptible 
 animal to which they attach. 
 
 In the first stage of development after gaining the 
 circulation the piroplasma is within the red corpuscle 
 as a single body near the corpuscle's margin. Later it 
 Piroplasma^ Tig- "^^^^i^^^^s into two bodics which remain slightly connected 
 eminum (after by a Small filament. A single corpuscle may contain as 
 Crawley, from many as four or even six parasites. The doubled bodies 
 
 Doflem, Cir. No. i • • n i i i i j 
 
 194, Bu. An. ind. enlarge, assummg a spmdle-shaped and later a pear- 
 u. s. Dept. Agr.) shaped appearance. Finally, as a result of this invasion, 
 the corpuscles break down, and the parasites become 
 free bodies in the plasma. That a multiplicative stage occurs within 
 the bovine host is evidenced from the fact that inoculation of sus- 
 ceptible cattle with a small quantity of virulent blood will produce the 
 disease with the development of myriads of the parasites in the blood of 
 the inoculated animals. 
 
 Occurrence. — Numerous attempts have been made to produce Texas 
 fever in other species of animals by inoculating them with infected blood 
 from cattle. That all of these experiments have proved negative in- 
 dicates that the disease is one purely bovine. All bovine animals that 
 have never been exposed are susceptible, and in all cases natural in- 
 fection with the protozoan causing the disease is due to puncture by 
 the cattle tick. 
 
 The disease exists in European and Asiatic countries, Africa, Australia, 
 and the Philippine Islands. It was probably introduced into the United 
 States by cattle brought over by the early Spanish settlers. The terms 
 " Texas fever " and " southern cattle fever " are misleading to some in 
 giving the impression that the disease is confined to the Southern States. 
 Southern cattle carrying the infecting organism in their blood, though 
 themselves possessing degrees of immunity to Texas fever, disseminate 
 it through ticks from their bodies among cattle in the North or among 
 those of the South which are susceptible to the disease in a virulent 
 form. 
 
 Exposure and Development. — The period from exposure to tick in- 
 fested pastures or pens to the appearance of the disease depends upon 
 the time which elapses from the dropping of the female ticks from the 
 southern cattle to the hatching of the larvae from their eggs, and this 
 
THE PROTOZOAN SUBGROUPS 349 
 
 will be influenced by climatic conditions. If the larval ticks are already 
 present and at once attach to the exposed animals symptoms of the fever 
 may develop ten to twelve days later. Where the susceptible animals 
 are placed upon pastures, in pens, or other places immediately after 
 these have been infected with ticks from southern cattle, a period must 
 intervene covering egg-laying and hatching of the larvae before the 
 northern animals become inoculated. In sununer this period may oc- 
 cupy from twenty to forty days; in cooler weather it takes longer for the 
 eggs to hatch, and under such conditions sixty daj'S or longer may be 
 required before the infective generation of ticks appears. Thus, de- 
 pending upon season and temperature, the disease may appear in twelve 
 days to two or three months after exposure (see life histor>' of Texas 
 fever tick, page 148). 
 
 Symptoms. — Two distinct types of Texas fever are presented, — an 
 acute fatal and a chronic form, from the latter of which the animals 
 usually recover. Whether the fatal or the milder type appears will de- 
 pend upon season and the susceptibilty of the animals. When northern 
 cattle and those raised in tick-free districts in the South are attacked in 
 the hot weather of summer, the acute form occurs. If the susceptible 
 animals are affected in the latter part of autumn the milder chronic spn- 
 ptoms appear, and it is bj' this type of the disease that partly immune 
 southern cattle are affected at any season, the fatal form rareh' attack- 
 ing these animals. 
 
 The Acute Type. — In this form of the disease the onset of the symp- 
 toms is rapid. The animal is depressed and stands or lies down apart 
 from the held, there is loss of appetite and rumination ceases. The tem- 
 perature rises within twenty-four to forty-eight hours to 107° or 108° F., 
 the fever accompanied by increase in the rate of pulse and respiration. 
 During the early stages of the disease there is constipation which 
 is generally followed by diarrhea. The hemoglobin released by the 
 disintegration of the corpuscles causes a blood-stained urine (hemoglobi- 
 nurea), from which symptom is derived the name "red water," some- 
 times given to the disease. Cerebral disturbances, exhibited by stag- 
 gering, disorders of vision, or delirium, may appear in some cases. A 
 conclusive diagnosis may be made upon finding the parasites within the 
 corpuscles by microscopic examination of the blood. 
 
 A fatal termination is usually reached within three or four days. If 
 recovery occurs, it is much prolonged, due to the time required for the 
 generation of new corpuscular elements to replace those destroyed. 
 
 The Chronic Type.— The difference in the symptoms of the chronic 
 type of the disease from those of the acute is one of degree. Further, 
 there is a seasonal difference, the milder chronic form usually appearing 
 in the late fall and early winter, the acute in the hot sununer months. 
 The temperature does not go as high, remaining at about 103° F. and 
 
350 PARASITES OF THE DOMESTIC ANIIVIALS 
 
 not exceeding 105° F. The anaemic condition is indicated by the paleness 
 of the visible mucosae, and the extended course brings about great 
 emaciation. In these cases hemoglobin is not usually passed with the 
 urine, hence hemoglobinurea or ''red water," typical of the acute form, 
 is absent. 
 
 Death rarely occurs in this type of the disease, though, due to its 
 prolonged course and the excessive loss of flesh, much loss is sustained 
 in the productive valuation of the animal. 
 
 Prevention and Treatment. — Prevention is by measures dealing 
 with the cattle tick Margaropus annulatus, which is the specific carrier 
 and transmitter of the protozoan causing the disease. As study of the 
 life histoiy of this tick has shown that it will not mature except upon a 
 bovine or equine host, it follows that it can be exterminated from in- 
 fested pi-emises by keeping cattle and horses off of such premises until 
 the larval ticks, unable to find a host, have perished. With this purpose 
 in view, systems of pasture rotation have been devised additional to 
 methods directed toward the destruction of ticks on the cattle (Ref. 
 Margaropiis annulatus, p. 145). 
 
 Medical treatment of animals sick with Texas fever has not proved 
 satisfactory. In the milder type of cases the constipation may be re- 
 lieved somewhat by Epsom salts. Repeated doses of digitalis during 
 the excessive anaemia and the administration of tonics, such as gentian 
 and nux vomica, during the stage of convalescence, have been recom- 
 mended as beneficial. The recovering animal should have free access 
 to pure water and a generous supply of nutritious food. 
 
 Order III. Sarcosportdia 
 
 Sporozoa (p. 336). — The Sarcosporidia are parasites in striated 
 muscle cells of vertebrates. Sporulation takes place during the develop- 
 ment of the trophozoite which becomes surrounded by a protective 
 envelope. 
 
 These muscle parasites are found in man, in domestic and wild birds, 
 and are common in domestic mammals. The muscles more commonly 
 invaded are those of the upper part of the esophagus, larynx, the body 
 wall, the diaphragm, and the psoas muscles. 
 
 Development. — Within the muscle fiber the parasite first appears as 
 a minute body in which stage it is known as Miescher's tube. As the 
 young ti'ophozoite develops it becomes multinuclear and surrounded by 
 a membrane, while groups of spores form in the center of the proto- 
 plasmic body. With the continuation of the spore formation the cyst 
 enlarges, causing such distension of the muscle fiber as to result in its 
 rupture, releasing the cyst which ultimately bursts, the spores thus 
 becoming scattered to infest new muscle cells. By repetitions of this 
 
THE PROTOZOAN SUBGROUPS 
 
 351 
 
 auto-infective process the entire skeletal musculature may become 
 affected. More or less destruction of muscle tissue is thus brought 
 about which necessarily is relatively injurious to the host; furthermore, 
 the effect is contributed to by the extremely toxic nature of the parasites 
 themselves. 
 
 Importance of Sarcosporidiosis and Mode of Infection. — Hosts show- 
 ing high incidence of infection with Sarcosporidia among domestic 
 animals are pigs, sheep, cattle, and horses, the infecting species in each 
 case being Sa7-cocys(is miescheriana occurring in pigs, S. tenella in sheep. 
 
 Fk;. 172. — Various foini.s of Sarcospoiiilia. _'. S:iii(h\ >tis lilani-hanli. Longidtudinal 
 section of an infected muscle with yount; iiidi\i(lual (after Ciawley, from Doflein, from 
 VanEeckc, Cir. No. 194, Bu. An. Ind., U. S. Dept. Agr.). 3. Sarcocystis tenella in a 
 Purkinje cell of the heart of a sheep (after Crawley, from Doflein, from Schneidemuhl, 
 Cir. No. 194, Bu. An. Ind., U. S. Dept. Agr.). 4. Sarcocystis tenella in the wall of the 
 esophagus of a sheep (after Crawley, from Doflein, from Schneidemuhl, Cir. No. 194, Bu. 
 An. Ind., U. S. Dept. Agr.). 5. Sarcocystis muris in muscles of mouse (after Crawley, 
 Cir. No. 194, Bu. An. Ind., U. S. Dept. Agr.). 
 
 S. hianchardi in cattle, and S. berirami in horses. In these animals the 
 infection has been considered as of little pathologic importance; the 
 sarcosporidiosis is apparently never fatal, and it is rare to find an animal 
 visibly affected. This conclusion, however, may be modified somewhat 
 by further study of the parasite, warranted b}' its prevalence, toxicity, 
 and possibly greater pathologic import than at present supposed. 
 Up to the present time little has been brought to light as to the life his- 
 
352 PARASITES OF THE DOMESTIC ANIMALS 
 
 toiy of the Sarcosporidia or as to the mode by which they infect. They 
 are known to be fatal to mice, and it has been found that when mice are 
 fed upon the flesh of other mice containing Sarcosporidia they become 
 infected. Hence the conclusion follows that natural transmission occurs 
 in these animals through their habit of nibbling at their dead; but this 
 method of transfer can hardly be considered in the case of sheep, cattle, 
 and horses, and the mode of infection in these animals remains a prob- 
 lem. 
 
 In an article upon the Sarcosporidia encountered in Panama (Journal 
 of Parasitology, March, 1915), Darling suggests that these muscle 
 parasites of vertebrates are aberrant forms of the Neosporidia of in- 
 vertebrates, and points to the facility with which herbivora may in- 
 g3st Neosporidia with leaves and other vegetation bearing infected 
 invertebrates and their droppings. "Is it not possible," Darling writes, 
 "that Sarcosporidia may be sidetracked varieties of some of the Neo- 
 sporidia of invertebrates which have invaded the musculature of a 
 hospitable though b}^ no means definitive host and are unable to con- 
 tinue further their life cycle and escape from a compromising and aber- 
 rant position?" The high incidence of infection among sheep, cattle, 
 horses, and swine is evidence favoring this explanation. 
 
GLOSSARY 
 
 Aberrant. In botany and zoiilogy, differing in some of its characters from the group 
 
 in which it is placed. 
 Acari. Arthropods of the order Acarina; mites and ticks. 
 Acaricide. A medicinal agent used to destroy acari. 
 Agamous. In zoology, having no distinguishable se.xual organs. 
 Amorphous. Without definite form; shapeless. 
 Ambulatory. Formed or adapted for walking. 
 Ametabolic. Pertaining to insects and other animals which do not undergo a 
 
 metamorphosis. 
 Anorexia. Loss or absence of appetite. 
 
 Antenna. A segmented process on the head of insects, myriapods, and crustaceans. 
 Anthelmintic. A medicinal agent used to destroy or expel worms from the intestinal 
 
 tract. 
 Apodal. Without feet. 
 Apterous. Without wings. 
 Aquatic. Growing in or frequenting water. 
 Arboreal. Attached to or frequenting trees. 
 Arista. A tactile filament at the end of the antenna of an insect. 
 Article. A segment or part of the body connected by a joint with another segment 
 
 or part. 
 Asexual. Having no sex. 
 
 Basis capituli. Basal portion of the capitulum or head of a tick. 
 Biiid. Cleft or divided into two parts. 
 
 Bisexual. Having the organs of both sexes in one individual. 
 Buccal. Pertaining to the cheeks or mouth cavity. 
 Budding. A method of reproduction by which a protuberance from the parent 
 
 organism develops into a new organism. 
 Bursa. A sac or sac-like cavity. 
 Capitulum. The head of a tick. 
 
 Caryozoic. Pertaining to parasites which live in the cell nucleus. 
 Catalepsy. Suspension of sensibility and voluntary motion. 
 Caudal. Pertaining to the tail. 
 Cephalic. Pertaining to the head. 
 
 Cephalothorax. The fused head and thorax of arachnids. 
 
 Chelae. Pincer-like terminations of certain of the limbs of crustaceans and arachnids. 
 Chelate. Terminated by chela?. 
 Chitin. The horny substance forming the harder part of the integument of insects 
 
 and other arthropods. 
 Cilia. Hair-like processes, as of a cell, capable of vibratory movement. 
 Coelom. The body-cavity, as distinguished from the intestinal cavity; the periaxial, 
 
 perivisceral, or perienteric space. 
 Ccelozoic. Pertaining to parasites which live in the ccclomic cavities of the body. 
 
354 GLOSSARY 
 
 Coxa. The hip or hip joint. In insects and other arthropods the first segment of 
 the leg from the body, articulating with the second segment or trochanter. 
 
 Cystogenous. Producing or bearing cells. 
 
 Cytozoic. Pertaining to parasites which live within the cell cytoplasm. 
 
 Dentate. Having a toothed margin or tooth-like projections. 
 
 Denticulate. Having very small tooth-like projections. 
 
 Dimorphism. The pi'operty of assuming or of existing under two distinct forms. 
 
 Dipterous. Having two wings; belonging to the insect order Diptera. 
 
 Dorsum. The dorsal surface or back of an animal. 
 
 Ecdysis. The process of casting the skin; molting. 
 
 Elytra. The fore-wings of beetles, serving to cover the hind wings. 
 
 Enterozoic. Pertaining to parasites which live in the lumen of the digestive tract. 
 
 Epimeron. One of the side-pieces in the segment of an arthropod animal. 
 
 Facet. A smooth, flat, circumscribed surface. 
 
 Fauna. The aggregate of the animals of a given region or geological period. 
 
 Femur. The thigh bone. The third segment of the leg of an insect, articulating 
 proximally with the trochanter and distally with the tibia. 
 
 Filiform. Thread-like. 
 
 Fission. Reproduction by division of the body into two parts, each of wliich be- 
 comes a complete organism. 
 
 Flagellum. A whip-like appendage or process of a cell. 
 
 Flora. The aggregate of the native plants of a given region or period. 
 
 Gamete. A sexual cell or germ cell. 
 
 Gametocyte. An adult parasite, as in the Plasmodium of malaria, when in its 
 reproductive form. 
 
 Granular. Consisting of grains or granules. 
 
 Gregarious. Inclined to gather together, as to live in flocks or herds. 
 
 Habitat. The natural abode of an animal or plant. 
 
 Halteres. The rudimentary hind wings of Diptera; balancers. 
 
 Haustellum. A proboscis adapted to take food by suction, as in many insects. 
 
 Hematozoic. Pertaining to parasites which live in the blood. 
 
 Hemelytra. The partially thickened anterior wings of certain insects. 
 
 Hermaphroditism. The union of the two sexes in the same individual. 
 
 Hexacanth. The sLx-hooked tapeworm embryo; the onchosphere. 
 
 Hexapod. A six-footed animal; a true insect. 
 
 Hyaline. A glassy or transparent substance or surface. 
 
 Imago. The final or adult stage of insects. 
 
 Infundibuliform. Having the form of a funnel. 
 
 Labium. In insects, the lower lip, formed by the second pair of maxillae. 
 
 Labrum. In insects, the upper lip. 
 
 Lobe. A somewhat rounded projection or division of an organ or part. 
 
 Macrogamete. The large female gamete or germ cell. 
 
 Macrogametocyte. The female gametocyte. 
 
 Mandibles. In arthropods, the anterior pair of mouth parts which form biting jaws. 
 
 Marine. Living in the sea. 
 
 Maxillae. In arthropods, paired appendages behind the mandibles, usually serving 
 as accessoiy jaws. 
 
 Merozoites. Asexually formed spores of the malaria parasite. 
 
GLOSSARY 355 
 
 Mesothorax. The middle segment of the thorax of an insect. 
 
 Metabolism. The processes concerned in the building up of protoplasm and its 
 
 destruction. 
 Metamere. One of a series of segments composing the body, as in many worms 
 
 ;iii(l in arthropods. 
 Metamorphosis. Change of form or structure, as in the larval, pupal, and imago 
 
 stages of an insect's development. 
 Metaphyta. Plants consisting of many cells; all plants above the Protophyta. 
 Metathorax. The posterior segment of the thorax of an insect. 
 Metazoa. Animals which, in an embryonic condition, possess at least two distinct 
 
 germinal layers; all animals above the Protozoa. 
 Microgamete. The male germ cell consisting of a detached flagelliform process of 
 
 a niirrogametocyte. 
 Microgametocyte. The parent male cell. 
 
 Micron. One thousandth of a millimeter; a unit of microscopic measure. 
 Molting. The shedding of the hair, feathers, or outer layer of the skin, which are 
 
 replaced by new growth. 
 Morphology. The science of the outer form and internal structure of animals and 
 
 l)Iants. 
 Myasis. A disease caused by the presence of the larvte of flies in or on the body. 
 Myiasis. Same as myasis. 
 Myiosis. Same as myasis. 
 
 Ocellus. A small simple eye of many invertebrates. 
 Octopod. Having eight feet, as in adult arachnids. 
 Onchosphere. The tapeworm embryo; the hexacanth. 
 Ookinete. Same as zygote. 
 Oospore. Same as zygote. 
 Operculum. A lid-like process or part. 
 Ovum. An egg cell or egg. 
 Ovigerous. Egg bearing. 
 Oviparous. Producing eggs that hatch after they have passed from the body of the 
 
 l)arent. 
 Oviposition. The laying of eggs, especially applied to insects and arachnids. 
 Ovipositor. A specialized organ, as in certain insects, for depositing eggs. 
 Ovoviviparous. Producing eggs that have a well developed shell or covering, as in 
 
 oviparous animals, but which incubate within the body of the parent. 
 Ovulation. The formation of eggs in the ovary; the discharge of the egg or eggs 
 
 from the ovary. 
 Palpi. Appendages, usually organs of touch or taste, attached to the mouth parts 
 
 of insects and other arthropods. 
 Papilla. A small nipple-like or pimple-like projection. 
 Parasiticide. A remedy that destroys parasites. 
 Parthenogenesis. The production of individuals from ova without fertilization by 
 
 tlic male element. 
 Pedipalpi. Leg-like or pincer-like appendages of arachnids, located on each side of 
 
 the mouth. 
 Phylogenic. Pertaining to the ancestral history of an animal or plant. 
 Phytozoon. A colony of animals resembling a plant. 
 
356 GLOSSARY 
 
 Plasmodium. A mass of protoplasm formed by the union of two or more amebiform 
 
 bodies or individuals. 
 Plumose. Feathery; plume-like. 
 
 Pollenose. Bearing a powdery or pollen-like substance. 
 Predacious. Living bj' prej-ing on other animals. 
 Prehensile. Adapted for gi-asping. 
 Proboscis. The tubular process of the head, especially of insects and arachnids, 
 
 adapted for sucking or piercing. 
 Proglottid. The segment of a tapeworm. 
 Pro thorax. The anterior segment of the thorax of an insect. 
 Protophyta. The division of unicellular plants. 
 Protozoa. The phylum consisting of the unicellular animals. 
 Pruritus. An intense degree of itching. 
 Pseudopodia. Processes of the protoplasm of a cell which may be protruded or 
 
 retracted, as for locomotion or for taking food. 
 Pubescent. Arrived at puberty, or the earliest age at which the reproductive func- 
 tion can be performed. 
 Puparium. The case in which an insect is enclosed between its larval stage and 
 
 the state of full development or imago. 
 Pupiparous. Pertaining to insects in which the young are born ready to become 
 
 pupse, as in the sheep tick. 
 Quiescent. At rest. 
 
 Rostellum. A small beak or hook-like process. 
 Rostrum. A beak-like process or appendage. 
 
 Saproph5rte. Any vegetable organism living on dead or decaying organic matter. 
 Schizogenesis. Reproduction by fission. 
 Schizogony. Same as schizogenesis. 
 Schizont. A malaria parasite of the asexual generation. 
 Scolex. The head of a tapeworm, either in the larval or adult stage. 
 Scutum. The dorsal shield or plate, present in certain ticks. 
 Serrate. Notched or toothed on the edge. 
 Somatic. Pertaining to the body as a whole. 
 Somite. One of the longitudinal segments into which the body of annelid worms, 
 
 arthropods, and vertebrates is divided. 
 Spiracle. A breathing orifice, as in the tracheal openings of insects. 
 Spore. A germ or seed of one of the lower animals or plants. 
 Sporocyst. A case or cyst containing many spores. 
 Sporogenesis. Reproduction by means of spores. 
 Sporogony. Same as sporogenesis. 
 Sporozoite. One of the young active spores of a sporozoan produced by division of 
 
 the passive spores contained in the sporocyst. 
 Sporulation. Spore formation. 
 Stigmata. Small spots or marks; usually applied to the respiratory openings of 
 
 insects; spii-acles. 
 Strobila. An adult tapeworm. 
 Suctorial. Adapted for sucking. 
 Tarsus. In insects, the small segments forming the distal termination of the leg 
 
 and articulating with the tibia. 
 
GLOSSARY 357 
 
 Tergum. In zoology, the back. 
 
 Terrestrial. Of or inhabiting the land or ground in distinction from trees, water, etc. 
 
 Tibia. In insects, the fourth segment of the leg, articulating proximally with the 
 
 femur and distally with the tarsi. 
 Tracheae. The air-conveying tubules forming the respiratory system of insects and 
 
 other arthropods. 
 Trenchant. Sharp; cutting. 
 Trochanter. In insects, the second segment of the leg, ai-ticulating proximally with 
 
 the coxa and distally with the femur. 
 Vacuole. A cavity or vesicle in cell protoplasm. 
 Vermicide. A substance which kills worms; a drug to kill parasitic worms of the 
 
 intestines. 
 Vermifuge. A medicine that expels worms from the bodies of animals. 
 Verminous. Infested with worms, or caused by worms, as verminous diseases. 
 Viviparous. Producing living young by true birth, as in mammals, and not by 
 
 hatching from eggs, as in oviparous and ovoviviparous animals; often applied 
 
 to the bringing forth of young which have been hatched from eggs within the 
 
 body of the parent. 
 Zoophyte. Same as phytozoa. 
 Zygote. The encysted stage of certain sporozoans after fertilization by a sperm 
 
 cell and before division into spores. 
 
INDEX 
 
 Acanthia lectularia, 90 
 Acanthocephala, 217, 224, 300 
 Acariasis, 96 
 Acarina, 94 
 
 parasitism of, 95 
 Ades calopus, 29 
 Agriostomum, 280 
 Amblyonima, 142 
 
 americanuni, 145 
 Ameba,312,324 
 
 budding, 313 
 
 ectoplasm, 312 
 
 encystation, 313 
 
 endoplasm, 312 
 
 fission, 313 
 
 method of feeding, 313, 324 
 
 morphologic characteristics, 312 
 
 motility, 312, 324 
 
 nucleus, 313 
 
 pseudopodia, 312, 324 
 
 reproduction, 313, 324 
 
 respiration, 313 
 
 streaming of cytoplasm, 312, 313, 
 324 
 
 vacuoles, 312, 313 
 Ameba meleagridis, 325 
 Amebic dj'sentery, 326 
 
 in man, 326 
 American dog tick, 143 
 Amphistomidse, 157, 167 
 Amphistomum cerv'i, 167 
 Ankylostoma, 280 
 
 canina, 291 
 
 duodenale, 292 
 Ankjdostomeae, 280 
 Ankylostomiasis, 291 
 Ankylostomimi stenocephalum, 292 
 
 Annelida, 224, 307 
 Anopheles, 26, 320 
 
 maculipennis, 26 
 
 punctipemiis, 2S 
 
 c^uadrimaculatus, 26 
 Anoplocephala mamillana, 175 
 
 perfoliata, 174 
 
 plicata, 175 
 Anthelmintics, use and action 
 
 of, 221 
 Apterous insects, IS 
 Arachnida, 94 
 
 classification of, 96 
 Arduenna, 228 
 
 strongylina, 251 
 Arduenninae, 228 
 Argasidae, 97, 139 
 Argas americanus, 139, 327 
 
 miniatus, 139, 327 
 Arthropoda, The, 13 
 
 circulatory system, 14 
 
 digestive system, 14 
 
 excretory organs. 14 
 
 musculature, 14 
 
 nervous system, 14 
 
 reproduction, 15 
 
 res]Dirator}' system, 14 
 
 sense organs, 15 
 
 structure in general, 13 
 Arthropoda as transmitters of infec- 
 tious diseases, 313, 315 
 Arthropoda, parasitic subgroups of 15 
 Ascariasis, 229, 231 
 
 importance of treatment, 233 
 
 location of wonns, 229, 232 
 
 occurrence, 231 
 
 pathogenic influences, 232 
 
360 
 
 INDEX 
 
 Ascariasis of the cat, 237 
 
 occurrence, 239 
 
 treatment, 239 
 Ascariasis of the dog, 237 
 
 occurrence, 238 
 
 post-mortem appearance, 239 
 
 treatment, 239 ■ 
 Ascariasis of the hog, 239 
 
 effect, 240 
 
 treatment, 241 
 Ascariasis of the horse, l33 
 
 control, 234 
 
 etiology, 234 
 
 occurrence, 233 
 
 sj-mptoms, 233 
 
 treatment, 234 
 Ascariasis of the ox, 241 
 Ascariasis of the sheep, 241 
 Ascaridffi, 222, 229 
 
 parasitism of, 229, 231 
 Ascaris, 225, 229 
 
 equi, 233 
 
 equorum, 233 
 
 lumbricoides, 229, 239 
 
 marginata, 237 
 
 megalocephala, 233 
 
 mystax, 237, 239 
 
 ovis, 229, 239 
 
 suis, 229, 239 
 
 suum, 229, 239 
 
 vitulorum, 241 
 Ascaroidea, 225 
 
 Auricular mange of the cat, 118 
 Auricular scabies of the rabbit, 118 
 
 B 
 
 Bacillary white diarrhea of chicks, 345 
 Bacterium pullorum, 345 
 Bathmostomum, 281 
 Bedbug, The 8, 90 
 
 as a pest of poultry, 90 
 
 control, 92 
 
 effect of bite, 90 
 
 habits, 90 
 
 reproduction and development, 90 
 Beef measles, 174, 194, 195 
 
 degeneration of cyst, 198 
 
 development, 197 
 
 federal regulations in regard to, 199 
 
 influence of temperature, 198 
 
 location and appearance, 197 
 
 method of infection, 197 
 
 occurrence, 196 
 
 vitality of larvae, 198 
 Beef and pork tapeworm, methods of 
 
 differentiation, 200 
 Beef tapeworm, 170, 195 
 Belascaris marginata, 237 
 
 mystax, 237, 239 
 
 cati, 237, 239 
 Bilharzia bovis, 168 
 
 crassa, 168 
 Bilharziosis, 168 
 Black gnat, 31 
 Blackhead of turkeys, 325 
 Black horse fly, 35 
 
 as a transmitter of disease, 36 
 
 effect, 35 
 
 life history, 35 
 
 protection from, 36 
 Blood fluke, 168 
 Blow fly, 50, 52 
 
 effect, 53 
 
 reproduction and development, 52 
 Bluebottle fly, 52 
 Body louse, 79 
 Body mange of poultry, 132 
 Boophilus, 142 
 
 annulatus, 144, 145, 314, 347 
 bovis, 144, 145, 314, 347 
 decoloratus, 316 
 Bot flies, 53 
 Bot, horse, 5, 53, 57 
 Bothriocephalus latus, 185 
 Brachiopoda, 155 
 
 Bronchial and pulmonary strongylosis 
 of cattle, 259 
 
INDEX 
 
 361 
 
 control, 264 
 
 course, 260 
 
 development, 263 
 
 etiology, 263 
 
 post-mortem appearance, 262 
 
 prognosis, 260 
 
 symptoms, 259 
 
 sjTnptoms, duration of, 260 
 
 treatment, 265 
 Bronchial and pulmonary strongylosis 
 of the horse, 261 
 
 occurrence, 261 
 
 symptoms, 261 
 Bronchial and pulmonary strongylosis 
 of the pig, 260 
 
 occurrence, 260 
 
 symptoms, 260 
 Bronchial and pulmonary strongylosis, 
 post-mortem appearance, 262 
 
 control, 264 
 
 development, 263 
 
 etiology, 263 
 
 treatment, 265 
 Bronchial and pulmonary strongylosis 
 of the sheep and goat, 256 
 
 control, 264 
 
 course, 259 
 
 development, 263 
 
 etiology, 263 
 
 post-mortem appearance, 262 
 
 prognosis, 259 
 
 symptoms, 258 
 
 treatment, 265 
 Buffalo gnat, 31, 32 
 
 control, 33 
 
 effect, 33 
 
 life history, 32 
 
 occurrence, 32 
 
 protection from, 33 
 
 treatment, 34 
 Brazilian septicemia of fowl, 327 
 Bruce, investigations of, 45, 315, 330 
 Bryozoa, 155 
 Bunostomeae, 281 
 
 Bunostomum trigonocephalum, 293 
 phlebotomum, 293 
 
 Calliphora vomitoria, 52 
 Cardiac filariasis of the dog, 248 
 Cardio-pulmonary strongylosis of the 
 dog, 261 
 
 post-mortem appearance, 263 
 
 symptoms, 262 
 Castor-bean tick, 143 . 
 Cattle tick, 144, 145, 314, 347 
 Cestoda, 159, 169 
 Chabertia ovina, 287 
 Chiggers, 96, 99 
 Chloroform as ti-eatment for lung 
 
 woi-ms, 266 
 Choanotainia infundibuliformis, 189 
 Chorioptes, 103 
 
 parasitism, 103 
 
 species, 103 
 Chorioptes communis, 103 
 
 var, bovis, 113 
 
 var. equi, 108 
 
 var. ovis, 112 
 Chorioptic scabies of cattle, 113 
 
 course, 113 
 
 location, 113 
 
 treatment, 120, 130 
 Chorioptic scabies of the horse, 108 
 
 course, 108 
 
 diagnosis, 109 
 
 lesions, 109 
 
 prognosis, 109 
 
 symptoms, 108 
 
 transmission, 109 
 
 treatment, 120, 129 
 Chorioptic scabies of the sheep, 112 
 
 course, 112 
 
 prognosis, 112 
 
 symptoms, 112 
 
 transmission, 112 
 Chrysomyia macellaria, 50 
 
INDEX 
 
 Cimex lectularius, 90 
 
 Cimicidffi, 22, 90 
 
 Citto taenia denticulata, 185 
 
 Classification of the Arachnida, 96 
 
 Classification of the phylum Ccelhel- 
 
 minthes, 222 
 Classification of Insects, 20 
 Classification of the phylum Platy- 
 
 helminthes, 157 
 Classification of the plyhun Protozoa, 
 
 322 
 Cnemidocoptes, 103, 132 
 
 species of, 103, 132 
 Cnemidocoptes gallinse, 103, 133 
 
 mutans, 103, 132 
 Coccidia, 322, 323, 337 
 
 infection, 337 
 
 life cycle, 322, 337 
 
 parasitism, 337 
 
 pathogenicitj^, 337 
 
 reproduction, 337 
 Coccidial enteritis of chicks, 345 
 
 control, 346 
 
 diagnosis, 345 
 
 differentiation from bacillary white 
 diarrhea, 345 
 
 infection, 346 
 
 post-mortem appearance, 345 
 
 symptoms, 345 
 Coccidiosis of the dog, 342 
 
 investigations bj^ Hall and Wigdor, 
 342 
 Coccidiosis of cattle, 343 
 
 of chicks, 345 
 
 of the dog, 345 
 
 of man, 342 
 
 of the rabbit, 342 
 Coccidium cuniculi, 342 
 
 oviforme, 342 
 
 tenellum, 345 
 
 zurni, 343 
 Cochliomyia macellaria, 50 
 Ccelhelminthes, 216 
 
 classification of, 156, 216, 222 
 
 Coelom, 216 
 
 Coenurosis, 204 
 
 Coenurus, 173, 194, 204, 205 
 
 Colic, thrombo-embolic, 288, 290 
 
 Commensalism, 2, 7 
 
 example of, 2, 7 
 Compsomyia macellaria, 50 
 Connective tissue mite of poultry, 
 
 134 
 Cooperia curticei, 268 
 
 oncophora, 275 
 Cryptobia, 329 
 Cryptocystis, 178, 195 
 Ctenocephalus cards, 65, 79 
 
 felis, 65 
 Culex and Anopheles, differentiation, 
 
 28 
 Culex pungens, 26, 28 
 Culicidse, 20, 24 
 Cylicostomese, 281 
 Cylicostomum, 281 
 Cysticercoid, 173, 178, 195 
 Cysticercosis, 174, 195 
 Cysticercus, 173, 174, 194, 195 
 
 bovis, 174, 195, 197 
 
 cellulosEe, 174, 195, 199, 202 
 
 ovis, 203 
 
 tenuicollis, 174, 179, 195, 203 
 
 trichodectes, 79, 178, 183 
 Cytoleichidffi, 134 
 Cytoleichus nudus, 134 
 
 D 
 
 Davainea cesticillus, 190, 191 
 
 echinobothrida, 191 
 
 proglottina, 189 
 
 tetragona, 190, 191 
 Degeneration, parasitic, 3, 4 
 Demodecidae, 96, 97, 103 
 Demodectic mange, 96, 104 
 
 of the dog, 116 
 
 of the hog, 115 
 
 of the sheeji, 112 
 
INDEX 
 
 363 
 
 Demodex foUiculorimi, 10-i 
 
 var. canis, 104, 116 
 
 var. ovis, 104, 112 
 
 var. snis, 104, 115 
 Depluming mange of poultry, 133 
 Deplimaing mite, 101, 133 
 Dermacentor, 142 
 
 electus, 143 
 
 occidentalis, 143 
 
 reticulatus, 143 
 
 variabilis, 143 
 Dibothriocephalus latus, 185 
 Dibothrium latum, 185 
 Dicrocoelium lanceatum, 160, 163 
 Dictyocaulus arnfieldi, 261 
 
 filaria, 221, 256 
 
 viviparous, 259 
 DioctophjTiie renale, 296 
 
 \'isceralis, 296 
 Diphyllobothriasis, 185 
 
 occurrence, 186 
 Diphyllobothriidae, 160, 185 
 Diphyllobothrium latum, 185 
 Diplospora bigemina, 342 
 Dipping vats, 126 
 Dips, 48, 120, 125 
 Diptera, 18, 20 
 
 parasitic families of, 23 
 
 parasitism of, 23 
 Dipterous insects, 18, 23 
 Dipylidium caninum, 68, 79, 178, 181, 
 
 ^183 
 Dirofilaria inmiitis, 221, 248 
 Dispharagus hamulosus, 254 
 
 nasutus, 254 
 
 spiralis, 254 
 Distomese, 156, 157 
 Distomiasis, 157, 163, 165 
 
 of cattle, 166 
 
 of the sheep, 165 
 Distomvun americanum, 160 
 
 hepaticum, 160 
 
 lanceolatum, 160 
 
 magnvun, 160 
 
 Dochmiasis, 291, 292 
 Doclmiius cernuus, 293 
 
 radiatus, 293 
 
 stenocephalus, 292 
 
 trigonocephalus, 291 
 Docophorus cygni, 86 
 
 icterodes, 84 
 Dourine, 333 
 
 control, 336 
 
 federal control of outbreaks, 333 
 
 infection, 333, 334 
 
 stages in, 334 
 
 sjTiiptoms, 334 
 Drepanidotsenia infundibulifomiis, 189 
 D3^sentery of cattle, 343 
 
 Earthwonn, 216 
 Ecdysis, 13 
 
 Echinococcosis, 183, 210 
 Echinococcus, 173, 181, 183, 194, 210 
 
 alveolaris, 212 
 
 granulosus, 181, 183, 184, 194, 210 
 
 multilocularis, 210, 212 
 
 pohiiiorphus, 181, 183, 210 
 Echinorh^^lcllus gigas, 306 
 Ectozoa, 9 
 Eimeria avimn, 345 
 
 stiedse, 342 
 El dourine, 333 
 Endoparasites, 9 
 Entameba, 326 
 
 coli, 326 
 
 histolytica, 326 
 Entero-hepatitis of turkeys, 325 
 Entozoa, 9 
 Erratic parasites, 8 
 Esophageal and gastric filariasis of the 
 dog, 250 
 
 course, 251 
 
 development, 251 
 
 occurrence, 250 
 
 pathogenesis, 250 
 
364 
 
 INDEX 
 
 symptoms, 251 
 
 treatment, 251 
 Esophageal filariasis of cattle, 246 
 
 of the dog, 250 
 
 of the sheep, 246 
 
 of the horse, 247 
 European dog tick, 143 
 EustrongyUdffi, 224, 296 
 Eustrongylosis, 296 
 
 occurrence, 296 
 
 symptoms, 297 
 
 treatment, 298 
 Eustrongylus gigas, 296 
 
 visceralis, 296 
 Exoparasites, 9 
 
 Fasciola americana, 160, 163 
 
 hepatica, 5, 160 
 
 lanceolata, 160, 163 
 
 magna, 160, 163 
 Fasciola hepatica, life history of, 5, 160 
 Fasciola lanceolata, life history of, 163 
 Fasciola magna, life history of, 163 
 FascioHasis, 157, 163, 165 
 Fascioliasis of cattle, 166 
 
 control, 167 
 
 symptoms, 166 
 
 treatment, 168 
 Fascioliasis of the sheep, 165 
 
 control, 167 
 
 course, 165 
 
 prognosis, 166 
 
 symptoms, 165 
 
 treatment, 168 
 FascioHdae, 157, 160 
 Filaria, 227 
 
 bancrofti, 249 
 
 cervina, 248 
 
 equina, 244 
 
 immitis, 248 
 
 labiato-papillosa, 248 
 
 sanguinis hominis, 249 
 
 sanguinolenta, 250 
 
 Filariae of cattle, 246 
 
 of the dog, 248 
 
 of the hog, 251 
 
 of the horse, 244 
 
 of poultry, 254 
 
 of the sheep, 246 
 Filariasis of cattle, 246 
 
 effect, 247, 248 
 
 occurrence, 247, 248 
 Filariasis of the deer, 248 
 Filariasis of the dog, 248 
 
 diagnosis, 249, 251 
 
 occurrence, 248, 250 
 
 pathogenesis, 249, 250 
 
 theories as to infection, 249 
 
 treatment, 250, 251 
 Filariasis of the hog, 247, 251 
 
 control, 253 
 
 occurrence, 252 
 
 treatment, 254 
 Filariasis of the horse, 244 
 
 effect, 245, 246 
 
 occurrence, 244, 245, 246 
 
 treatment, 246 
 Filariasis of poultry, 254 
 Filariasis of the sheep, 246 
 
 effect, 247 
 
 occurrence, 247 
 Filariidse, 222, 244 
 
 parasitism of, 244 
 Filarioidea, 227 
 Fixed parasites, 8 
 Flagellata, 322, 326 
 Fleas, 65 
 
 as carriers of disease, 66 
 
 control, 68 
 
 habits, 66 
 
 household infestation, 69 
 
 reproduction and development, 
 65,66 
 
 species, differential characters of, 65 
 
 treatment, 68 
 
 usual hosts, 66 
 
 vitality, 68 
 
INDEX 
 
 365 
 
 Flesh flies, 50, 52 
 
 protection from, 52 
 
 reproduction and development, 52 
 Flies, 11,23,35 
 Fluke, liver, 5, 156, 160, 163 
 Fly, house, 11,37, 189 
 Follicular mange of the dog, 116 
 
 course, 116 
 
 symptoms, 116 
 
 transmission, 117 
 
 treatment, 130 
 Follicular mange of the hog, 115 
 
 occurrence, 115 
 
 treatment, 130 
 Follicular mange mite, 103 
 Follicular mange of the sheep, 112 
 
 location, 112 
 
 prevalence, 112 
 Forked worm of fowl, 293 
 Fowl septicemia, 327, 345 
 Fowl tick, 139 
 
 control, 140 
 
 development, 140 
 
 effect, 140 
 
 habits, 140 
 
 occurrence, 140 
 Fumigation treatment in venninous 
 bronchitis, and pneumonia, 265 
 
 Oaigeria, 281 
 Gamasidse, 96, 98 
 Gamasid mifes, 96, 98 
 Gastric filariasis of the dog, 250 
 Gastric filariasis of the horse, 245, 246 
 Gastric and intestinal filariasis of the 
 
 hog, 251, 252 
 Gastro-intestinal strongylosis of cattle, 
 272 
 
 control, 276 
 
 development, 276 
 
 etiology, 276 
 
 occurrence, 275 
 
 pasture rotation, 277 
 
 post-mortem appearance, 275 
 
 symptoms, 275 
 
 treatment, 277 
 Gastro-intestinal strongylosis of the 
 
 goat, 268 
 Gastro-intestinal strongylosis of the 
 sheep, 268 
 
 control, 276 
 
 development, 276 
 
 etiology, 276 
 
 occurrence, 271 
 
 pasture rotation, 277 
 
 pathogenesis, 272 
 
 post-mortem ap])earance, 275 
 
 sjin])toms, 272 
 
 treatment, 277 
 Gastrophilus equi, 5, 53 
 
 hemorrhoidalis, 57 
 
 intestinalis, 5, 53 
 Gid of cattle, 205, 209 
 Gid of the sheep, 204 
 
 the coenurus, 205 
 
 control, 209 
 
 development, 206 
 
 occurrence, 205 
 
 post-mortem appearance, 207 
 
 symptoms, 208 
 
 treatment, 209 
 Gigantorhynchus hirudinaceus, 306 
 Glossary, 353 
 Glossina, 44, 314 
 
 longipalpis, 44, 46 
 
 morsitans, 44, 46, 330 
 
 palpalis, 44, 46 
 Gnat, buffalo, 31, 32 
 Gnathobdellidc^, 224, 308 
 Gnats, 31 
 Gongylonema, 227 
 
 scutata, 246 
 Gongylonemina', 227 
 Goniocotes abdominalis, 82 
 
 compar, 86 
 
 gallinre, 82 
 
366 
 
 INDEX 
 
 gigas, 82 
 
 hologaster, 82 
 Goniodes damicornis, 86 
 
 stylifer, S4 
 Grammoceplialus, 281 
 Green-head fly, 36 
 Gyalocephalus, 281 
 
 H 
 
 Habronema megastoma, 245 
 
 microstoma, 246 
 Haemaphysalis, 142 
 Hcematobia serrata, 41 
 Hsematopiims asini, 73 
 
 eurj-stermis, 74 
 
 macroeephalus, 73 
 
 suis, 77 
 
 urius, 77 
 Hsemonchus coutortus, 268 
 Hsemopis sanguisuga, 308 
 Harvest mites, 99 
 
 effect, 100 
 
 habits, 100 
 
 protection from, 100 
 
 treatment, 100 
 Heel fly, 57 
 Hehninthes, 9 
 Helotism, 7 
 Hematic filariasis of the dog, 248 
 
 diagnosis, 249 
 
 occurrence, 248 
 
 pathogenesis, 249 
 
 theories as to infection, 249 
 
 treatment, 250 
 Hematic filariasis of man, 249 
 Hemiptera, 22, 89 
 Hemosporidia, 323, 347 
 
 dift'erence in m:de of infection from 
 Coccidia, 337, 347 
 
 relationship to other groups, 336, 
 347 
 
 relative pathologic importance, 347 
 Hepatic coccidiosis of rabbits, 342 
 
 Herpetomads, 316 
 
 experiments -with, 316 
 Herpetomonas donovani, 316 
 Heterakiasis of poultr}-, 242 
 
 sj-mptoms, 243 
 
 treatment, 243 
 Heterakidse, 222, 242 
 Heterakinse, 226 
 Heterakis, 226 
 
 inflexa, 242 
 
 papillosa, 242 
 
 perspicillum, 242 
 
 vesicularis, 242 
 Heteroxenous parasites,[S 
 Hippoboscidse, 21, 47 
 Hirudinea, 224, 307 
 Hirudo medicinahs, 309 
 Hook wonn, 291, 292 
 Horn fly, 41 
 
 control, 43 
 
 effect, 42 
 
 habits, 41 
 
 life histon,', 41 
 
 occurrences, 41 
 
 protection from, 43 
 Horse bot flies, 5, 53 
 
 effect of bots, 55 
 
 habits, 53 
 
 life historj', 54 
 
 treatment, 56 
 Horse leech, 308 
 
 efi'ect, 309 
 
 mode of infestation, 309 
 
 occurrence, 309 
 
 treatment, 309 
 House flj', 11, 37, 189 
 
 as a transmitter of infectious dis- 
 eases, 11, 38, 189 
 
 control, 38 
 
 habits, 38 
 
 life historj', 37 
 
 longevity, 37 
 
 protection from, 38 
 Hvalomma, 142 
 
INDEX 
 
 367 
 
 Hydatid disease, 173, ISl, 1S3, 194, 210 
 
 control, 214 
 
 development, 212 
 
 the echinococcus, 210 
 
 longe\'ity of cyst, 213 
 
 occurrence, 210 
 
 post-mortem appearance, 213 
 
 sj-mptoms, 214 
 Hjinenolepis carioca, 190, 191 
 HjTnenoptera, 18 
 Hypoderma bo-\ds, 58 
 
 lineata, 57 
 
 Imago, The, 19 
 Incidental parasites, 8 
 Infectious entero-hepatitis of turkeys, 
 325 
 
 control, 326 
 
 course, 325 
 
 infection, 325 
 
 post-mortem appearance, 325 
 
 symptoms, 325 
 
 treatment, 326 
 Insecta, 15 
 
 classification of, 20 
 Insects, 15 
 
 development, 18 
 
 duration of life, 19 
 
 growth, 19 
 
 lar\'2e, 18 
 
 metamorphosis, 18 
 
 mouth parts, 16 
 
 parasitic subgroups, 20 
 
 reproduction, 18 
 
 structure, 15 
 Internal parasites, 155 
 Intestinal strongj'losis of the cat, 291 
 
 of cattle, 272, 285 
 
 of the dog, 291 
 
 of the goat, 268, 281, 287 
 
 of the hog, 287 
 
 of the horse, 288 
 
 of the sheep, 268, 281, 287 
 
 Intratracheal injections, 265 
 Introduction, 1 
 Isospora bigemina, 342 
 Itch mites, 101 
 Ixodes, 142 
 
 hexagonus, 143 
 
 ricinus, 143 
 Ixodidjp, 96, 97, 136, 141 
 Ixodoidea, 96, 97, 136, 139 
 
 K 
 
 Kala-azar, 316 
 
 Kerosene emulsions, 48 
 
 Kerosene in mosquito control, 25, 
 
 31 
 Kidney womi of the dog, 296 
 Kidney worm of the hog, 295 
 
 Laminosioptes cysticola, 134 
 Lan'se, dipterous, 50 
 Lar\'3e, insect, 18 
 Leeches, 216, 307 
 Leg mange of poultrj-, 132 
 Leishmania donovani, 316 
 Leptus autumnalis, 100 
 Lice, 70 
 
 biting, 71 
 
 sucking, 70 
 Lice of poultry, 82 
 
 control, 88 
 
 occurrence, 82 
 
 treatment, 88 
 Life, degeneracj' in mode of, 1 
 Life history of beef tapeworm, tabular 
 
 re\iew, 172 
 Life histories of dog tick and Texas 
 
 fever tick compared, 151 
 Life historj' of Echinococcus granu- 
 losus, tabular review, 213 
 Life historj' of gid tapeworm, tabular 
 review, 207 
 
368 
 
 INDEX 
 
 Life history of horse botfly, tabular 
 
 review, 55 
 Life history of liver fluke, tabular 
 
 review, 163 
 Life history of sheep botfly, tabular 
 
 review, 63 
 Life history of Trichinella spiralis, 
 
 tabular review, 303 
 Lime and sulphur dips, 122, 125 
 
 method of preparing, 125 
 Linguatula rhinaria, 94, 153 
 Lin;uatulida, 153 
 Linguatulidse, 97 
 Linognathus pedalis, 76 
 
 piliferus, 78 
 
 stenopsis, 77 
 
 vituli, 74 
 Liotheidse, 22, 71 
 Lipeurus anatis, 84 
 
 baculus, 86 
 
 caponis, 83 
 
 columbae, 86 
 
 heterographus, 83 
 
 meleagridis, 84 
 
 polytrapezius, 84 
 
 squalidus, 84 
 
 variabilis, 83 
 Lissoflagellata, 328 
 Liver flukes, 5, 156, 160 
 
 infection, 160, 164 
 
 life history, 5, 160 
 
 losses from, 162 
 
 migrations and pathogenesis, 164 
 
 prevalence, 162 
 
 prevalence in United States, 164 
 Lobosa, 322, 324 
 Lone star tick, 145 
 Lousiness, 71 
 Lung worms, 256 
 
 control, 264 ' 
 
 development, 256, 263 
 
 method of infection with, 256, 
 263 
 Lyperosia irritans, 41 
 
 M 
 
 Maladie du coit, 333 
 Malaria, 26, 318 
 Malaria, latent, 322 
 Malaria organisms, the asexual cvcle, 
 318, 319 
 the gametocytes, 319 
 hberation of the merozoites, 319 
 the macrogametocyte, 319 
 the merozoites, 319 
 the microgametes, 319 
 the microgametocyte, 319 
 relation of liberation of merozoites 
 
 to chill, 319 
 repeating of cycle, 319 
 the schizont, 319 
 the signet ring stage, 319 
 the sporozoites, 319, 320 
 Malaria organisms, life history, 318 
 Malaria organisms, the parthenoge- 
 
 netic phase of, 322 
 Malaria organisms, the sexual cycle, 
 320 
 fertilization of the macrogamete, 
 
 320 
 fomiation of cyst, 320 
 formation of macrogamete, 320 
 formation of the microgametes, 
 
 320 
 fonnation of the sporoblasts, 320 
 formation of the sporozoites, 320 
 liberation pf the sporozites, 320 
 the microgametoblast, 320 
 migration of ookinete, 320 
 the ookinete or zygote, 320 
 passage of sporozoites to salivary 
 
 glands of mosquito, 320 
 relationship of anopheline mosquito 
 to, 26, 313, 319, 320 
 Mai de caderas, 332 
 infection, 333 
 occurrence, 332 
 symptoms, 332 
 
INDEX 
 
 Mallophaga, 21, 71 
 Mange, 96, 101, 102, 103, 104, 112, 
 113, 114, 115, 116, 117, 118 
 
 cnemidocoptic, 132 
 
 follicular, 102, 112, 115, 116 
 
 notoedric, 118 
 
 sarcoptic, 102, 104, 112, 114, 121 
 Mange of the body of poultry, 
 133 
 
 course, 133 
 
 symptoms, 133 
 
 treatment, 133 
 Mange of the cat, 117 
 
 course, 118 
 
 diagnosis, 118 
 
 treatment, 120, 123 
 Mange of cattle, 114 
 
 treatment, 120, 124 
 Mange of the dog, 115, 116 
 
 course, 115, 116 
 
 lesions, 115, 116 
 
 symptoms, 115, 116 
 
 transmission, 115, 117 
 
 treatment, 120, 123, 130 
 Mange of the goat, 1 13 
 
 treatment, 120, 124 
 Mange of the hog, 114, 115 
 
 sjTnptoms, 114, 115 
 
 transmissions, 114 
 
 treatment, 120, 122, 130 
 Mange of the horse, 104 
 
 control, 122 
 
 development, 105 
 
 diagnosis, 105 
 
 lesions, 105 
 
 prognosis, 107 
 
 symptoms, 104 
 
 transmission, 107 
 
 treatment, 120, 121 
 Mange of the legs of poultry, 132 
 
 course, 132 
 
 symptoms, 132 
 
 treatment, 132 
 Mange mites, 96, 103, 132, 134 
 
 Mange of poultry, 132, 134 
 Mange of tlie rabbit, 118 
 
 treatment, 120, 124 
 Mange and scab mites, 96, 101, 102, 
 103, 117, 132, 134 
 
 development, 101, 103 
 
 reproduction, 101, 103 
 Mange of the sheep, 112 
 
 treatment, 120, 124 
 Margaropus, 142, 145 
 
 annulatus, 144, 145, 314, 347 
 Mastigophora, 322, 326 
 Measles, 174, 194, 195 
 
 ofman, 174, 194, 195 
 
 of the ox, 174, 195 
 
 of the pig, 174, 195 
 
 of the sheep, 174, 195 
 Medicinal leech, 309 
 Melophagus ovinus, 4, 47, 76 
 Menopon biseriatum, 83 
 
 pallidum, 83 
 Menopum biseriatum, 83 
 
 pallidum, 83 
 
 trigonocephalum, 83 
 Metamorphosis, insect, 19 
 
 complete, 19 
 
 incomjjlete, 19 
 Metastrongylidae, 227 
 Metastrongylina>, 223, 256 
 
 life history, 256, 263 
 Metastrongylus, 227 
 Metazoa, 311 
 Miescher's tube, 350 
 Mites, 94 
 MoUuscoidea, 155 
 Molting, 13 
 Moniezia alba, 176 
 
 denticulata, 185 
 
 expansa, 176 
 
 planissima, 176 
 Monoxenous parasites, 8 
 Mosquitoes, 11, 24 
 
 breeding habits, 24 
 
 control, 31 
 
370 
 
 INDEX 
 
 Culex and Anopheles, differentia- 
 
 • tion, 28 
 
 development, 25 
 
 effect upon live stock, 31 
 
 lan-se, 24 
 
 pathologic importance, 26 
 
 protection against, 31 
 
 pupse, 25 
 
 range, 24 
 
 relationship to filariasis, 26 
 
 relationship to malaria, 26, 313, 320 
 
 relationship to yellow fever, 26, 29 
 Multiceps gaigeri, 181 
 
 multiceps, 179, 194, 204, 206, 207 
 
 serialis, 179 
 Musca domestica, 11, 37, 189 
 
 vomitoria, 52 
 Muscidffi, 20, 37 
 MutuaHsm, 2, 7, 
 
 example of, 2, 7 
 Myasis, 50 
 
 Nagana, 45, 314, 330 
 
 etiology, 45, 314, 330 
 
 investigations by Bruce, 45, 314, 
 330 
 
 occurrence, 330 
 Nemathehninthes, 155, 216, 222 
 Nematoda, 217, 222, 
 Nematode worms, parasitism in gen- 
 eral, 219 
 
 adaptabilitj' to changed environ- 
 ment, 221 
 
 factors influencing injury to host, 
 220 
 
 host limitations, 220 
 
 infection, 219, 220 
 
 treatment in general, 221 
 Nematodirus fiUcollis, 273 
 Neosporidia, 336, 350 
 Net tick, 143 
 Nodular disease, 281 
 
 Nodular strongylosis of cattle, 285 
 
 of the goat, 281 
 
 of the hog, 287 
 Nodular strongylosis of the sheep, 281 
 
 development, 283 
 
 importance, 284 
 
 occurrence, 283 
 
 post-mortem appearance, 284 
 
 sjTiiptoms, 284 
 
 treatment, 285 
 Notoedres, 101, 117 
 
 var. cati, 117, 118 
 
 var. cuniculi, 118 
 
 parasitism of, 103 
 Notoedric mange, treatment of, 120, 
 123, 124 
 
 Obhgate parasites, 8 
 
 Ocular filariasis of the horse, 245 
 
 of the ox, 248 
 (Esophagostomese, 280 
 (Esophagostomiasis of cattle, 285 
 
 of the goat, 281 
 
 of the hog, 287 
 
 of the sheep, 281 
 CEsophagostomum, 255, 280 
 
 columbianum, 281 
 
 dentatiun, 287 
 
 inflatum, 285 
 
 radiatimi, 285 
 
 subulatum, 287 
 
 venulosum, 282 
 (Estridse, 21, 53 
 (Estrus o\as, 62 
 Optional parasites, 8 
 Organic multiplication, influences re- 
 stricting, 1 
 Ornithobius bucephalus, 86 
 Ornithodorus megnini, 140 
 Ornithonomus CA'-gni, 86 
 Ostertagia marshalli, 269 
 
 ostertagi, 272 
 
INDEX 
 
 371 
 
 Otacariasis of the cat, 118 
 occurrence, 118 
 treatment, 131 
 Otacariasis of the dog, 117 
 
 occurrence, 117 
 
 prognosis, 117 
 
 sjTnptoms, 117 
 
 treatment, 131 
 Otacariasis of the rabbit, 1 18 
 
 course, 118 
 
 sjinptoms, 119 
 
 treatment, I'M 
 Otobius megnini, 159 
 Otodectes, 101, 103, 115, 117 
 
 parasitism, 103 
 Otodectes cynotis, 115, 117 
 Oviparous, application of the term, 
 
 219 
 0^^position, 18, 219 
 Ovipositor, 18 
 Ovo\aviparous, application of the 
 
 term, 219 
 Ox bot flies, 57 
 
 effect of bots, 62 
 
 life history, 58 
 
 occurrence, 57 
 
 treatment, 62 
 Ox warbles, 53, 57 
 Oxyuriasis, 236 
 
 effect, 236 
 
 occurrence, 236 
 
 treatment, 237 
 Oxyuridffi, 222, 235 
 OAjoirinse, 226 
 Oxynris, 226 
 
 curv'ula, 235 
 
 equi, 235 
 
 mastigodes, 235 
 
 Parasites, alternation of hosts in, 5, 
 Parasites, determinate transitory, 8 
 
 determinate erratic, 8 
 
 erratic, 8 
 
 fixed, S 
 
 heteroxenous, 8 
 
 incidental, 8 
 
 monoxenous, 8 * 
 
 optional occasional, 8 
 
 permani nt, 8 
 
 stray, 8 
 Parasites, development of patho- 
 genicity in, 315 
 Parasites, external, 9 
 
 internal, 9 
 Parasites, factors influencing injury 
 by, 10, 315 
 
 age of host, 11 
 
 location, 10, 315 
 
 movements, 10 
 
 nature of food, 10 
 
 number present, 10 
 Parasites, influence upon host, 10, 315 
 Parasites, systematic position of, 6 
 Parasitic diseases, terms used in, 9 
 Parasitism, 2, 3, 7, 315 
 
 adaptation to, 3, 4, 315 
 
 degeneration in, 3, 4 
 
 factors leading to, 1, 6, 315 
 
 forms of, 7 
 
 functions involved in adaptation 
 to, 3 
 
 range of, 3 
 
 reproductive function in, 4 
 Parasitism, evolution of, 315 
 Parthenogenesis, 15, 322 
 Pathogenic Protozoa, 311, 324 
 
 arthropods as carriers of, 23, 315 
 PedicuHdse, 21, 70 
 Pediculosis of the cat, 79 
 
 control, 80 
 
 occurrence, 79 
 
 treatment, 81 
 Pediculosis of cattle, 74 
 
 control, SO 
 
 indications of, 75 
 
 location, 75 
 
 treatment, 81 
 
372 
 
 INDEX 
 
 Pediculosis of the dog, 78 
 
 control, 80 
 
 effect, 78 
 
 location, 78 . 
 
 treatment, 81 
 Pediculosis of the goat, 77 
 
 control, 80 
 
 effect, 77 
 
 occurrence, 77 
 
 treatment, 80 
 Pediculosis of the hog, 77 
 
 control, 80 
 
 effect, 77 
 
 occurrence, 77 
 
 treatment, 81 
 Pediculosis of the horse, 72 
 
 control, 80 
 
 indications of, 73 
 
 location, 73 
 
 treatment, 80 
 Pediculosis of mammals, 71 
 
 complications, 71 
 
 effect, 72 
 
 indications of, 72 
 
 predisposing factors, 71 
 
 treatment, 80 
 Pediculosis of man, 79 
 Pediculosis of poultrj^, 82 
 
 control, 88 
 
 dust bath in, 88 
 
 effect, 82 
 
 indications of, 82 
 
 occurrence, 82 
 
 parts attacked, 82 
 
 sodium fluoride in treatment of, 
 88 
 
 treatment, 88 
 Pediculosis of the sheep, 76 
 
 control, 80 
 
 occurrence, 77 
 
 treatment, 80 
 Pediculosis, control and treatment, 80 
 Pediculus capitis, 79 
 
 corporis, 79 
 
 humanus, 79 
 vestimenti, 79 
 Permanent parasites, 8 
 Pharyngeal filariasis of the hog, 247 
 Philopteridse, 21, 71 
 Philopterus cygni, 86 
 
 icterodes, 84 
 Phthiriasis, 71, 79 
 Phthirius inguinalis, 79 
 
 pubis, 79 
 Physocephalus sexalatus, 252, 253 
 Phytoparasites. 7 
 Piroplasma bigeminum, 313, 347 
 Plasmodium, 313, 318 
 
 falciparum, 318 
 
 malarise, 318 
 
 prsecox, 318 
 
 yivax, 318 
 Platyhelminthes, 155, 157 
 
 classification of, 155, 157 
 Plerocercoid, 173, 195 
 Polystomese, 156 
 Polyzoa, 155, 159 
 Pork measles, 174, 195, 199 
 
 degeneration of cyst, 202 
 
 development, 202 
 
 diagnosis, 202 
 
 influence of temperature upon larvse, 
 202 
 
 locatin and appearance of cysts, 
 201 
 
 method of infection, 201 
 
 occurrence, 200 
 
 symptoms, 202 
 
 vitality of larvse, 202 
 Pork tapeworm, 195, 199 
 Poultry mite, 98 
 
 control, 9 
 
 development, 99 
 
 effect, 99 
 
 habits, 98 
 
 occurrence, 98 
 
 reproduction, 99 
 Predaceous animals, 3, 9 
 
INDEX 
 
 373 
 
 Protozoa, 311 
 
 carj'ozoic, 322 
 
 coelozoic, 322 
 
 colonization of, 311 
 
 cytozoic, 322 
 
 differentiation from Metazoa, 311 
 
 enterozoie, 322 
 
 hematozoic, 322" 
 
 investigations as to patiiogenicity, 
 313, 315 
 
 investigations as to pathogenicity in 
 the United States, 314 
 
 natural classification of, 322 
 
 parasitism, 313 
 
 pathogenicity, 313, 315 
 
 pathogenic classificarion of, 322 
 
 specialization in, 311 
 Protozoa, classification of, 322 
 Protozoa, methods of reproduction in. 
 313, 318, 327, 329, 336, 337 
 
 asexual method, 318, 319, 337 
 
 multiplicative cycle, 318, 319, 337 
 
 propagative cycle, 318, 320, 337 
 
 sexual method, 318, 320, 337 
 
 sporulation, 318, 319, 320, 336, 337 
 Pseudopodia, 312, 324 
 Psoroptes, 101, 102 
 
 parasitism, 102 
 
 species of, 103 
 
 varieties, 103 
 Psoroptes conmiunis, 103 
 
 var. bovis, 103, 113 
 
 var. cuniculi, 103, 118 
 
 var. equi, 103. lOS 
 
 var. ovis, 103, 109 
 Psoroptic scabies of cattle. 113 
 
 course, 113 
 
 s\nnptoms, 113 
 
 treatment, 120, 128 
 Psoroptic scabies of the goat, 113 
 Psoroptic scabies of the horse, 108 
 
 lesions, 108 
 
 transmission, 108 
 
 treatment, 120. 129 
 
 Psoroptic .scabies of the rabbit, 118 
 
 course, 118 
 
 sjinptoms, 119 
 
 treatment, 120, 131 
 Psoroptic scabies of the sheep, 109 
 
 after-treatment, 128 
 
 course, 110 
 
 historical, 110 
 
 lesions, 110 
 
 prognosis, 110 
 
 SNinptoms, 110 
 
 treatment, 120, 124 
 Pubic louse, 79 
 Pulex irritans, 65 
 
 serraticeps, 65 
 Pulicida^, 21, 65 
 Pulmonary strongylosis of the cat, 262 
 
 .s\ini)toms, 262 
 Pupation, 19 
 Pyrosoma bigeminum, 313 
 
 R 
 
 Red bugs, 99 
 
 Red dysentery of cattle, 343 
 
 Red mange of the dog, 104, 116 
 
 Red-tailed bot fly, 57 
 
 Remora, 2 
 
 Reproduction, oviparous, 18, 219 
 
 ovoviparous, 18,219 
 
 pupiparus, 4, 18 
 
 viviparous, 18, 219 
 Respirator^' mite of fowl, 134 
 Rhipicentor, 142 
 Rhipicephalus, 142 
 Rhizopoda, 322, 324 
 
 reproduction in, 324 
 Rhvnchobdellidsp. 308 
 
 Sarcocystis bertrami, 351 
 blanchardi, 351 
 miescheriana, 351 
 tenella, 351 
 
374 
 
 INDEX 
 
 Sarcophaga sarraceiiise, 52 
 Sarcoptes, 101 
 
 parasitism, 102 
 
 species of, 102 
 
 varieties, 102 
 Sarcoptes minor var. cati, US 
 
 minor var. cuniculi, 118 
 
 mutans, 132 
 Sarcoptes scabiei, 102 
 
 var. boA-is, 114 
 
 var. canis, 115 
 
 var. equi, 104 
 
 var. o\as, 112 
 
 var. suis, 114 
 Sacroptic mange, 101, 102 
 
 of cattle, 114 
 
 of the dog, 115 
 
 of the goat, 113 
 
 of the hog, 114 
 
 of the horse, 104 
 
 of the sheep, 112 
 Sarcoptidse, 96, 101 
 Sarcosporidia, 323, 336, 350 
 
 development, 350 
 
 muscles commonl}^ invaded, 350 
 
 parasitism, 350 
 
 pathologic importance, 351 
 
 theorv^ as to source and mode of 
 infection, 351 
 
 toxicity, 351 
 Sarcosporidiosis, 350 
 
 mode of infection, 352 
 Sarcosporidiosis of cattle, 351 
 
 of the horse, 351 
 
 of mice, 352 
 
 of the pig, 351 
 of the sheep, 351 
 Scabies, 96 
 Scab mites, 94, 96 
 Scaly leg of poultry, 132 
 Schistosoma bovis, 16S 
 Schistosomidse, 157 
 Schizogony, 318, 319, 337 
 Sclerostomiasis, 288 
 
 Sclerostomum edentatum, 289 
 equinum, 288 
 hypostomum, 287 
 tetracanthum, 289 
 vulgare, 289 
 Scorpion, 94 
 Screw womi fly, 50 
 development, 50 
 effect, 50 
 occurrence, 50 
 protection from, 51 
 reproduction, 50 
 treatment, 51 
 Sea anemone and hermit crab, 
 
 mutualism of, 2 
 Septicemia of chicks, 345 
 Setaria labiato-papillosa, 244 
 Sheep bot fly, 62 
 effect of bots, 63 
 life liistory, 62 
 occurrence, 62 
 prevention, 64 
 treatment, 64 
 Sheep measles, 174, 195, 203 
 Sheep measles, muscular, 203 
 control, 204 
 derivation, 203 
 development, 204 
 economic importance, 204 
 occurrence, 203 
 Sheep measles, \dsceral, 203 
 control, 203 
 development, 203 
 method of infection, 203 
 occurrence, 203 
 
 relation to food sanitation, 203 
 sjTiiptoms, 203 
 Sheep staggers, 204 
 Sheep "tick," 4, 47 
 control, 48 
 effect, 48 
 life history, 4, 47 
 occurrence, 47 
 treatment, 48 
 
INDEX 
 
 375 
 
 Simplicity, primitive and degenera- 
 tive, 3 
 Simuliidte, 20, 31 
 Simulium pecuarmn, 32 
 Siphonaptera, 21, 65 
 Siphunculata, 21, 70 
 Sleeping sickness, 46, 314 
 Southern cattle fever, 145, 313, 347 
 Southern cattle tick, 144, 145, 347 
 Spider, 94 
 Spinose ear tick, 140 
 
 development, 141 
 
 effect, 141 
 
 habits, 141 
 
 occurrence, 141 
 Spirocheta gallinarum, 327 
 
 marchouxi, 327 
 
 theileri, 316 
 Spirochetida, 315, 322, 327 
 
 as blood parasites, 315, 316 
 
 evolution of pathogenicity in, 315 
 
 pathogenicity, 315, 327 
 
 transmission, 316 
 Spirochetosis, 315, 327 
 
 of fowl, 327 
 Spiroptera megastoma, 245 
 
 microstoma, 246 
 
 sanguinolenta, 250 
 
 scutata, 246 
 
 sexalata, 252 
 
 strongylina, 251 
 Spirura, 227 
 Spiruridse, 227 
 Spirurinse, 227 
 
 Splenic fever of cattle, 145, 313, 347 
 Sporogony, 318, 320, 337 
 Sporozoa, 323, 336 
 
 relationship to other forms, 336 
 
 reproduction in, 318, 322, 336, 337 
 Stable fly, 39, 332 
 
 control, 40 
 
 effect, 40 
 
 life historj^, 39 
 
 occurrence, 40 
 
 protection from, 41 
 
 relation to infectious diseases, 40 
 332 
 Staggers of sheep, 204 
 Stegomya calopus, 29 
 
 fasciata, 29 
 Stephanurus dentatus, 295 
 Sting, insect, 18 
 Stomach wonns, pasture rotation 
 
 in eradication of, 277 
 Stomach worms of cattle, 272 
 
 of the goat, 268 
 
 of the sheep, 268 
 Stomoxys calcitrans, 39, 315, 332 
 Stray parasites, 8 
 Strongjdea, 280 
 Strongj'les of the resj^iratory system, 
 
 255, 256 
 Strongj'lidcc, 223, 255 
 ]3arasitism of, 255 
 Strongj'linse. 223, 280 
 Strongyloidca, 226 
 Strongj'losis, 255 
 
 bronchial, 256 
 
 gastric, 268 
 
 intestinal, 268, 280 
 
 pulmonary, 256 
 
 renal, 295, 296 
 
 vascular, 289 
 Strongj'losis, bronchial and pulmonary 
 
 of cattle, 259 
 
 of the goat, 256 
 
 of the horse, 261 
 
 of the pig, 260 
 
 of the sheep, 256 
 Strongylosis of the intestines of the 
 
 cat, 291 
 Strongylosis of the intestines of the 
 dog, 291 
 
 development, 292 
 
 occurrence, 292 
 
 post-mortem appearance, 292 
 
 sjTiiptoms, 292 
 
 treatment, 293 
 
INDEX 
 
 Strongylosis of the intestines of the 
 horse, 288 
 
 development, 289 
 
 post-mortem appearance, 290 
 
 sjTiiptoms, 290 
 
 treatment, 291 
 Strongylosis of the large intestine of 
 
 the goat, 287 
 Strongylosis of the large intestine of 
 the sheep, 287 
 
 occurrence, 288 
 Strongylosis, pulmonary of the dog, 
 261 
 
 of the cat, 262 
 Strongylosis, tracheal, of poultry, 293 
 Strongylus, 226, 255 
 
 annatus, 288 
 
 arnfieldi, 261 
 
 capillaris, 258 
 
 colubrifonnis, 271 
 
 contortus, 268 
 
 curticei, 268 
 
 edentatus, 289 
 
 equinus, 288 
 
 filaria, 256 
 
 fiUcollis, 273 
 
 instabilis, 271 
 
 micrurus, 259 
 
 oncophora, 275 
 
 ostertagi, 272 
 
 paradoxus, 260 
 
 pusillus, 262 
 
 rufescens, 257 
 
 vasorum, 261 
 
 ventricosus, 268 
 
 vulgaris, 255, 289 
 Strongyl worms, importance of, 255 
 
 infestation, conditions favoring, 255 
 Struggle for existence, 1 
 Subcutaneous mite of fowl, 134 
 Summaries on development of Texas 
 
 fever tick, 149, 150 
 Surra, 314, 315, 332 
 
 course, 332 
 
 flies as carriers of, 314, 315, 332 
 
 infection, 332 
 
 occurrence, 332 
 
 sjinptoms, 332 
 Symbiosis, 2, 7 
 
 phases of, 2 
 Symbiotes, 103 
 
 communis, 103 
 Sjaigameae, 281 
 Syngamosis, 293 
 Syngamus, 281, 294 
 
 bronchialis, 293, 294 
 
 trachealis, 293, 294 
 Synopsis of tape wo mi larvse, 194 
 Synthetocaulus abstrusus, 262 
 
 capillaris, 258 
 
 rufescens, 257 
 
 Tabanida", 20, 35, 332 
 Tabanus atratus, 35 
 
 lineola, 36 
 
 striatus, 332 
 Table of principal tapeworais and 
 
 larvae, 173 
 T»nia, 173 
 Taenia alba, 176 
 
 cesticillus, 190 
 
 coenurus, 179 
 
 crassicoUis, 184 
 
 cucumerina, 178 
 
 echinobothrida, 191 
 
 echinococcus, 181, 210 
 
 expansa, 176 
 
 fimbriata, 174, 176, 177 
 
 hydatigena, 178, 195, 203 
 
 mamillana, 175 
 
 marginata, 178 
 
 mediocanellata, 195 
 
 ovis, 204 
 
 perfoliata, 174 
 
 plicata, 175 
 
 proglottina, 191 
 
INDEX 
 
 377 
 
 saginata, 170, 174, 195 
 
 serialis, 179 
 
 serrata, 179 
 
 solium, 174, 195 
 
 tsenisefomiis, 184 
 
 tetragona, 190 
 Ta^niasis, 172, 174 
 
 prevention, 187 
 
 treatment in general, 186 
 Tffniida", 20, 159, 170 
 
 life history of, 169, 171 
 Tail scab of cattle, 113 
 Tapeworm larvae, 173, 174, 194 
 
 synopsis of, 194 
 Tapeworms, 5, 169 
 
 classification of, 159, 173 
 
 cystic fonns, 173, 194 
 
 degeneration of, 5, 172 
 
 parasitism of, 5, 172 
 Tapewonns of the cat, 184 
 
 occurrence, 184 
 
 symptoms, 184 
 
 treatment, 188 
 Tapewonns of cattle, 176 
 
 occurrence, 177 
 
 symptoms, 177 
 
 treatment, 188 
 Tapewonns of chickens, 189 
 
 control, 192 
 
 diagnosis, 192 
 
 investigations as to, 189 
 
 occurrence, 189, 191 
 
 sjTnptoms, 191 
 
 treatment, 192 
 Tapewonns of the dog, 178 
 
 diagnosis, 183 
 
 occurrence, 181 
 
 pathogenesis, 182 
 
 prevention, 187 
 
 relation to human infection, 183 
 
 s\inptoms, 181 
 
 treatment, 186 
 Tapewonns of the horse, 174 
 
 occurrence, 175 
 
 symptoms, 175 
 
 treatment, 188 
 Tapewonns of the rabbit, 185 
 
 diagnosis, 185 
 
 occurrence, 185 
 Tapewonns of the sheep, 176 
 
 occurrence, 177 
 
 symptoms, 177 
 
 treatment, 188 
 Telosporidia, 336 
 Tetrameres fissispina, 254 
 Texas fever, 11, 145, 313, 347 
 
 acute type, 349 
 
 chronic tjije, 349 
 
 development of the piroplasma, 348 
 
 distribution, 348 
 
 infecting organism of, 347 
 
 influence of climate upon, 349 
 
 occurrence, 348 
 
 l)eriod from exjiosure to develop- 
 ment, 348 
 
 prevention, 350 
 
 relationship of the tick to transmis- 
 sion, 145, 314, 347 
 
 sjinptoms, 349 
 
 treatment, 350 
 Texas fever tick, 11, 144, 145, 314, 347 
 
 losses occasioned by, 151 
 
 progress in eradication of, 152 
 
 publications relative to, 145 
 Texas fever tick, life history of, 148, 347 
 
 adult period, 150 
 
 hatching period, 148 
 
 incubation period, 148 
 
 larval period, 150 
 
 longevity period, 149 
 
 nonparasitic development, 148 
 
 njinphal period, 150 
 
 oviposit ion period, 148 
 
 parasitic development, 149 
 
 preoviposition jieriod, 148 
 
 summary of nonparasitic periods, 
 149 
 
 summary of parasitic jieriotls, 150 
 
378 
 
 INDEX 
 
 Thorn-headed womi, 306 
 Thorn-headed womi of the hog, 303 
 
 life history, 306 
 
 occurrence, 306 
 
 pathogenesis, 306 
 
 symptoms, 306 
 
 treatment, 307 
 Thj^sanosoma actinioides, 174, 176, 
 
 177 
 Tick fever, 365, 145, 313, 347 
 Ticks, 136 
 
 classification of, 136 
 
 stages in development of, 139, 145 
 
 structure of, 136 
 Tick, Texas fever, 144, 145, 314, 
 
 347 
 Toxascaris limbata, 238 
 
 marginata, 238 
 Toxins, parasitic, 11, 174, 220 
 Tracheal injections, 265 
 Tracheal strongjdosis of fowl, 293 
 
 development, 294 
 
 lesions, 294 
 
 occurrence, 294 
 
 prevention, 295 
 
 symptoms, 294 
 
 treatment, 295 
 Transmigration, 8 
 Trematoda, 156, 157 
 Trichina spiraHs, 220, 299, 301 
 Trichinella, 225 
 Trichinella spiralis, 220, 299, 301 
 
 degeneration of cyst of, 303 
 
 development of cyst of, 302 
 
 life liistory, 302 
 
 location of cysts of, 303 
 
 migration, 220, 302 
 Trichinellidse, 224, 299 
 Trichinellinffi, 225 
 Tricliinelloidea, 225 
 Trichinosis, 220, 301 
 
 intestinal, 302 
 
 method of infection, 302, 304 
 
 muscular, 302 
 
 occurrence, 301, 304 
 
 prophj-laxis, 305 
 
 symptoms in the hog, 304 
 
 treatment, 305 
 Tricliinosis in man, 304. 
 Trichocephalus affinis, 299 
 
 crenatus, 299 
 
 depressiusculus, 300 
 Trichodectes clmiax, 77 
 
 equi, 73 
 
 latus, 78 
 
 panmipilosus, 73 
 
 pilosus, 73 
 
 scalaris, 75 
 
 sphserocephalus, 76 
 
 subrostratus, 79 
 Trichostrongylidae, 226 
 Trichostrongylinse, 223, 268 
 Trichostrongjdus, 226 
 
 instabilis, 271 
 Trichurinse, 225 
 Trichuris, 225 
 
 crenatus, 299 
 
 depressiusculus, 300 
 
 o\as, 299 
 Trinoton lituratum, 86 
 
 luridum, 84 
 Trinotum lituratum, 86 
 
 luridum, 84 
 Triodontophorus, 281 
 Trombidiidffi, 96, 99 
 Trombidium holosericeum, 100 
 Tropisurus fissispinus, 254 
 Trypanoplasma, 328 
 Trypanosoma, 328 
 
 americanum, 336 
 
 brucei, 314, 330 
 
 equinum, 332 
 
 equiperdum, 333 
 
 evansi, C14, 332 
 
 gambiense, 314 
 
 le^visi, 314 
 
 theileri, 329 
 Tiypanosomatida, 322, 328 
 
INDEX 
 
 379 
 
 Trypanosomes, 314, 32S 
 
 classification of, 322, 32S 
 
 morphology of, 328, 329 
 
 parasitism of, 314, 329 
 
 reproduction, 329 
 
 transmission, 314, 329 
 
 transmission by flies, 45, 314, 329 
 Trypanosomes, flies as carriers of, 
 45, 314, 329 
 
 leeches as carriers of, 314 
 
 lice as carriers of, 314 
 
 mosquitoes as carriers of, 314 
 Trj'-panosomiasis, 11, 45, 314, 328 
 
 human, 46, 314 
 
 investigations by Bruce, 45, 314, 330 
 Tsetse flies, 44, 314, 330 
 
 control, 43 
 
 method of reproduction, 44 
 
 relationship to trypanosomiasis, 45, 
 314, 330 
 Tsetse fly disease, 44, 314, 330 
 
 investigations by Bruce, 44, 314, 
 330 
 Tunicata, 3 
 Tumsick, 204 
 Typhoid fever, 11, 
 
 U 
 
 Uncinaria, 281 
 Uncinariasis, 291 
 
 Uncinaria canina, 291 
 cernua, 293 
 radiata, 293 
 stenocephala, 292 
 trigonocephala, 291 
 
 V 
 
 Vermes, 155 
 
 Vermicides, use and action of, 121, 186 
 Vermifuges, use and action of, 121, 186 
 Verminous bronchitis and pneumonia 
 of cattle, 259 
 
 of children, 231 
 
 of the goat, 256 
 
 of the horse, 261 
 
 of the pig, 231, 260 
 
 of the sheep, 256 
 Vi\'iparous, application of the term, 
 219 
 
 W 
 
 Warble flies, 53, 57 
 White diarrhea of chicks, 345 
 Wood tick, 143 
 Wo mis, 155 
 
 classification of, 155, 157, 173 
 
 Zooparasites, 8 
 
 Printed in the United States of America 
 
JUL 1 2000 
 MAK 1 8 ZM/