5*5 
 
 {nn 3V 
 
 A- 
 
 V, ?. . 
 
 II B R.ARY 
 
 OF THE 
 U N IVER.SITY 
 OF ILLINOIS 
 
 NATURAL- HISTORY SURVE 
 
 550.5 
 ■FI 
 
 v.2,cop.£ 
 

 Return this book on or before the 
 Latest Date stamped below. 
 
 Theft, mutilation, and underlining of books 
 are reasons for disciplinary action and may 
 result in dismissal from the University. 
 University of Illinois Library 
 
 JUN ? t 
 
 9J5 
 
 L161 — O-1096 
 

Field Columbian Museum. 
 Publication 73. 
 Geological Series. 
 
 Vol. II, No. 1 
 
 NORTH AMERICAN 
 PLESIOSAURS. 
 
 PART I. 
 
 BY 
 
 Samuel W. Williston, M.D., Ph.D., 
 
 Associate Curator, Division of Palaeontology; 
 Professor of Palaeontology, University of Chicago. 
 
 Oliver C. Farrington, Ph.D., 
 Curator of Geology. 
 
 Chicago, U. S. A. 
 
 April, 1903. 
 
( ii:< >logical Series 
 
 Field Columbian Museum. 
 Publication 75. 
 
 Vol. II, No. 1 
 
 NORTH AMERICAN 
 
 PLESIOSAURS. 
 
 PART I. 
 
 \\X 
 
 Samuel \Y. Williston, M.D., Ph.D., 
 
 Associate Curator, Division of Palaeontology ; 
 Professor of Palaeontology, University of Chicago. 
 
 Oliver C. Farrington, Ph. D., 
 Curator of Geology. 
 
 Chicago, U. S. A. 
 
 April, 1903. 
 
NORTH AMERICAN PLESIOSAURS. 
 
 PART I. 
 
 BY SAMUEL W. WILLISTON. 
 
 CONTENTS. 
 
 Introduction, .......... 
 
 Bibliography and catalogue of North American Plesiosaurs, 
 Dolichorhynchops osborni WilHston. I)escrii)tion of skeleton, with restor 
 at ion, ........... 
 
 Ciraoliasaurus snowii Williston, Destription of skull and neck, 
 Brachauchenius lucasii Williston. Description of skull, vertebrae and ribs 
 Polycotylus latipinnis Cope. Description of paddle, 
 l'olycotylus ischiadicus Williston. Description of pelvis, . 
 Plesiosaurus gouldii Williston. Description of dorsal vertebra, 
 Propodial hones of young Plesiosaurs from the Cretaceous of Kans; 
 A peculiar food-habit of the Plesiosaurs, ..... 
 
 Plates 1 to XX IX 
 
 Pagb 
 
 3 
 7 
 
 13 
 
 5- 
 57 
 6 7 
 
 72 
 T- 
 73 
 75 
 79 
 
INTRODUCTION 
 
 There arc few orders of reptiles, so long and so widely known as 
 arc the plesiosaurs, of which our knowledge is more unsatisfactory. 
 It has been within the past decade only that a tolerably complete 
 knowledge of any form has been obtained, thanks largely to the 
 researches of Seeley, Dames and Andrews. Especially is our ignor- 
 ance of the American forms yet great. Very few figures or adequate 
 descriptions have been published of our numerous and diverse types. 
 Not only are the specific characters of the descriptions almost wholly 
 undecipherable, but the generic characters even can be satisfactorily 
 made out in but few. Thirty-two species and fifteen genera have 
 be< d described from the United States, and in not a single one of 
 them has there been even a considerable part of the skeleton made 
 known. The skull is known in but three species, and in only one has 
 there been any description of it. With the exception of a sketch of 
 the incomplete girdles of Elasmosaurus plaiyurus t and of a few limb 
 bones by Leidy, with an outline figure of a Megalneusaurus paddle by 
 Knight, nothing of the extremities has been published. And yet, 
 specimens of plesiosaurs are not at all rare in American deposits and 
 collections. 
 
 Although most of the genera and species of the United States 
 have been founded on such scant material, and even more scanty 
 descriptions, that their identification is almost impossible, except by 
 actual comparison of the type specimens, it is not at all improbable 
 that nearly all the names which have been proposed will eventually 
 be found valid. The group has a wide geological range, from the 
 Jurassic to the uppermost Cretaceous, nearly every epoch being repre- 
 sented by one or more species. 
 
 The writer has for some time given such attention as his duties 
 permitted to the study of the American plesiosaurs, in the hopes 
 eventually of clearing up much of the confusion now existing con- 
 cerning these animals, and the present paper was intended to be pub- 
 lished as a portion of this monographic study. As, however, the 
 publication of so extensive a paper must be deferred for some time, 
 he has thought best to publish that portion now prepared in advance 
 
 3 
 
4 Field Columbian Museum — Geology, Vol. II. 
 
 of a more final review of the subject. The present paper contains 
 detailed descriptions of Dolichorhynchops osborni Williston and Brack- 
 auchenius lucasi Williston; a revised description of Cimoliasaurus 
 
 snowii Williston, together with certain descriptions of and remarks 
 upon such other forms from the Kansas Cretaceous as bear more 
 or less directly upon the principal species here discussed. As 
 will be seen from the list given below, no less than nine distinct 
 species of plesiosaurs have been described from the Kansas Cretaceous, 
 all of which, except one or two, are autoptically more or less known 
 to the writer, together with nearly as many more hitherto undescribed. 
 The true generic determination of the most of these species is impos- 
 sible at present. So little is known of the real generic characters, not 
 only of the American but also of the. European plesiosaurs, that, 
 unless specimens are very complete, it is impossible to correctly 
 assign them. Furthermore, there is in many respects such wide 
 diversity between the different forms now known that almost every 
 species seems rightfully to belong in a different genus. On the other 
 hand, in our present ignorance of their value, generic differences can 
 rarely be recognized unless one has a considerable portion of the skel- 
 eton. Generic determination is, therefore, for the most part, at the 
 present time simply guess-work. In the present paper I have, for 
 convenience sake, given names to some of these new forms, but the 
 generic names are always provisional, and the specific names also 
 in some cases. Cimoliasaurus snowii I do not believe is congeneric with 
 the type" species of the genus; it belongs as well in several other 
 genera proposed by American writers. I do not see, however, much 
 use in giving new generic names to every form until some raise// cfi/rr 
 can be discovered for them. I have departed from this conviction in 
 proposing two new generic names for species herewith described, 
 largely because the specimens upon which the names are based are 
 more than usually complete, and because there seems to be positive 
 characters to sustain the names. 
 
 The full description and illustration of Dolichorhynchops osborni 
 will, I trust, aid in the solution of many of these generic problems; 
 they will at least furnish a means of comparison for other forms known 
 already or to be discovered in the future. 
 
 A second part of this work is to follow soon, I trust. It will 
 contain the descriptions and illustrations of two or three other skulls, 
 different in structure from those herewith described and from each 
 other, together with other important material. 
 
 I am glad to express my thanks to Prof. Dr. E. Fraas for kind 
 
Ark. 1903. North American Plesiosaurs — Williston. 5 
 
 suggestions, and for the communication of photographs; and to Prof. 
 II. F. Osborn for kind favors. 
 
 Seeley* has proposed to divide the plesiosaurs into two chief 
 groups, the Dicranopleura, including those forms with double-headed 
 ribs in the cervical region, both long-necked (Dolichodeira) and short- 
 necked (Brachydeira): and of which singularly no certain representa- 
 tives have been discovered in America: and the Cercidopleura, those 
 with single-headed ribs, also including both long-necked and short- 
 necked types. Cope in iKKyt proposed the two sub-families: Poly- 
 cotylina. for those with broad epipodial bones; and the Plesiosaurina 
 for those with elongated epipodial bones, of which there are no 
 certain representatives in America. But objections may be urged 
 against both of these classifications. Certain forms very closely 
 allied to P/iosai/n/s, a dicranopleuran, have single-headed ribs through- 
 out. Polycotylus is a short-necked type, with single-headed cervical 
 ribs, and it seems almost certain that certain long-necked forms that 
 should be widely separated have also broad epipodial bones. 
 
 Nevertheless, I feel pretty confident that the final classification of 
 the Plesiosauria will include three or four distinct families and twenty 
 or thirty well-defined genera. There is scarcely a group of extinct 
 reptiles, unless it be the Dinosauria, which offers more divergent 
 characters than do the plesiosaurs. The skull may be long and 
 slender or short and broad; the teeth, irregular in size and large, or 
 small and nearly uniform: the prefrontals and postorbitals separated 
 or suturally united: the parietals with a high thin crest, 6r without 
 such a crest; the palatines widely separated or broadly contiguous; 
 the supraoccipitals paired orsingle(P). The neck may include as few 
 as thirteen vertebrae or as many as seventy-two, the vertebrae all 
 very short or the posterior ones elongated; the ribs single or double- 
 headed; the arches anchylosed to the centra or suturally free through- 
 out life: The dorsal vertebrae may be no longer than the anterior cervi- 
 cals or much elongated; all the vertebrae may have conspicuous 
 vascular foramina below or be without them; the diapophyses may 
 be much elongated and situated low down, or shorter and situated 
 high, up; the vertebral spines elongated or short. In the pectoral 
 girdle there may be a long epicoracoidal process; the clavicles and 
 episternum either present or absent. The epipodial bones are two 
 
 ♦Proc. Royal Soc. Lond. 1S92. 151. 
 t American Naturalist. 1SS7. 564. 
 
6 Field Columbian Museum — Geology, Vol. II. 
 
 in number and elongated, or three or four and broad. The ilium may 
 differ in its mode of attachment and the form of both pubis and ischium 
 may differ much. 
 
 Certainly among all these characters, and probably not a few 
 others, there will be no dearth of material for classification. Unfor- 
 tunately there are yet many forms in which we do not know what 
 relations these different characters bear to each other, and until we 
 do, any classification must be provisional. I believe that most 
 herpetological taxonomists will agree with me that the differences 
 between Dolichorhynchops and Brachauchenius are more than generic in 
 value, and I doubt not that differences of equal value will be discov- 
 ered in yet other species when we shall know more about them than 
 we do at present. 
 
 The origin of the Plesiosauria I will discuss in a later paper. 
 For the present, I may say that I believe that their nearest affinities 
 among all reptiles, recent or extinct, are with the Dicynodonts. 
 
CATALOGUE AND BIBLIOGRAPHY OF THE NORTH AMERICAN 
 
 PLESIOSAURIA. 
 
 PLESIOSAURUS. 
 
 Conybeare, Trans. Geol. Soc. Lond. v, 560, 1821. 
 
 BREVI FEMUR Cope, Cret. Yertebr. 256, 1875. — Greensand No. 5, New 
 Jersey. 
 
 Cimoliasaurus magnus (Leidy) Cope, Ext. Batrach. 1S69, 43. 
 ff. 13-15. 
 
 •gulo Cope, Proc. Acad. Nat. Sci. Phil. 1872, 228; Cret. Vert 1875, 
 256. — Fort Pierre Cretaceous, Kansas {t'rrorc, Niobrara). 
 
 *MUDGE1 Cragin, Fifth Pub. Colorado Col. Sci. Soc. 69, ff. 1-3. — 
 Comanche Cretaceous, Kansas. 
 
 *GOULDil Williston, Kansas Univ. Quart, vi, 57, 1897. — Comanche 
 Cretaceous, Kansas. 
 
 sHiRLKVKNSis Knight, Amer. Journ. Sci. 1900, p. 115. — Jurassic, 
 Wyoming. 
 
 All of the foregoing species were based upon fragmentary mate* 
 rial, and it is improbable that any belong in the genus Plesiosaurus. 
 
 CIMOLIASAURUS. 
 Leidy, Proc. Acad. Nat.. Sci. Phil. 1851, 325 (1852). 
 
 MAGNUS Leidy, I.e.; ibid. 1854, 72, pi. ii, ff. 4-6: Cretac. Rept. 1865, 
 25, pi. v, ff. 13-19, pi. vi; Cope, Ext. Batrachia, etc. 1869, 
 42; Lydekker, Cat. Fos. Rept. Brit. Mus. 11, 211. — Creta- 
 ceous No. 5, New Jersey. 
 
 ii, amor Leidy, Proc. Acad. Nat. Sci. Phil. 1870, 22. — Cretaceous, 
 New Jersey (see also Discostiurus'). 
 
 *SNOWll Williston, Science, xvi, 262; Trans. Kansas Acad. Sci. xii, 
 174, 1890; Cope, Proc. Amer. Phil. Soc. xxxiii, 109. — Nio- 
 brara Cretaceous, Kansas. 
 
 laramiensis Knight, Amer. Jour. Sci. x, 117, 119. — Jurassic, Wyo- 
 ming. 
 
 7 
 
•8 Field Columbian Museum — Geology, Vol. II. 
 
 This genus was based s upon vertebral centra alone, from the 
 ■cervical, dorsal and caudal regions: the author, however, referred 
 them all erroneously to the dorsal and lumbar regions. The type is 
 well figured in Leidy's work on Cretaceous Reptiles, plates v and vi. 
 The vertebrae have infracentral vascular foramina. The ribs are 
 single-headed. The largest centrum measures no millimeters in 
 the greatest diameter. This genus has served as a sort of waste 
 basket for the reception of fragments and poorly known forms. C, 
 snotvii is known from a skull and long neck. It can scarcely belong 
 i n Cimoliasaitrus. 
 
 DISCOSAURUS. 
 Leidy, Proc. Acad. Nat. Sci. Phil. 185 1, 326 (1852). 
 
 i'Lanior Leidy, Proc. Acad. Nat. Sci. Phil. 1870, 20, 22; Cope, Cretac. 
 Vert. 1875, 255 (Cimoliasaitrus). — Cretaceous, Mississippi. 
 
 Discosai/rus vetustus Leidy, Cretac. Reptilia, 23, pi. 5, ff. 10-12. 
 
 vetustus Leidy, Cretac. Reptilia, 22, pi. iv, ff. 13-18, pi. v, ff. 1-9; 
 Proc. Acad. Nat. Sci. Phil. 1851, 326; Cope, Ext. Batrachia 
 etc. 256; Amer. Journ. Sci. 1870, 141; Cretac. Vert. 1875, 
 255 (Cimoliasaurus). — Cretaceous, Alabama. 
 
 This genus was based upon the mutilated bodies of two caudal 
 vertebrae from the Cretaceous of Alabama. Leidy associated with 
 these other mutilated vertebrae from the Cretaceous of Mississippi, 
 New Jersey and Alabama. Cope suppressed the name, as of a genus 
 insufficiently differentiated from Cimoliasaiirits. This is quite true, as 
 it is also true of several of Cope's own genera of the plesiosaurs. It 
 is not at all improbable, however, that there are different species, and 
 perhaps different genera represented by the specimens Leidy described 
 and figured. 
 
 BRIMOSAURUS. 
 Leidy, Proc. Acad. Nat. Sci. Phil. 1854, 73. 
 
 <;randls Leidy, Proc. Acad. Nat. Sci. Phil. 1854, 73, pi. i, ff. 1-3; 
 ibid. 1870, 10; ibid. 1871, 22 (Discosauri/s); Cope, Ext. 
 Batrachia, etc. 1869, \7,,^(Cii/io/iasauri/s); Proc. Bost. Soc. 
 Nat. Hist. 1869, 266 (id.)', Amer. Journ. Sci. 1870, 269 (id.), 
 Rep, Geol. Surv. Terr. 1871, 400 (id.)', Cretac. Vert. 1875, 
 2 55 ( l 'd.) — Cretaceous, Arkansas. 
 
 Tins genus and species were founded upon more or less imperfect 
 
Apr. 1903. North American Plesiosaurs — YVilliston. 9 
 
 dorsal vertebrae from the Cretaceous, probably Benton, of Clark 
 County, Arkansas. Cope suppressed the generic name as of a genus 
 not sufficiently differentiated from Cimo/iasaurus. I believe, however, 
 that both genus and species are valid; and that the former will include 
 some of the species from Kansas. Lambe has identified the species 
 from the Belly River Cretaceous of Canada, but it seems to me that 
 the identity must be more or less problematical. 
 
 ELASMOSAURUS. 
 
 Cope, Proc. Acad. Nat. Sci. Phil. 1868, 68. 
 
 •platyurus Cope, 1. c; Notes on Geology, Leconte, 1868, 68; Proc. 
 Bost. Soc. Nat. Hist. 1869, 266; Amer. Nat. iii, 87; Ext. 
 Batrachia, etc. 1869, 47, ff. 7-12, pi. ii, ff. 1-9, pi. iii; Amer. 
 Jour. Sci. 1870, 140, 268; Amer. Nat. v, 47; Rep. U. S. Geol. 
 Surv. Terr. 1871, 393, 1872, 320, 336; Cretac. Vert. 1875, 44, 
 79, 256; Bull. U. S. Geol. Surv. Terr, iii, 1877, 578; Amer. 
 Nat. xxii, 724; Leidy, Amer. Jour. Sci. xlix, 1870, 392; Proc. 
 Acad. Nat. Sci. Phil. 1870. 9, 18; Lydekker, Cat. Foss. Rept. 
 Brit. Museum, ii, 181 (Cimo/iasaurus). — Fort Pierre Cretace- 
 ous, Kansas. 
 
 intermediis Cope, Proc. Amer. Phil. Soc. 1894, 112. — Fort Pierre 
 Cretaceous, South Dakota. 
 
 0RIENTALI3 Cope, Proc. Acad. Nat. Sci. Phil. 1868, 313; Proc. Bost. 
 Soc. Nat. Hist 1869, 266; Geological Surv. New Jersey, 
 Cook, Append. (1868), 1869, 733; Amer. Nat. 1869, 87; Ext. 
 Batrachia, etc. 1869, 44, 55, pi. ii, f. 10; Amer. Jour. Sci. 
 1870, 368; Cretac. Vert. 1875, 255; Bull. U. S. Geol. Surv. 
 Terr, iii, 1877, 567, 578; Am. Nat. xi, 1877, 311; Leidy, Proc. 
 Acad. Nat. Sci. Phil. 1870, 22 {Discosaurus). — Greensand No. 
 4, New Jersey. 
 
 skri'Iniinis Cope, Bull. U. S. Geol. Surv. Terr, iii, 578, 1877; Amer. 
 Nat. xi. 1S77, 311. — Niobrara Cretaceous, Nebraska. 
 
 The genus Eiasmosaurus was founded upon a nearly complete 
 series of vertebra? obtained near the vicinity of Fort Wallace, Kansas, 
 wrongly ascribed to the Niobrara epoch. The neck was very long. 
 The incomplete girdles are also known. No additional material has 
 been ascribed to the type species since the original description by 
 
 Cope. 
 
io Field Columbian Museum Geology, Vol. II. 
 
 POLYCOTYLUS. 
 Cope, Proc. Amer. Phil. Soc. xi, 117, 1869. 
 
 *latii'innis Cope, 1. c; Ext. Batrachia, etc. 36, pi. 1, ff. 1-12; An. 
 Rep. U. S. Geol. Surv. 1871, 388; ibid. 1872,320,335; Bull. 
 U. S. Geol. Surv. Terr. 27, 1874; Cretac. Vertebrata, 45, 72, 
 255, 1, vii, ff. 7, 7a; Leidy, Ext. Vert. Fauna. 279. — Niobrara 
 Cretaceous of Kansas. 
 
 *ischiadicus Williston, postea, Niobrara Cretaceous, Kansas. 
 
 This genus was based upon a portion of a propodial bone and 
 imperfect cervical and dorsal vertebrae. The ribs of the neck are 
 single-headed. 
 
 PIRATOSAURUS. 
 Leidy, Cretaceous Rept. N. Amer. p. 29, 1865 
 PL1CATUS Leidy, 1. c. pi. xix, fig. 8. — Cretaceous, Minnesota. 
 
 Based upon a single tooth. Believed by the author to be Cro- 
 codilian. The horizon is probably Niobrara, judging from the 
 accompanying fossils. If so, it would seem very probable that the 
 tooth belongs to a plesiosaur, though rather sharply conical in shape. 
 
 NOTHOSAUROPS. 
 Leidy, Proc. Acad. Nat. Sci. Phil. 1870, 74. 
 
 occiduus Leidy, 1. c. ; Rep. Geol. Surv. Terr. 1873, i, 345, pi. xv, ff. 
 11-23; Cope, Bull. U.S. Geol. Surv. Terr, i, 28, i8j^.(P/cs/o- 
 saitrus); Cretac. Vert. 1875, 256 {id.). — Laramie [?] Cretaceous, 
 Dakota. 
 
 TAPHROSAURUS. 
 Cope, Proc. Amer. Phil. Soc. xi, 274, 1870. 
 
 lockwoobi Cope, Ext. Batrachia, etc. 1869, 40 {P/i-siosa/tri/s); Proc. 
 Amer. Phil. Soc. xi, 274. — Cretaceous No. 1, New Jersey. 
 
 OLIGOSIMUS. 
 Leidy, Proc. Acad. Nat. Sci. Phil. 1872, 39 (1873). 
 
 GRANDjEVUS Leidy, 1. c. 40; Extinct Vert. Fauna, 286, 345, pi. xvi. 
 ff. 18, 19.— 
 
 This genus and species were proposed for a detached caudal 
 vertebra of small size, without definite horizon, from Green River, 
 
Apr. 1903. North American Plesiosaurs — Willi STON. 11 
 
 Wyoming. The processes are attached. The description will apply 
 to caudal vertebrae of various genera. 
 
 URONAUTES. 
 Cope, Proc. Acad. Nat. Sci. Phil. 1876, 345. 
 cetiformis Cope, 1. c. 346. — Fort Pierre (?) Cretaceous, Montana. 
 
 species Cope, Amer. Nat. 1887, 566. — Fox Hills Cretaceous, New 
 Mexico. 
 
 This genus was based upon cervical, dorsal and caudal vertebrae. 
 The cervicals are short, with the processes partly attached, and the 
 ribs single-headed. 
 
 Professor Cope referred the type species to the Fox Hills Cre- 
 taceous with doubt. I suspect, rather, that the horizon is Fort 
 Pierre. 
 
 OROPHOSAURUS. 
 
 Cope, Amer. Naturalist, 1887, 564. 
 
 PAUCIPORUS Cope, 1. c. — Fox Hills Cretaceous of New Mexico. 
 
 Based upon parts of three cervical vertebrae. The neural arches 
 art coossified, the ribs free. Centra short; ribs single-headed. 
 
 P1PTOMERUS. 
 Cope, Amer. Nat. 1867, 564. 
 UEGALOPORUS Cope, 1. c. 564. — Fox Hills Cretaceous, N» \v Mexico. 
 MICROPORUS Cope, 1. c. — Fox Hills Cretaceous, New Mexico. 
 HEXAGONUS Cope. 1. c. — Fox Hills Cretaceous, New Mexico. 
 
 This genus and species are based upon cervical and dorsal verte- 
 bra only. The cervicals are short, the processes free and the ribs 
 single-headed. 
 
 TR1NACROMERUM. 
 < Cragin, Amer. Geologist, Dec. 1888. 
 
 • i'.kn iomantm Cragin, 1. c. ; ibid, 1891, 171. — Penton Cretaceous, 
 Kansas. 
 
 A large part of the skeleton was known to the describer, includ- 
 ing the skull, vertebra-, part of the girdles and limbs. 
 
12 Field Columbian Museum — Geology, Vol. II. 
 
 PANTOSAURUS. 
 Marsh, Report Geological Congress, 1891, 159; Amer. Journ. Sci. 
 xli, 1895, 406; Parasaurus Marsh, Amer. Journ. Sci. xliii, 
 338, 1891 (preoccupied). 
 
 STRIATUS Marsh, Amer. Journ. Sci. xliii, 338, 1891 (Parasaurus); ibid, 
 i, 406, 1895, ff. — Baptanodon Beds, Wyoming. 
 
 Based upon a posterior cervical centrum. "Vertebrae strongly 
 grqoved. Neck long and slender, the vertebrae preserved resemble 
 most in form and size those of Plesiosaurus plicatus Phillips." 
 
 EMBAPH1AS. 
 Cope, Proc. Amer. Phil. Soc. 1894, 111. 
 CIRCULOSUS Cope, 1. c. — Pierre Cretaceous, South Dakota. 
 
 This genus and species were founded on three vertebrae, cervical 
 and dorsal. The cervicals are short, with persistent sutures. Ribs 
 double-headed(P). 
 
 MEGALNEUSAURUS. 
 Knight, Amer. Journ. Sci. v, 1898, 375. 
 
 rex Knight, Science, 1895, 449 {Cimoliasaurus)\ Amer. Journ. Sci. v, 
 I 8g8, 379, ff. 1-3. — Jurassic, Wyoming. 
 
 A large portion of the skeleton of the type species is known; the 
 parts so far described are the vertebrae and limbs. 
 
 ■ DOLICHORHYNCHOPS. 
 
 YYilliston, Kansas Univ. Sci. Bulletin, No. 9, p. 141, Sept. 1902. 
 *osborni Williston, 1. c. — Niobrara Cretaceous, Kansas. 
 
 BRACHAUCHENIUS. 
 
 Williston, postea. 
 *lucasi Williston, postea. — Benton Cretaceous, Kansas. 
 
Apr. 1903. North American Plesiosaurs — Williston. 13 
 
 DOLICHORHYNCHOPS OSBORNI. 
 
 The specimen of DolichorJiynchops osborni herewith described and 
 illustrated was discovered by Mr. George Sternberg in the chalk of 
 Logan County, Kansas, in the summer of 1900, and skilfully collected 
 by his father, Mr. Chas. H. Sternberg, the veteran collector of fossil 
 vertebrates. The specimen was purchased of Mr. Sternberg in the 
 following spring for the University of Kansas, where it has been 
 mounted and where it now is. When received at the museum the 
 skeleton was almost wholly contained in a large slab of soft yellow 
 chalk, with all its bones disassociated and more or less entangled 
 together. The left ischium, lying by the side of the maxilla, was 
 protruding from the surface, and a part of it was lost. The bones of 
 the tail and some of the smaller podial bones were removed a little 
 distance from the rest of the skeleton, and were collected separately 
 by Mr. Sternberg. The head was lying partly upon its left side and 
 some of the bones of the right side had been macerated away; the 
 maxilla indeed had disappeared. 
 
 The task of removing and mounting the bones has required the 
 labor of Mr. H. T. Martin the larger part of a year, and is, as finally 
 mounted, an example of great labor and skill on his part. For the 
 position of the bones in the recreated skeleton and their general 
 arrangement I am of course responsible. There is some little doubt 
 as to the exact position of the pectoral girdle, as respects the ribs and 
 vertebrae. The position as shown in the restoration is that which 
 med, upon the whole, most nearly the truth, judging from the 
 figured skeletons of Plcsiosaurus. There is also some doubt about 
 the proper length of the tail. The relations of the preserved centra 
 seemed to indicate a loss of a few vertebrae in this region, and for 
 that reason four plaster models have been intercalated. There are 
 nineteen vertebrae preserved in the neck; there may have been one 
 more, or possibly two, but for reasons discussed further on this is 
 doubtful. In the dorsal region their are thirty vertebrae, three of 
 which maybe called pectoral. Twenty-five are preserved in the tail. 
 The skull, after its complete removal from the matrix, was found 
 to be so very fragile that it was not thought expedient to mount it. 
 It was also somewhat distorted, as will be seen from the illustrations. 
 A model, therefore, was made under my careful supervision, and 
 mounted in its stead. The skeleton as mounted is just ten feet in 
 
14 Field Columbian Mtseum — Geology, Vol. II. 
 
 length. The neck in life must have been thick and heavy at the base, 
 tapering rapidly from the trunk to the head. The'trunk was broad, 
 as is evident from the position of the ribs, with the under side not flat, 
 as might be supposed, but strongly convex from side to side. The 
 abdominal region proper, between the girdles, must have been short, 
 and could not have been very distensible. The short tail was thick at its 
 base, as is conclusively shown by the attachment of the ilia and the 
 elongated ischia. Furthermore, the fore legs, at least, must have 
 been enclosed for a considerable distance at their attachment by the 
 skin and muscles of the pectoral region; they could not have been 
 pedunculated to the extent that they are usually represented to be in 
 the restorations. The species was named in honor of Prof. H. F. 
 Osborn of Columbia University. 
 
 The distinguishing characters, both family and generic, may be 
 summed up as follows: 
 
 Dolichorhynchops. — Head elongate, the facial 'region much attenuated; 
 teeth nearly uniform in size, small; prefrontal and post frontal bones not 
 joined; parietals extending into a high crest; sup/ aoeeipilal bones separated ; 
 internal nares small, included between the vomer and palatine only ; pala- 
 tines broadly separated throughout ; a large vacuity between the pterygoids 
 anteriorly; quadrate proeess of pterygoids short. Neek but little longer 
 than the head, eon/posed of nineteen or twenty vertebra'; all presacral 
 vertebra' of nearly equal length, moderately eoneave, and with vascular 
 foramina below; spines short, uniform in length; diapophyses of the dorsal 
 vertebra situated high up. Coraeoids with long epicoracoid process; 
 clavicles and seapuhe free; episternum with an emargi nation in front and 
 behind, the latter forming part of a large interclavicular foramen. 
 Three cpipodial bones, all broader than long. Ischium elongated, 
 length ten feet. 
 
 Skull. — The skull of Dolichorhynchops osborni is of a remarkably 
 elongate and slender form, attenuated in front of the orbits, and with a 
 thin, high, parietal crest. The region between the eyes is very nar- 
 row, the superior temporal vacuities large, and the teeth numerous 
 and slender. The head is more nearly of the typical aquatic fish-eat- 
 ing type than is perhaps known in any other plesiosaur, and the neck 
 is as short as or shorter than in any other plesiosaur hitherto 
 described. The skull, as received, was lying partly upon its left side, 
 with a part of the right side separated and injured, some of the bones 
 having been macerated away. The specimen was completely removed 
 from the matrix, including even that which was between the bones, 
 and the elements of the brain case were separated out. In conse- 
 
Ahr. 1903. North American Plesiosaurs — Williston. 15 
 
 quence, the fragility of the skull was such that it was not deemed 
 prudent to mount it with the remainder of the skeleton. A model of 
 it was therefore made, based upon my drawings and studies, and 
 which, I think, represents the skull very nearly as it must have been 
 during life. Its width in all parts may not have been accurately 
 determined, but the discrepancies from the reality can not be great. 
 
 The premaxillaries are separated from each other distinctly by 
 suture, the long facial processes apparently lying in contact with each 
 other without close union. The suture separating them from the 
 maxilla begins just back of the sixth tooth ; it curves upward and 
 backward for a short distance, and then runs parallel with the upper 
 border as far back as the narial opening, whence the margin runs more 
 obliquely to the tip of the processes above the middle of the orbit. 
 Each premaxilla bears six teeth, which are among the largest of the 
 jaws, and are all of nearly uniform size, the first one curved forward. 
 The facial process is slender, flattened on its opposing, sutural sur- 
 face, and with its external, convex surface distinctly striated longi- 
 tudinally. The dentigerous portion is convex, pitted toward the 
 anterior part, and about twenty- five millimeters in height, opposite 
 the last tooth. The relations of the bone on the palatal surface can 
 not be determined. 
 
 The maxilla are long and narrow on the facial surface, and 
 very narrow on the palatal surface, at least posteriorly. They bear 
 twenty teeth on each side, the first ten or eleven of which are 
 of nearly equal size, and scarcely smaller than those of the pre- 
 maxilla?. The posterior ten teeth are crowded, occupying a 
 space less than one-half that of the preceding ten, and they are 
 smaller. The greatest width of the maxilla on the facial surface 
 —about twenty-five millimeters — is at about seventy millimeters in 
 front of the orbit, whence the bone narrows to a width of ten milli- 
 meters below the anterior border of the x orbit. Below the orbit, the 
 bone extends as a narrow bar, becoming slightly narrower posteriorly, 
 before the beginning of the jugal suture. Beyond this, it flattens 
 posteriorly to near its extremity, which is about midway of the tem- 
 poral bar, and one hundred millimeters beyond the last tooth. 
 
 There are twenty-five or twenty-six teeth in each jaw. They are 
 inserted by a long fang, the pulp cavity of which occupies more than 
 one-third of the diameter, extending a short distance into the crown. 
 In the largest teeth, the crown is about twenty millimeters in length, 
 with a diameter at the base of six millimeters. The crown is rela- 
 tively slender, strongly convex anteriorly, sharply conical, and with 
 slender, delicate, longitudinal stiia 1 , except on the outer, anterior 
 
16 Field Columbian Museum — Geology, Vol. II. 
 
 part, where the surface is nearly smooth. The posterior teeth are 
 much smaller, as already stated, and are much more closely placed, 
 their length varying from six to twelve millimeters. 
 
 The united parietals form a high, thin, vertical plate of bone, 
 convex in outline, about fifty millimeters in height in the middle, and 
 only three or four in thickness at the margin, and extending nearly as 
 far forward as the pineal foramen. Posteriorly, the sides extend 
 downward and outward into a broad flattened process for union with 
 the upper ramus of the squamosal. The suture, which is clearly 
 apparent, runs downward and outward to the free margin of the 
 parietal on each side, beginning in front of the posterior thickened 
 bar of the squamosal. Anteriorly this free margin of the parietal is 
 continued outward, like the eaves of a roof, to the posterior part of 
 the orbit, where it is somewhat roughened ; it turns upward here 
 rather abruptly. About twenty millimeters above- this angle, separated 
 by a concave space, is the massive projection for the epipterygoid. 
 This bone has been broken away from its attachment on each side, 
 and separated for a short distance, leaving a jagged fracture, without 
 indications of suture. The upper margin of this thickened epiptery- 
 goid protuberance is continued by sutural union with the postfrontal. 
 A little in front of the parietal foramen, the bone narrows to a width 
 of four or five millimeters, blended with and continued into the frontal, 
 which continues forward to the premaxillary, under which it disap- 
 pears. The sutural union for the postfrontal is well marked on the 
 right side, beginning a little back of the pineal foramen and running 
 downward, outward and backward to the upper margin of the epiptery- 
 goid protuberance. Internally the parietals form a broad roof, to 
 which is attached, rather far forward, by distinct, oval, obliquely 
 placed, V-shaped articular surfaces, the paired supraoccipitals, which 
 do not reach quite to the lower free margin of the parietals on 
 each side. 
 
 Anteriorly,, as already stated, the frontal (?) continues, without 
 the slightest indication of a suture with the parietals, forward for forty 
 millimeters or so more, as a narrow, flattened surface above, distinctly 
 divided by a median suture, to the upper end of the facial processes 
 of the premaxillae, which articulate on the outer side of the slender 
 projection, overlapping the upper surface. How much further the 
 bones continue I can not say, but evidently as far forward as the 
 anterior end of the orbits. On the right side, the " postprefronto- 
 nasal" has been macerated away, so that its relations are clearly 
 marked. Below these bones are broader, continuous on each side 
 with the free margin of the roof, as already described. The rostrum 
 
Apr. 1903. North American Plesiosalrs — Willis ion. 17 
 
 formed by the " frontals " is stout and rounded, and is continued at 
 least as far forward as the anterior end of the orbit, clearly separated 
 above and below by the median suture. The anterior ends are lost in 
 front in the broken fragments of bone, between and beyond the 
 anterior end of the orbits. Lying between the orbits, and separated 
 from each other by a narrow interval, are the narrow bones which may 
 represent the conjoined postfrontals and prefrontals and nasals. On 
 the right side, as stated above, the bone had been macerated away, 
 and while some of its processes had been broken off and lost, the 
 sutures for union with the parietal, frontal and prefrontal are beauti- 
 fully preserved, showing the relation to these bones in a way that 
 precludes doubt. The bone shows no trace of division whatever into 
 its supposed elements. It articulates with the "frontal," parietal, 
 epipterygoid, " postorbital," '• supraorbital," 'premaxilla and maxilla. 
 Posteriorly the bone extends downward, outward and backward to the 
 upper margin of the epipterygoid protuberance; externally and 
 posteriorly it sends off a projection for union with the post-orbital ; 
 anteriorly the bone fits into a groove on the outer side of the facial 
 processes of the premaxillaries for a distance of thirty or forty milli- 
 meters, and has a stout process on the outer side for union with the 
 supraorbital, or whatever the element may be here. On the under 
 side there is a broad, flattened, vertical plate, continuous from the 
 posterior, inferior angle, and widened in the middle so as to reach the 
 greater part of the way to the upper surface of the palatal bone, form- 
 ing the inner wall of the orbit in large part. The plate given off for 
 union with the "supraorbital" is separated by a sharp, deep notch 
 from a similar process for union with the " postorbital. " The ' ' supra- 
 orbital" bone has been crushed back over this process, so that the 
 distinguishing suture can be perceived in one place only, anteriorly. 
 In front of the orbit, the bone sends out a thin, triangular plate, 
 which curves downward to meet the maxillae, separated from its mate 
 by the premaxillae. Doubtless this part represents the nasal, and per- 
 haps also the lachrymal, but there are no indications of distinguishing 
 sutures, and I do not believe that the nasal exists as a separate ele- 
 ment in the adult plesiosaur — I can not find that it has ever been 
 described in any plesiosaur. It joins the maxillae broadly and the 
 "supraorbital" behind; in the angle between the three bones is 
 located the small external nares. Below the supraciliar plate, near 
 the anterior part of the orbit, on the side of the prefrontal, there is a 
 well-defined fossa, leading forward into the ethmoidal region, into 
 which opens a small foramen from the upper surface between the pre- 
 frontal and supraorbital. 
 
 
i8 Field Columbian Museum — Geology, Vol. II. 
 
 The supraorbital forms, as already stated, a horizontal plate 
 extending out over the orbit in front. Its union with the prefrontal 
 posteriorly is obscured by fracture, but indications of a suture are 
 seen anteriorly. Between this bone and the postorbital there is a 
 deep notch, angulated externally. The suture between the prefrontal 
 and supraorbital is clearly seen anteriorly, running from the small 
 foramen already mentioned forward and outward to terminate near 
 the maxilla, at the posterior end of the nares. The connection of the 
 bone with the maxilla can not be made out, as there has been an 
 infolding here ; its connecting suture with the ascending process of 
 the maxilla is, however, well defined, running obliquely forward. 
 The descending plate of the supraorbital has, in its orbital margin 
 near the upper part, a small foramen, piercing the bone obliquely. 
 The horizontal portion terminates anteriorly by sinking to the surface 
 of the descending portion. The whole bone reminds one of the pre- 
 frontal of Clidastes, 
 
 The postorbital bone is a narrow, elongate and thin bone, united 
 above with the postfrontal, and to a slight extent with the parietal, 
 near the top of the epipterygoid ; below to the jugal. On the right 
 side, this bone, like the postprefrontal and jugal, has been macerated 
 away, and, although somewhat distorted, presents no evidence of 
 being composed of more than one element. 
 
 In the above description of these frontal elements, I have fol- 
 lowed the usual determinations, but I am not satisfied with them. The 
 "supraorbital," though occupying the position usual for this bone 
 above the orbit, has relations anteriorly that are altogether unusual ; 
 the nasal and the lachrymal do not appear to exist as independent 
 elements. It would seem more likely that this supposed "supra- 
 orbital" is really the lachrymal, if the postfrontal and prefrontal are 
 fused into one element. Again, such a combination of the postfrontal 
 and prefrontal and their peculiar articulations is remarkable. The 
 very narrow frontal, while showing a distinct suture in the middle, 
 presents no evidence of any connection with the parietal — it seems 
 more to be a very narrow rostrum projecting in front of the parietal 
 and separating the bones, which otherwise would answer very well 
 for frontals. In this latter case, the so-called "supraorbital" would 
 really be the prefrontal, and the postorbital the postfrontal or post- 
 fronto-orbital. This may seem a violent supposition, but it does not 
 seem at all improbable to me. Nor is the union of the parietal with 
 the premaxilla any more extraordinary than is the union of the supra- 
 occipital with the frontal in many Cetacea. 
 
 Sclerotic plates are present in the left orbit of this specimen in a 
 
Apr. 1903. North American Plesiosal rs-»— Willis ion. 19 
 
 nearly undisturbed condition. There are fourteen in the ring with 
 beveled and imbricated contiguous margins, in texture, size and 
 position very much like the corresponding bones of the mosasaurs. 
 The pupillary opening measures about thirty millimeters in diameter, 
 and the entire diameter of the ring is about seventy millimeters. The 
 occurrence of sclerotic plates in the plesiosaurs has long been known. 
 1 described them in Cimoliasaurus snowii in 1890, and Owen many 
 years earlier (Fossil Reptilia of the Liassic Formation, p. 10) said: 
 " In both orbits some of the thin sclerotic plates of the eyeball are 
 preserved ; this is the first specimen in which I have had evidence of 
 their structure." 
 
 The jugal is a small element intercalated between maxilla, post- 
 orbital and squamoso-prosquamosal. The suture separating it from 
 the maxilla runs nearly parallel with the lower border of the bone. 
 In its posterior third this suture is very distinct ; it seems to be con- 
 tinued forward to attain the margin of the orbit at its lower ppsterior 
 part. Above, the bone is distinguished from the postorbital by a 
 nearly parallel suture : behind by a nearly transverse suture from the 
 squamosal. On the right side, the jugal had been separated from the 
 other bones by maceration ; its relations, therefore, are positively 
 indicated. The bone terminates about twenty millimeters before the 
 posterior end of the maxilla. On the inner side, just back of the 
 rounded orbital margin, the bone articulates by a flattened surface, 
 about the size of one's finger-nail, with the ectopterygoid. The bone 
 is pierced on its outer surface by three or four small zygomatic 
 foramina. 
 
 The broad, triradiate element, variously considered as being com- 
 posed of, or the homologue of, the squamosal and mastoid by Owen*, 
 the squamosal and supratemporal by Andrewst, the squamosal and 
 prosquamosal by Owen and Baur, the supratemporal and supramas- 
 toid by CopeJ, the squamosal, supratemporal and quadratojugal by 
 Woodward^, differs materially in its structure from that described or 
 figured in other plesiosaurian skulls, in that the element, or elements, 
 whatever they are, articulate proximally with the maxilla, as well as 
 :he postfrontal and jugal. Posteriorly, the suture separating the. bone 
 
 ♦Trans. Geol. Soc. Load. (2). v. pt, iii. pi. xlv. 1840. 
 
 t Quart. Journ. Geol. Soc. Lond. lvii, 249. 1896. 
 
 % Proc. Amer. Phil. Soc xxxiii, no, 1894. Cope, in his es-;i\ on the posterior cranial arches in 
 he Reptilia (Trans. Amer. Phil. Soc. 1892), reaches the conclusion that the lower temporal har of 
 he Crocodilia, Sphcnodoiiy etc.. corresponds with the zygomatic arch of the mammalia, and there* 
 .-<■ suppresses the term '•squamosal." The squamosal— so-called— in the Reptilia he calls the 
 upramastoid. absent in the lacertilia and other forms. 
 
 S Vert. Paleont., f. 116 A, 1898. 
 
20 Field Columbian Museum —Geology, Vol. II. 
 
 from the quadrate is situated as in Cinwliasaunts snowii, at the external 
 angle of the quadrate, which it borders to its upper extremity.. At 
 the lower extremity there is a very distinct squamate suture, running 
 upward and forward and becoming lost about twenty millimeters from 
 its origin. This suture is clearly apparent on the two sides, and is 
 also seen in the skull of Cifnoliasaurus snowii, as it was figured by 
 myself (1. c.) and Cope*. Just what the course of the suture is 
 anteriorly I cannot say, but I believe that it is indicated by a line 
 passing forward to the maxilla, and excluding that bone from union 
 with the squamosal. Whatever be its relations anteriorly, I doubt 
 not that the quadratojugal exists as a distinct ossification in the 
 plesiosaurs. In a separated quadrate of another species of plesiosaur 
 ( T. aiwnymum Will.), from the Benton of Kansas, the sutural sur- 
 faces for union with the quadratojugal and squamosal are clearly dis- 
 tinguished. The quadratojugal does not enter into the formation of 
 the condylar surface of the quadrate, as has been suspected, and as it 
 does in Sphenodon; this is certain. On the outer side of this quadrate, 
 just above the articular surface, there are two sutural surfaces — one 
 on the posterior and outer border, for the attachment of the squamosal, 
 the other on the anterior border for the attachment of the quadrato- 
 jugal, which, in this case, as also in Dolichorhynthops osbomi, must 
 have been overlapped in part by the squamosal. In Cimoliasaurus 
 snowiii the suture between the squamosal and the quadratojugal is 
 very clearly indicated from the exterior, the squamosal not descend- 
 ing as low as in the other species. The suture shown as separating 
 the quadratojugal from the squamosal anteriorly is conjectural, but I 
 believe, as already stated, that it will be found to extend as far for- 
 ward as the maxilla. 
 
 The suture separating the squamosal from the postorbital is short 
 and vertical, joining the border near the anterior extremity of the 
 bone, as seen from the outer side. The suture joining the jugal is a 
 squamous one, extending on the inner side nearly to -the margin of the 
 orbit, but leaving a small space for the union of the ectopterygoid 
 with the jugal. The suture with the maxilla is long and oblique, con- 
 cealed. in about half its extent by the jugal. I believe, however, that 
 the squamosal is really separated from the maxilla by the intervention 
 of the quadratojugal, as already described, and for which there seems 
 to be some evidence in the specimen. On the right side the maxilla 
 had been removed by maceration, leaving the sutural surface for the 
 temporal element very clear in its whole extent. 
 
 Posteriorly, the sutural line of the squamosal passes downward 
 
 * Froc. Amer. Phil.Soc. 1894. 
 
Apr. 1903. North American Plesiosaurs — Willis ton. 21 
 
 bv a somewhat zigzag line to reach the inner border of the quadrate a 
 little above the border of the pterygoid process. On the inner side, 
 the sutural line passes nearly directly across, and then upward to the 
 inner border. 
 
 The connection with the parietal is definite. The suture indi- 
 cated by Copt- in his figure of Cimoliasanriis snowii (1. c. ) does not 
 exist in the specimen figured, nor is there any such in the skull of 
 Dolichorhynchops osborni here described. In order to definitely deter- 
 mine this fact I removed the portion supposed by Cope to be the 
 supramastoid from the skull of the Cimoliasanriis specimen and carefully 
 cleaned it. thereby proving beyond peradventure that the supposed 
 suture is in reality a fracture. The squamosal, or as it should be 
 called, the squamoso-prosquamosal, in that form, as will be described 
 hereinafter, reaches to the top of the skull, notwithstanding Baur's 
 opinion to the contrary. . The two squamosals touch each other, or 
 nearly do so, as in the skull of Cryptoclidus described by Andrews. 
 
 The temporal bar in the plesiosaurs, it is thus seen, is composed 
 of the jugal, qnadratojugal, squamosal and prosquamosal (supratem- 
 poral). This last element is not distinct in either of the skulls here 
 described, nor is it usually apparent in the adult skull, but Owen* 
 d< scribes and figures it as distinct; Andrews also saysf that " In sev- 
 eral Plesiosaurian skulls in the British Museum the suture between 
 these elements is distinct." 
 
 The quadrate is a short and broad bone, united by a pit-like 
 sutural surface on the inner side with the posterior prolongation of 
 the pterygoid, on the outer side with the squamosal and qnadrato- 
 jugal, as already described. Posteriorly the sutural surface for the 
 squamosal begins a little above the pterygoid articulation, runs down- 
 ward and outward for a short distance, then upward and outward to 
 another point, whence it goes downward to appear on the outer sur- 
 face a little below the angle of the bone, which it follows nearly to 
 the lower articulation. The articulation for the paroccipital is imme- 
 diately above and before the pit for the articulation of the pterygoid. 
 A separated quadrate of another species (7\ anonym 11m), already 
 described in part, with its sutures distinct and the bone undistorted, 
 shows an elongated articular surface, broadest upon the inner end, 
 narrowed and turned upward at the outer extremity nearly to the 
 lower end of the squamosal articulation. A non-articular groove on 
 the inner side of the middle behind divides the articular surface; it 
 does not appear to be present in either of the other species. The 
 
 ♦Trans. Geol. Soc. 121, v. Fl. xiv (1840). 
 fQuart. Journ. Geol, Soc. Hi, 250, 1S96. 
 
22 ■ Fikld Columbian Museum — Geology, Vol. II. 
 
 pterygoid articular surface reaches to within about twenty-five milli- 
 meters of the articular extremity. The inner border of the pit is 
 produced forward for articulation, apparently, with the paroccipital. 
 The two narrow, concave, articular surfaces for the squamosal and 
 quadratojugal are separated by a narrow, non-articular ridge. They 
 both extend very nearly to the cotylar surface of the bone. 
 
 The pterygoids articulate posteriorly by a deep, pit-like suture 
 with the inner side of the distal extremity of the quadrate; the latter 
 does not send out a process to meet the bone. The bar connecting 
 the quadrate with the body of the bone is oval in cross-section, with 
 a rounded inferior border. It is about thirty millimeters in length 
 and is placed obliquely; it does not extend much posteriorly to the 
 coronal plane of the occipital condyle. In front of this quadrate 
 process there is an elongate, flattened or concave plate, with nearly 
 parallel sides, separated from the parasphenoid by a slender, elon- 
 gated vacuity. * At the posterior extremity of this plate there is a nar- 
 row bridge connection with the basisphenoid. The connecting suture 
 is not determinable, so that one cannot say whether the two ptery- 
 goids meet here in the middle, as in Pcloneustcs and P/iosa/irits, or are 
 separated, as in Plcsiosaurus. In front of the interpterygoid vacuity 
 the pterygoids unite with the parasphenoid broadly; here also the 
 connecting suture cannot be determined. Opposite this connection 
 exteriorly, the bone sends out a stout process for union with the ecto- 
 pterygoid or transverse bone. Back of both of these, and on the inner 
 side, near the margin of the vacuities above, there is the attachment 
 of a stout epipterygoid pillar, passing upward, and apparently a little 
 inward to unite with the lower anterior part of the parietals, as 
 already described: both extremities are tumid, and the connecting 
 sutures cannot be determined. The rod is broken on both sides in 
 the specimen near the parietal end, and, as preserved, is curved for- 
 ward. It is oval in cross-section, with the greater diameter of about 
 ten millimeters; the entire length is thirty millimeters. Anteriorly, 
 the pterygoid sends a flattened process to meet the posterior extremity 
 of the vomers; it is flattened and pointed. This process is gently 
 expanded at each extremity, especially the proximal; it has a smooth, 
 thin edge on each side, except at the distal end, where it meets its 
 mate, suturally, in the middle. Between the two processes there is 
 an elongate, oval vacuity, which is not filled by the ossified para- 
 
 * Andrews calls this opening the posterior palatine vacuity or foramen; hut this term is more 
 properly restricted to the opening between the palatine, pterygoids and maxilla;, corresponding to 
 the posterior palatine foramina of mammals, and is thus used in the Chelonia— the sub- or infra- 
 orbital vacuity of Andrews and other authors. 
 
Apr. 1903. North American 1'i.esiosaurs — Williston. 
 
 23 
 
 sphenoid in this specimen. There is, however, a slight projection in 
 
 the middle of the opening behind, which may represent a more 
 extensive ossification, but it seems very probable that there was a 
 real vacuity here, unlike the condition in Pc/onct/stcs and Plesiasaurus. 
 The union with the vomer is oblique, from without inward and 
 forward. 
 
 The pcUatine and ectopterygoid on one side, though retaining 
 
 Fig. 1. Fig. 2. 
 
 Palate of PeUneustes. Palate of PUsiosavrus. 
 
 /'.v.. premaxilla; w.v., maxilla; v., vomer; m., internal nares; /<7., palatine; />/., pterygoid; 
 /i'., posterior palatine vacuity; cp., ectopterygoid; f>s.. basisphenoid; fio., basioccipital; (/..quad- 
 rate; .c</.. squamosal. After Andrews. 
 
 their original positions approximately, were free in the specimen ; 
 they are complete and show their sutural relations very well. On the 
 Other side, they are both in position. The palatine is a long, narrow, 
 thin bone, concave from side to side above, and correspondingly con- 
 vex below. The inner, slightly sinuous margin is thin, and overlaps 
 the outer margin of the palatine process of the pterygoid. Near its 
 anterior extremity there is a small emargination for the nares*, where 
 
 'See description of the palate in Brachaucheniut beyond. 
 
24 Field Columbian Museum — Geology, Vol. II. 
 
 tin' bone comes in contact with the proximal end of the vomer ; for a 
 little distance in front of this emargination, and distad to the pointed 
 extremity of the bone, the border is slightly thickened for union with 
 the vomer. Posteriorly, the rounded extremity of the bone is slightly 
 thickened, and with sutural roughening for union with the ectoptery- 
 goid process of the pterygoid. The outer border is slightly concave 
 throughout nearly its whole extent ; it is also thin for nearly its whole 
 extent. Anterior to the small narial emargination, the bone forms a 
 long, slender point. On the proximal end, the thin border is under- 
 lapped by the thin anterior prolongation of the ectopterygoid for a 
 distance of about fifty millimeters ; the remainder of the extent comes 
 in contact with the maxilla, but presents no distinct sutural surface, 
 unless it be near the anterior extremity. There is no posterior pala- 
 tine foramen. 
 
 The ectopterygoid or transverse bone is of a slender, triangular 
 shape. Its slender anterior end extends forward on the outer margin 
 of the palatine. *The posterior inner angle has a well marked sutural 
 surface underlapping the pterygoid process. The outer extremity is 
 thickened, curving somewhat downward to unite with the jugal, and, 
 by a thin border, with the maxilla. 
 
 The vomer is a very long, narrow bone, uniting with the palatine 
 process of the pterygoids posteriorly by a squamous suture, and, for 
 a short distance on the outer side posteriorly, with the slender 
 pointed extremity of the palatine, the small narial opening intervening. 
 They lie closely side by side, apparently without sutural union. 
 They are concave above, and convex below from side to side, and are 
 rather stout. The anterior ends are so concealed that they can not 
 be described or figured. 
 
 Brain-o'ase. — The lateral walls of the brain-case in the reptilian 
 skull are composed of six distinct elements, according to the views of 
 some comparative anatomists. Two of these may be fused with con- 
 tiguous elements in the adult skull, or one or more of them may be 
 entirely absent. Those elements supposed to contain the otic capsule 
 were called by Huxley, in his lectures on the structure of the verte- 
 brate skull (Elements of Comparative Anatomy, 1864), the epiotic, 
 prootic and opisthotic. The other three are the supraoccipital, 
 exoccipital and alisphenoid. The epiotic, Huxley homologized with 
 the so-called epiotic of fishes and batrachians, and, although indis- 
 tinguishably united with the supraoccipital in all adult reptilian 
 skulls*, he believed to be a distinct ossificatory element. This has 
 
 ♦Parker describes the epiotic as a distinct element in T>vf>i<ioitoti<s natrix. Phil. Trans.. 
 l^7V l>. 4°S- 
 
Apr. 1903. North American Plesiosaurs — YVilliston. 25 
 
 been denied by Baur*. No indications of such an ossification have 
 bet D found in adult reptiles, living or extinct, even in those in which 
 the opisthotic remains as a permanently free ossification. The opis- 
 thotic was previously called paroccipital by Owen in 1838, and the 
 name must take precedence. Copet, however, suspected that the 
 opisthotic or paroccipital is really composed of two elements, the 
 outer of which is the true paroccipital, while the inner, that entering 
 into the formation of the otic canals, may be properly called the opis- 
 thotic. Baur denies this, insisting that there is but a single element, 
 persistent in the Testudinata, Ichthyopterygia, the young of Sphenodon, 
 and other Rhynchocephalia, as well as in some of the Cotylosauria ; 
 firmly and indistinguishably fused with the exoccipital in all other 
 reptiles, so far as is known : free, according to Cope, also, as the 
 so-called squamosal of Baur, the paroccipital of Cope, the supratem- 
 poral of Woodward*, in the lacertilia. 
 
 If there be but' one element here, and, so far, the evidence is 
 inconclusive that there are two, then it must be called the paroccipital, 
 a name first given to it by Owen. Andrews describes the element as 
 distinct in the young of Crypt oclidns^i but there are no indications of 
 it in the present specimen. 
 
 The proStic of Huxley, the alisphenoid of Owen (Comparative 
 
 *Zool. Anzeiger, No, 298, 1889; Journ. Morphology, 1S89. p. 467. 
 
 t " The opisthotic in reptiles is general! 3 early fused with the exocciphal, but in the Ichthyop- 
 
 ter\yia ami Testudinata it is distinct, and takes the place of the petrosal as a support for the quadrate 
 in conjunction with the exoccipital. In the Pythonomorpha a hone which occupies the position of 
 the terminal part of the opisthotic (or paroccipital. which is the older namei issues from between 
 the exoccipital and petrosal, and sifpports the quadrate. Whether this is homologous with part or 
 all of the paroccipital is an open question. For the present 1 call it the paroccipital and it is 
 probably a distinct element from the opisthotic." Cope. Syllabus, 2d ed., 1898. A fuller description 
 of the relations of this hone the reader may find in my paper on the Mosasaurs il'niv. Kansas Geo), 
 Surv.. vol. iv. p. 121 1. After much reflection I believe that Cope is right in rejecting the term squa- 
 mosa! for this element, whatever it is. Parker describes and figures the opisthotic as a larire ele- 
 ment in the snake (1. C), Occupying its usuai and norma! position. At the same time it is exceed 
 ingly difficult to heiieve that the remarkable relations of the hone in the mosasaurs can he those of 
 tmosal, occupying almost the normal position of tile real opisthotic. That the bone called 
 squamosal in the lizards is not the squamosal would also seem probable, though not 
 impossible. 1 prefer to call the elements, until it he proven that there are two opisthotics 
 in the li/ard, the paroccipital and prosquamosal with Cope. It is of interest to note, however, that 
 Cope, in hi- last edition of the Syllabus 1 published posthumously), retains the name of squamosal 
 for the element he previously called the supratemporal 1 /'. r.. the prosquamosali. Further on he 
 defines the plesiosaurs as follow.-: " No supramastoid; paroccipital not distinct; a quadralo jttgal 
 arch: scapula triradiate; no clavicle: ribs one-headed." Cope's supramastoid is the hone he thought 
 erroneous! 3 to exist in the skull ol Cimoliasaurus snowii, that is the real squamosal if present, and 
 Andrews assures us that it is sometimes present in the young animal. 1 do not understand what is 
 meant by " no clavicle." unless it he that he accepted Hulke's determination of these elements as 
 the omosternum, a subject which will he discussed further on. He forgets also that some plesio 
 saurs do have rudimentary double-headed ribs in the cervical region, 
 
 Notwithstanding all that has been written, the homologies of the temporal bars in the reptilia 
 are set uncertain, more so than any other parts of the reptilian skull. 
 
 % Vertebrate Paleontology. 1898. 
 g Geological Magazine, 189;. p. 242. 
 
26 Fikld Columbian Museum — Geology, Vol. II. 
 
 Anatomy), is the petrosal of earlier authors, about which there is now 
 no discussion. It always articulates behind with the exoccipital and 
 paroccipital, above with the supraoccipital, below with the basi- 
 sphenoid, and to a greater or less extent with the parietal (in certain 
 lizards, etc.), the alisphenoids, when present, and epipterygoids. 
 The epipterygoid, the columella of earlier authors, unites the ptery- 
 goids with the parietals or frontals. It has been supposed to be 
 identical with the alisphenoids by Baur and others, but Baur* later 
 retracted this opinion, with reason, as may be seen by an inspection 
 of the cranial walls of Sphenodon. 
 
 The alisphenoids (orbitosphenoids of Owen) articulate with the 
 basisphenoid below, when present, and with the petrosals behind. 
 In the crocodilia and Sphenodon they also articulate with the epiptery- 
 goids. They seem to be absent in the plesiosaurs. 
 
 The bones of the brain capsule in our specimen of DolicJiorhyn- 
 chops had been separated by maceration before fossilization, and were 
 more or less displaced and entangled with one another. Moreover,, 
 in each temporal vacuity there had lodged deeply a thoracic vertebra, 
 wedged in and causing more or less distortion of the temporal arches. 
 The atlas and axis, also, were crowded into the occipital region. 
 The vertebrae had to be sacrificed in order not to endanger the other 
 bones. Mr. Martin, with great care and patience, removed the 
 disassociated bones of the capsule in more or less completeness. 
 They were all soft and mealy, almost of the consistency of brown 
 sugar when wetted, but by carefully infiltrating them with a solution 
 of gum arabic, the bones were hardened bit by bit and then removed 
 from the matrix. This exposed the surface of the basioccipital and 
 basisphenoid in their entirety, in an undisturbed and uninjured con- 
 dition. A gelatine mould of this surface was then made, from which 
 a plaster cast was taken, showing the sutural surfaces for the exoccip- 
 itals and petrosals. While none of the bones were obtained quite 
 complete, yet the mates, for the most part, mutually indicate the 
 complete characters of each, thus enabling a nearly complete restora- 
 tion of the capsule to be made. And the results have been well 
 worth all the trouble, as the bones present certain features of much 
 interest. 
 
 The brain cavity is broadly open in front, as in the lizardsf and 
 Sphenodon, with a broad base on the basisphenoid, a deep depression 
 
 *Zool. Anzeiger, No. 298, 1889. 
 
 tin the Pythonomorpha I have recently discovered that the brain-case is hounded in front in 
 part hy a well developed orhitosphenoid, uniting the frontal with the basisphenoid, The same bone 
 is present in the lizards and snakes. See Bulletin Kans. Univ., 1, No. 9, p. 14. 
 
Apr. 1903. North American Plesiosairs — Wii.liston. 
 
 27 
 
 for the pituitary, a narrow roof under the parietal, an open vacuity 
 posteriorly in the supraoccipitals, and with a relatively large otic 
 capsule. The exoccipitah unite obliquely with the basioccipital, tak- 
 ing no part in the formation of the condyle. The paroccipital pro- 
 cesses are small and slender, and there is no indication of a distinct 
 ossification. They are dilated slightly at the extremity, where they 
 abut against the upper part of the quadrate. They are directed down- 
 ward and outward, the distal extremity reaching a level below the 
 top of the occipital condyle. The occipital foramen is transversely 
 Oval, if the upper end is assumed to be near the top of the exocci- 
 pitals, which. show a slight angularity at the place of their union with 
 the separated supraoccipitals. At 
 tin upper posterior extremity of 
 each exoccipital there is a small, 
 deeply excavated, angular cavity, 
 excavated almost wholly from the 
 exoccipital, its upper border only 
 touching the posterior angle of the 
 supraoccipital. Its excavated sur- 
 face is smooth and sharply angu- 
 lar, looking upward and inward. 
 This surface probably corresponds 
 to the smooth tendinous surface 
 seen on the outer angle of the supra- 
 occipital, extending slightly on the 
 corresponding angle of the exocci- 
 pital, in the crocodile. At the 
 posterior part, the exoccipitals 
 approach each other rather closely. 
 
 leaving about four millimeters of basioccipital space in the circumfer- 
 ence of the foramen magnum. Anteriorly, however, the two bones 
 diverge rather widely, terminating a little posterior to the suture 
 separating the basioccipital from the basisphenoid. On the inner 
 side, back of the middle of the bone, and a third of the distance above 
 the sutural margin, is the large oval foramen for the vagus, opening 
 exteriorly below the middle of the moderately expanded paroccipital 
 process. The- smaller foramen for the hypoglossal is situated mid- 
 way between this and the posterior margin, and nearer to the sutural 
 surface ; it opens near the vagal orifice. The sutural surface for the 
 supraoccipital is flat and broadly triangular, pierced near its middle 
 by a small foramen leading into' the posterior semicircular canal in 
 the supraoccipital, the floor of which is seen on this surface, leading 
 
 Dolichorhynchops osborni. Occipital view of 
 skull, x l / } . l\i.. parietal; .»</.. squamosal; 1/.. 
 quadrate: so., supraoccipital; co.. exoccipital; 
 //.. pterygoid; <><'.. occipital condyle; /v.. basl 
 occipital. 
 
28 Field Columbian Museum — Geology, Vol, II. 
 
 as a narrow groove to the inner posterior margin of the surface. 
 Posteriorly the slit for the eighth nerve seems to be a little above 
 and back of the vagal opening, in the interstice between the exoccip- 
 ital and petrosal. The large cavity of this bone looks backward to 
 communicate broadly with a similar cavity in the petrosal on the inner 
 side. On the outer side there is a small foramen, nearly or quite 
 separated from the inner opening, also communicating with a small 
 foramen in the opposed sutural surface of the petrosal. Externally 
 the exoparoccipital shows a narrow fossa below the process, into 
 which open the vagal and hypoglossal foramina. Above, the gently 
 convex surface continues into the similar surface on the sides of the 
 snpraoccipitals. The posterior borders of the exoccipital and supra- 
 occipital meet in an obtuse angle, which is excavated, as already 
 v described for ligamentous attachment. 
 
 The snpraoccipitals are not only parial, but they are widely 
 separated from each other, approaching each other only at the upper 
 extremity posteriorly. They enclose between their smooth, narrow 
 edges posteriorly a large vacuity, continuing the foramen magnum 
 quite to the parietal roof. This relation of these bones I can not 
 find paralleled in any reptiles. Though paired in the Stegocephalia, 
 as also in Pariotic/u/s, they meet in a median suture. Whether this 
 peculiar structure obtains in all other plesiosaurs I can not say, 
 inasmuch as the only references to the supraoccipitals which I find 
 in the literature is a brief one by Andrews* concerning the bone in 
 the young of Cryptoclidus, in which nothing is said of a similar 
 structure, and a notice by Owent, who describes the supraoccipital 
 in Plcsiosaiirus dolicliodcints as a single, arched bone. 
 
 The inferior articular surface for union with the exoccipital is flat 
 and triangular in shape, looking downward or slightly backward. It 
 is pierced near its middle by the foramen for the superior semicircular 
 canal. The sutural surface for union w T ith the petrosal meets the 
 exoccipital at an angle of about one hundred degrees, and is flattened 
 or gently concave, and shorter than the other sutural surface. The 
 external surface is moderately convex, and a little roughened. The 
 posterior border is thin and smooth, deeply concave and sinuous, the 
 upper extremity curved inward. The inner surface is quite smooth, 
 gently convex from before backward, nearly straight to its upper 
 third, where it bends strongly inward. The posterior border is short, 
 thick, convex from side to side, and concave on its upper part before 
 joining the sutural surface. The sutural surface above, for union with 
 
 *Geol. Mag. 1895. p. 242. 
 
 t Fossil Rept. Liassic Formation, p. 8. 
 
Apr. 1903. North America** Pl esiosai rs — WillIston. 29 
 
 the parietal, is elongate oval in shape, slightly convex in both direc- 
 tions, and turned obliquely inward posteriorly, so that the two bones 
 when in place form a V. The surface looks forward and upward, and 
 joins a projecting sutural surface of like shape on the parietal bone. 
 
 Mandible. — From the exterior of the mandible four elements are 
 visible, arranged much as in the crocodile or Sphenodon. The dent- 
 hi \ extends far back along the upper border, quite to the top of the 
 coronary eminence. Thence its suture runs obliquely to a little 
 beyond the posterior end of the symphysis on the lower border. The 
 element back of this on the upper border is doubtless the surangular. 
 separated from the angular below by a suture placed very much as it 
 is in the crocodile, beginning at the extreme posterior end of the 
 mandible. The bone extends anteriorly as an elongated point between 
 the dentary above and the angular below. The suture separating the 
 element from the articular cannot be made out. The two, united, 
 agree quite with the element described by Guenther in Sphenodon, and 
 as seen in a specimen fifty-eight millimeters in length before me. 1 
 distinguish in this mandible, as did Guenther in his, only four elements 
 — the dentary, which reaches far back; the coronoid, a flat triangular 
 bone occupying its usual place; the articular, inclusive of the 
 surangular; and the angular. Baur* describes five elements in a 
 Sphenodon skull fifty-six millimeters in length. The articular he 
 restricts to a small nodule or disk oi bone, similar to that of the 
 turtles, forming the articular surface; the surangular, the bone 
 before the cotylus, which he indicates as separated by a suture; the 
 angular he considers to be the inner prolongation of the bone which 
 reaches to the coronoid. The slender bone usually called the angular 
 he believes to be the splenial; while the bone usually called the 
 splenial (presplenial, Baur) in the crocodile and lizard he believes to 
 be wanting in the Sphenodon, as it usually is in the turtles. The 
 small ossification which he finds in the cotylus of the young 
 Sphenodon, similar to the element in a like place in the Tesfudinata, he 
 assumes to be present in all reptilian mandibles, but is obliterated in 
 the adult skull by the anchylosis of the suture. I certainly do not 
 find such a bone in the Sphenodon mandible before me, nor could Guen- 
 ther distinguish such an element. He believes then, that the element 
 usually considered the articular, is in reality composed of two bones — 
 a chondrogenous articular part and a dermogenous anterior prolonga- 
 tion. This is probably true, but I do not see the necessity of chang- 
 ing the names of the other anterior elements and of calling this 
 
 * American Naturalist, 1891. 
 
30 Field Columbian Museum — Geology, Vol. II. 
 
 anterior prolongation the angular, as does Baur. From the fact 
 that the bone on the inner side of the dentary, covering Meckel's 
 groove, is the only one which can with propriety be called "splenial" 
 (a " bandage " or "patch "), or opercular (a cover), it will be better to 
 retain the former name for the element, as usually applied, and to 
 give a new name to the part separated from the articular, wherever 
 it exists as an independent bone; it may be called the prearticnlar. 
 
 AAi JAAAJlAJJM 
 
 Fig. 4. 
 
 Riylit mandible of Clidastes tor/or Cope. D.. dentary; s/>., splenial,- pra.. prearticnlar; <mg. x 
 angular: air., coronary; art., articular; sin., surangular. 
 
 I assume that the element containing the cotylus must be the 
 articular, and that the one in front of it, back of the coronoid and 
 dentary, must be the surangular, though, as already stated, I can find 
 no positive evidence of a separating suture in the present specimen, 
 as is also the case in the adult Sphenodon mandible. Doubtless in 
 some more fortunately preserved specimen, or in one of a younger 
 animal, the separating suture will be traced. I will add that the 
 suture indicated by Cope* in his figure of the skull of Cimoliasaurus 
 snowii, as separating the articular from the surangular, does not exist 
 in the specimen; the place is indicated by a mere groove only. 
 
 The angular is very long, and is extensively visible from both 
 within and without. On the outer side it is seen reaching to a little 
 beyond the proximal end of the symphysis, where the pointed extrem- 
 ity is visibly intercalated between the dentary and a small portion of 
 the splenial. On the inner side, the suture follows inward below the 
 cotylus to the anterior inner angle of the articulation, near which it 
 passes upward to meet the prearticnlar. The bone passes beneath 
 this latter.t'ltment but its connection with the surangular cannot be 
 made out. Along the inferior border of Meckel's groove and the 
 splenial, the suture goes forward to near the proximal end of the 
 symphysis. 
 
 On the inner side of the mandible, there is an extraordinary 
 arrangement of the bones. After much deliberation, I interpret them 
 
 *Proc. Ani.-r. Phil. Soc. 1894. 
 
Apr. 1903. North American Plesiosavrs — Williston. 
 
 3i 
 
 as the splenial (presplenial of Baur), the prearticular (angular of 
 Baur), and the coronoid. The identity of the splenial is assured. It 
 has been dislodged upward slightly, disclosing the narrow Meckelian 
 groove, which terminates in an orifice at the proximal end of the 
 splenial. The bone ends posteriorly below the coronoid eminence. 
 Anteriorly it broadens so as to cover all but the upper inner part of 
 this surface, uniting with its mate to form the symphysis. From 
 
 AA&A LA-JLJU^ h 
 
 Fig. 5. 
 
 Left mandible to symphysis of Doliehorhynehops osbomi. ar/., articular; /m., prearticular; 
 
 <!ir.. surangular; cor., coronary; sf., splenial. Compare also Fl. II. 
 
 below, the thickened bone forms the inner part of the symphysis for a 
 short distance forward, at least. How far it extends can not be deter- 
 mined, as it gradually becomes thinner and disappears from view. 
 
 PI. II.) 
 
 The bone which I determine as the coronoid .is most peculiar, 
 remarkably unlike that in any other animal which I know. It is a 
 long, slender, flattened, trihedral bone, extending far forward, and 
 like the splenial, meeting its mate in the median symphysis. It 
 extends as far back as the end of the dentary, along its inner side, to 
 tin- most elevated part of the surangular, where it is thin and spatu- 
 late. It follows the inner margin of the dental border of the dentary, 
 apparently at least as far as the middle of the symphysis. At the 
 beginning of the symphysis with its mate, the bone is somewhat tri- 
 angular in cross-section, with its thin margin below touching the 
 splenial; the mesial surface is in contact with that of its mate, while 
 the upper surface is narrow. On one side the bone, while still retain- 
 ing its proper relation with that of the opposite side, has been par- 
 tially dislocated from the mandible, so that there can be no question 
 of its morphological relations to the contiguous elements.* 
 
 Between the splenial and the coronoid, on the inner side, is 
 seen a narrow, thin bone, corresponding epiite to the dermogenous 
 portion of the articular in the turtles and Rhynchocephalians, that is, 
 
 ♦This peculiar relation' of the coronoid is well illustrated in fie. 13, P-476. vol. xxxvii, of the 
 Quarterly Journal of the Geological Society, in Prof. Sollas' article on "A New Species it 
 
 1 mrus from the Lower Lias of Charmoiitli." 
 
32 Field Columbian Museum — Geology, Vol. II. 
 
 the angular of Baur. It lies above the splenial, disappearing beneath 
 the' coronoid anteriorly. Posteriorly it is joined by a suture with the 
 articular, approaching but not quite entering into the cotylar surface, 
 or if so, only to a slight extent. This end has been dislodged slightly 
 from its normal position and is slightly twisted upward. It is 
 scarcely possible that this is due to fracture, since the surface has all 
 the indications of a suture, and a fracture could hardly have occurred 
 here without injury to the bone underneath. The end is slightly 
 'thickened and fits into a pit on the anterior upper part of the articu- 
 lar rim; just below the suture, separating it from the articular, there 
 is a longitudinal ridge-like roughening, and a narrow, deep pit. This 
 element I call the prearticular. 
 
 For the sake of comparison, I have figured in PI. V the mandi- 
 ble oiSphcnodon, Crocodiltts, Clwlyd/a, Vara/uts, with the interpretation 
 of the elements as here accepted. 
 
 The bones of the skull, as of the entire skeleton, seem to have 
 had a sort of postmortem plasticity. Apparently during life the 
 sutures everywhere were free, and the parts all readily separable, and 
 wherever the bones have been disturbed or distorted the sutures have 
 pulled apart and widened. Where there has not been such disturb- 
 ance, however, the sutures are often obliterated, the elements fusing 
 together. This would seem to indicate youth, but plasticity in the 
 Cretaceous skeletons was largely due to the composition of the bones, 
 which may have been more or less persistent throughout life. Those 
 in which the inorganic proportions were large have suffered less from 
 postmortem disturbances than those in which the organic material was 
 considerable. Bird bones were never plastic, and very rarely are the 
 bones crushed, the cavities being filled with crystalline material often. 
 Of the pterodactyls, however, the bones are invariably found crushed, 
 though presenting little evidence of plasticity. Among the mosasaurs, 
 the mare firmly ossified bones of Clidastes are less often changed in 
 shape, while the Tylosaurs, on the other hand, were more or less 
 subjected to a plastic distortion. The structure of the plesiosaur 
 bones in all that I have seen is unusually soft. 
 
 Vertebr/e. — Atlas and axis. (PI. XXII.) The atlas has the 
 usual number of elements, the intercentrum and the two side pieces, 
 or neurapophyses. It will be convenient, however, to describe in 
 this connection the parts of the whole axial and atlantal complex, that 
 is, in addition to the odontoid, the axial intercentrum and the axial 
 centrum and arch. The arrangement of all these parts is very like 
 that in the lizards, crocodiles and various other reptiles, save that the 
 
Apr. 1903. North American Plesiosaurs — Willistom. 33 
 
 structure is somewhat more primitive- or generalized. The atlantal 
 intercentrum is the largest element of the complex, save the axial 
 centrum. It has five articular surfaces for union with as mmy bones ; 
 four of these surfaces are sutural, and, doubtless in old animals or in 
 other species, the sutures maybe obliterated. The inferior or ventral 
 surface has an obtuse ridge along the middle, on either side of which 
 the surface is flattened cr a trifle convex. This surface is free, and 
 its anterior and posterior margins are parallel. The anterior or 
 cephalic surface is concave for articulation with the hemispherical 
 occipital condyle, its rim forming more than one-third of the entire 
 circumference of the cup. The posterior surface is flat, elongated 
 triangular in shape, with a V-shaped emargination, for articulation 
 with the axial intercentrum. Dorsally the bone articulates by a 
 broad sutural surface with the odontoid, except on the cephalic part 
 of each lateral margin, which unites by a small, semi-oval surface with 
 the neurapophysis. 
 
 The axial intercentrum is not unlike the atlantal in shape, when 
 seen from the ventral side, though smaller. Its ventral surface con- 
 tinues the obtuse ridge of that intercentrum, but it is here quite 
 prominent, the nearly square free surface on either side being dis- 
 tinctly concave. The posterior surface for sutural union with the 
 body of the axis is flat or gently concave ; its free margin is broadly 
 V-shaped, with the inferior angle rounded : the dorsal margin is 
 gently concave in the middle to the truncated, very broad arms of the 
 V. The cephalic sutural surface is flat, for union with the atlantal 
 intercentrum, and like that of this bone, its surface is broadly tri- 
 angular in shape. On either side the bone articulates, through the 
 greater part of its extent, by an oblique, concave surface with the 
 axial rib, forming part of the pit for the reception of that bone. Its 
 upper lateral part unites by a small surface with the odontoid, form- 
 ing with it and with the axis the complete margin of the rib-pit. 
 Dorsally the bone articulates on its caudal half with the axis : on its 
 cephalic half with the odontoid. 
 
 The odontoid, or atlantal centrum, unites posteriorly by a broad, 
 flattened, sutural surface with the body of the axis. On the cephalic 
 side there is a concave surface in the middle, occupying about one- 
 half of the diameter for articulation with the condyle, the deep cup 
 being completed ventrally by the atlantal intercentrum and on the 
 sides by the neurapophyses. Dorsally the neurapophyses leave a 
 small notch of the rim incomplete, which is partly filled out by the 
 odontoid, making the diameter of the cupped surface of this bone 
 greater dorso-ventrally than from side to side. The sides of the bone 
 
34 Field Columbian Museum — Geology, Vol. II. 
 
 have a free, irregularly trapezoidal surface, the longer, cephalic bor- 
 der articulating with the atlantal neurapophysis, the caudal, oblique 
 border with the axial intercentrum, the ventrocaudal angle with the 
 axial intercentrum, and the ventral part of the caudal border with the 
 axial rib, its dorsal angle touching the axial neurapophysis. The 
 ventral side of the body unites suturally with the intercentra. On the 
 dorsal surface there is a narrow, free space, which helps form the 
 floor of the neural canal. 
 
 The lateral pieces or neurapophyses are composed of a large body 
 for sutural union with the other elements, and a small, laminar, 
 dorsal projection, which is free. The body is irregularly five-sided, 
 the external free surface convex dorso-ventrally. The cephalic sur- 
 face is smooth and concave, forming the lateral rim of the condylar 
 cavity. Ventrally a small articular surface is for union with the 
 condylar rim of the atlantal intercentrum; the border nearly parallel 
 with the upper. Caudad, there is a small articular surface for union 
 with the arch of the axis; the long border between these two joins the 
 lateral surface of the odontoid; the dorsal surface sends a flat pro- 
 jection backward to touch, or nearly touch the small, vestigial 
 prezygapophysis of the axis; this lamina is continued into a small, flat 
 process, the vestige of the neural lamina. These neurapophyses are 
 peculiar in articulating at their base for a short distance with the 
 neurapophyses of the axis, doubtlessly corresponding to the articular 
 surfaces between the body of the axis and the lateral masses of the 
 atlas in the mammalian vertebrae. It is very plainly evident, there- 
 fore, that the name zygapophysis, when applied to this articulation in 
 the mammalian axis and atlas is incorrect— the real zygapophyses are 
 completely lost. 
 
 The atlas, as a whole, is of a primitive and generalized character, 
 in that the neurapophyses are, for the most part, borne by their own 
 centrum, and the atlantal arch only in small part by the atlantal 
 intercentrum. 
 
 The axis has its anterior surface flattened for sutural union with 
 the odontoid. On the cephalic ventral part is received the axial 
 intercentrum, the lines of the union reaching midway of the body on 
 the ventral side. The pit for the reception of the rib is very large and 
 deep, and is formed in part by the odontoid and intercentrum. The 
 pedicles of the arch are stouter and broader than in the following 
 vertebrae, articulating in front with the lateral pieces of the atlas, 
 and, to a slight extent, with the odontoid. The prezygapophyses 
 are represented by a small tubercle, approximated to the flattened 
 posterior process of the lateral atlantal pieces. Back of this there is 
 
Apr. 1903. North American Pi.esiosaurs — Willistok. 35 
 
 a thickened, rugose, horizontal ridge, reaching to the intervertebral 
 notch. The posterior zygapophyses are situated rather high, and do 
 not differ materially from the same processes in the following verte- 
 brae. The spine is incomplete posteriorly, but seems to have been 
 short, stout and much inclined. 
 
 The structure of the plesiosaurian atlas and axis has be( n 
 described by Owen,* Huxleyt and Barratt.^ In the specimen of a 
 Plesiosaurus described by Barratt the different elements were sep- 
 arati d and were for the most part complete. The neurapophyses 
 difiet markedly in their expansion inward to form a roof for the neural 
 canal, though they do not touch each other. Theatlantal intercen- 
 trum also differs in its posterior projection into "two long processes," 
 which are, however, broken away, leaving only their bases. The 
 axial rib seems to articulate with the axis and axial intercentrum 
 only. In Plesiosaurus etkeridgii, the atlas and axis of which are 
 described by Huxley, the bases of the atlantal neurapophyses are 
 much larger and meet above the odontoid. In Plesiosaurus pachyomus , 
 as described by Owen, " the anchylosed bases of the neurapophyses 
 form the upper border of the cup," and the atlantal intercentrum 
 "develops a thick but short rough tuberosity from its under part," 
 and the rib projects from the centrum of the axis only. The pro- 
 cesses were all broken away. 
 
 It is seen that the structure in Dolichorhynchops is more special- 
 ized than in these species of Plesiosaurus. 
 
 The atlantal and axial intercentra, variously considered by differ- 
 ent authors as " subvertebral wedge-bones," hypapophyses or hypo- 
 centra, are correctly homologized by Baur, § Albrecht|| and Osborn.^[ 
 It is a little interesting to note, however, that Owen (1. c.) long ago 
 gave a correct hint of their homology: "According to the latter view, 
 what has usually been regarded as the centrum or body of the atlas 
 in Saurians, Chelonians and the higher Vertebrate, would be the 
 haemapophyses of that vertebra; and the odontoid process the true 
 centrum. " He concludes, however, that these elements are "detached 
 cortical parts of the real centrum;" though later he correctly compares 
 them with the hypocentra of the labyrinthodonts. 
 
 Perhaps the most primitive and unchanged condition of these ele- 
 
 * Ann. Man. Nat. Hist. xx. 217, 1850. 
 t Geological Journal, rf 
 
 }.\nn. Man. Nat. Hist. Nov. iS;S. . 
 
 5 American Naturalist. 1887. Sept., p. 830, 
 
 ii Bull. Mus. Roy. d'hist. Nat. de Belg. ii. 185. 
 
 • Mem. Amer. Mas. Nat. Hist. i. p. 1S7. 
 
36 Field Columrian Museum — Geology, Vol. II. 
 
 ments in the reptilia is found in Ichthyosaurus, in which, as shown 
 in the figures given of the axis and atlas by Owen, the intercentra 
 of the first three vertebrae occupy nearly their normal and unaltered 
 relations to the vertebrae. It is difficult to understand, however, how 
 such a primitive condition of these parts could have been inherited 
 from a terrestrial ancestor. In the plesiosaurs the specialization has 
 been carried further, still the structure is yet more primitive than is 
 known in any modern reptiles and in most of the extinct. We cerx 
 tainly can look for ancestral forms of these vertebrae among the 
 Stegocephalia or Anomodonts only; in all other reptilia they 
 have acquired too great specialization to easily revert to the gen- 
 eralized structure. 
 
 In the modern crocodiles the specialization has been carried so 
 far that the axial rib has become supported by the atlantal centrum 
 only, while the atlantal rib has been pushed forward on the atlantal 
 intercentrum. 
 
 It is of interest to observe that in Shastosaun/s of the earlier Ich- 
 thyopterygia, according to Merriam, there were probably five inter- 
 centra present in the anterior cervical region, while in Ichthyosaurus 
 there are but three, and in the more specialized forms, Baptanodon* 
 they have entirely disappeared. 
 
 Beyond the axis there are seventeen distinctly cervical 7'crtchnc 
 preserved, together with one or two transitional ones, which must be 
 classed with the dorsals, however. I believe that these were all that 
 the animal possessed, though it is possible there may have been one 
 or two more. The arches and ribs of all, save of the third, were 
 detached and scattered about among the other bones, so that much 
 difficulty was encountered in properly associating the parts. Because 
 of a gradual increase in size of the ribs and arches, as well as the 
 centra, it would seem that the final collocation made is correct, and 
 because all these processes agree in number it would seem still more 
 probable that no vertebrae are missing. (See Pis. VI-IX.) 
 
 The centra increase in height and width gradually throughout the 
 series. The third has a transverse diameter of thirty-five millimeters, 
 a height of thirty and length of twenty-eight. The sixteenth centrum 
 has its corresponding diameters as follows: forty-five, thirty-eight and 
 twenty-six. The three following are somewhat distorted, but seem 
 likewise to increase slightly in height and width. It will be observed 
 that the length is nearly or quite the same in all, the differences being 
 exhibited in the width and height only. The articular surfaces of the 
 centra are gently and evenly concave, with a slight rounded eminence 
 
 *W. C. Knight, in Hit. 
 
Apr. 1903. North American Plesiosaurs — Williston. 37 
 
 in the middle of the concavity, sometimes apparently obsolete. The 
 margins are rounded, the cartilaginous borders limited exteriorly by 
 a slender, smooth line. On the ventral surface, near the middle 
 antero-posteriorly, there are two vascular foramina, at the bottom of 
 a slight depression, and separated from each other by a rounded 
 ridge. Posteriorly the distance between these foramina becomes 
 greater. The pit for the articulation of the cervical rib occupies 
 nearly the whole length of the centrum, between the cartilaginous 
 margins, and reaches also nearly to the plane of the neural sur- 
 face. The ribs increase in length and width from the axis to the 
 beginning of the thorax. They are single headed, flattened, with the 
 free extremity moderately dilated and thinned, except those of the 
 axis, which are more styliform, and are directed more obliquely back- 
 ward. On the following vertebrae they are directed outward and 
 backward, with the distal extremity rounded, except in those of the 
 anterior vertebras, where the anterior part distally is slightly angu- 
 lated, as though suggesting a rudimentary anterior projection. The 
 spines slope gently backward. They increase but little in length, 
 that of the third vertebra measuring forty-eight millimeters in length 
 while that of the last is but fifty-five above the zygapophyses. They 
 increase in stoutness, however, much more than in length, the ante- 
 rior ones being slender, the posterior broad and thick with a some- 
 what expanded cartilaginous extremity. The zygapophyses are 
 broadly separated throughout, with an obliquity of about thirty 
 degrees from the dorsoventral plane. They are broadly oval in out- 
 line, of large size and nearly flat. They project strongly from the 
 body of the vertebra, leaving a space of about ten millimeters in 
 extent between the centra, when in close articulation, for the inter- 
 vening cartilage. The diameter of the spinal canal throughout the 
 series is about fifteen millimeters. Upon the floor of the canal there- 
 are two venous foramina, near the middle. 
 
 Thirty dorsal vertebrae were found in the matrix. The arches 
 invariably separated from the centra, and, because of the general 
 resemblance of the latter it is impossible to say whether all have been 
 correctly associated. The centra were in large part crushed or com- 
 pressed, and in some cases were so soft that it was found impossible 
 to remove them entire. Two of the arches were wedged into the 
 temporal fossae of the skull in such a way that it was found necessary 
 to largely destroy them in cleaning the skull. In general, the spines 
 of the dorsal region were so soft and frail, intermingled as they were, 
 that they could not be removed. A large part of them, hence, have 
 been modeled in the restored skeleton. Because, however, of not a 
 
38 Field Columbian Museum — Geology, Vol. II. 
 
 few arches that were recovered complete, or nearly so, from different 
 parts of the series, the restoration of the intervening parts of the 
 series has presented few difficulties. 
 
 The spines decrease very slightly in height, in breadth and in 
 thickness. Anteriorly they are directed somewhat backward, but 
 soon become quite vertical in position. In the posterior cervical and 
 anterior dorsal region the spines present a much larger, oval and 
 truncate extremity for ligament or cartilage; this surface measures 
 from twelve to fifteen millimeters in width in some of the posterior 
 cervicals. In the posterior dorsals the extremity is narrow— three or 
 four millimeters in width. The first diapophysis* is small, for the 
 attachment of a small, short rib, and is situated low down on the 
 pedicle, t close to the sutural surface. The next is much stouter and 
 longer, for the attachment of a long and strong rib. The next two or 
 three ascend progressively on the pedicle, until in the fifth the upper 
 margin of the root is above the plane of the anterior zygapophyses. 
 They retain this position throughout the series, the last two or three, 
 only, descending toward the centrum. The diapophyses have ac- 
 quired their greatest length by the sixth or seventh, and are directed 
 upward and outward. In the articulated skeleton there is a deep 
 costo-spinal groove on either side. The zygapophyses are largest 
 and stoutest in the posterior cervical region, decreasing gradually in 
 size, and becoming obsolete at the base of the tail. Throughout the 
 dorsal region they are but slightly cupped, and are directed dorsad 
 and ventrad, at only a slight angle from the median plane. There 
 are no indications whatever in any region of a zygosphene. The 
 centra throughout this region were more or less crushed in the 
 specimen, but seem to be very uniform in character. Their size is 
 but very little different from that of the posterior cervicals, their 
 length no greater; the venous foramina on the ventral side become 
 gradually more remote from each other. 
 
 Some of the dorsal ribs were so badly decomposed that they could 
 not be recovered from the matrix; others were so intermingled with 
 other bones that they could not be removed entire. The larger part, 
 however, have been recovered and restored nearly to their living 
 condition. The anterior long ribs are flattened, with an expanded 
 head, only moderately curved and with the distal extremity only a 
 little attenuated, the cartilaginous continuation evidently of some 
 
 *Baur (Anatom. Anzeiger ix. No. 4, 1893, p. 120) would restrict this term to the process bearing 
 the head of the rib in the Stapedifera. 
 
 tSeeley has proposed to call these vertebra; in which the rib is ascending from the centrum, 
 pectorals. 
 
Apr. 1903. North American Plesiosaurs — Williston. 39 
 
 length. The posterior ribs are short, less flattened, with a less 
 expanded head and with a pointed distal extremity. From the 
 position of the diapophyses anteriorly, it is quite evident that the ribs 
 were directed much more outwardly than downwardly. In the 
 restored skeleton, the transition from the long to the short ribs has 
 been made gradual, and two or three on each side have been 
 modeled here. (See PI. XI.) 
 
 About fifteen ventral ribs were preserved; others have undoubtedly 
 been lost. Only one is symmetrical; it is about thirty centimeters in 
 length and is thickest near its middle, tapering to a point on each 
 side, and has a moderate curvature. The others preserved measure 
 from twelve to sixteen centimeters, and have a thickness near their 
 middle of about ten millimeters. They are gently curved, irregularly 
 prismoidal in section, and taper to a point at each extremity. Because 
 of their number and the scattered positions in which they were found, 
 it has not been possible to arrange them in the mounted skeleton with 
 any degree of precision. In the known European specimens they 
 form a double series of three, with a larger symmetrical median one. 
 Abdominal ribs are known only in th.e crocodilia, rhyncocephalia 
 pterosaurs, ichthyosaurs, dinosaurs and plesiosaurs. 
 
 The caudal vertebrae were found at some little distance from the 
 remainder of the skeleton, and for the most part had been collected 
 separately by Mr. Sternberg. The processes, as elsewhere in the 
 column, had been separated, and were, many of them, found variously 
 intermixed with the other bones. Both the centra and the proo 
 however, were in excellent condition, as were those of the neck, in 
 marked contrast to the dorsal vertebras. The last twelve taper so 
 uniformly that it is quite certain they all belonged together, and that 
 no intervening ones were missing. This series has a diameter of 
 forty millimeters at the beginning and only twelve at the extremity, 
 with lengths respectively of twenty-five and twelve millimeters. The 
 greatest decrease in size occurs in the last five or six of the series. 
 These distal five or six have the shortening much more pronounced 
 on the dorsal than on the ventral side, indicating a well-marked 
 upward curvature of the extremity of the tail. Because of the rapid 
 change in the characters of these vertebrae there has been no difficulty 
 of associating the processes with their respective vertebrae. The 
 spines in the early ones of the series slope at a moderate angle back- 
 ward, the obliquity being greatest in the twelfth from the end. In 
 the last six, the spines are much shorter and stand nearly vertically, 
 or even with an anterior slope. The diameter of the last centrum 
 preserved indicates the presence of two, or perhaps three smaller 
 
40 Field Columbian Museum — Geology, Vol. II. 
 
 ones forming the extreme tip of the tail; these must have been mere 
 nodules of bone, without processes. (See PI. X.) 
 
 Several other vertebrae are assigned to the caudal series, chiefly 
 on the evidence of the venous foramina on the ventral side of the 
 centra, though they have no facets for the chevrons. Between these 
 and the continuous series, four vertebras have been intercalated; the 
 number may be too great; possibly not enough. That some were 
 missing is quite certain, since the change in the direction of the spine 
 is too abrupt in the ones preserved. Because the tail as restored 
 seems to be of about the length of some other known forms, I am 
 inclined to believe that the number of the caudal vertebrae, all told, 
 did not exceed twenty-five. All those preserved, except the anterior 
 ones, show a nearly circular and somewhat cupped surface on each 
 side for the attachment of the haemapophyses. The separate branches 
 are directed downward, outward and backward. They are somewhat 
 flattened and expanded distally, except the distal ones, which are 
 more rod-like. The diapophyses or ribs of the connected series 
 spring from near the middle of the centra dorso-ventrally, and are 
 directed outward horizontally, the most posterior ones also slightly 
 forward. They have a somewhat expanded extremity, with a cartilag- 
 inous margin. At the beginning of the series they arise near the 
 middle of the centra antero-posteriorly, but gradually approach the 
 anterior margin. They terminate as free ribs on the seventh before 
 the end, that is on the ninth or tenth before the extreme tip of the 
 the tail. The sixth has a small exogenous tubercle to represent the 
 process. None of the caudal vertebrae, save at the immediate base, 
 have functional zygapophyses, and the tail was evidently capable of 
 considerable lateral and vertical movements. There are no indications 
 whatever of a terminal fin, unless the upward curvature of the tip of 
 the tail suggests such an appendage. Its use, however, could not 
 have been great, since the evident shortness of the tail, and its inter- 
 ference with the hind limbs would have deprived it of much service 
 as a propelling organ. 
 
 Pectoral Girdle. — The scapula is of the usual triradiate shape. 
 The coracoid or glenoid ramus is short and rather stout, some- 
 what expanded at the extremity, with the two articular facets 
 meeting in an obtuse angle, the larger, oval one for the glenoid 
 articulation ; the smaller, triangular one for union with the cora- 
 coid. The 'dorsal ramus is narrowest, is rather stout, thickened 
 on the posterior and thinned on the anterior border ; it termi- 
 nates in a flattened surface for attachment of a suprascapu- 
 
Apf. 1903. North American Plesiosairs — Willis ion. 
 
 4i 
 
 lar cartilage. The ventral or clavicular (proscapular) extremity 
 is broad and thin and deeply concave on its visceral surface. 
 Its inner border is rounded for the most part and thin, except 
 
 Fig. 6. 
 
 Fart of right scapula of Plesiosaurus wudgei Cragin, external (.left and internal (right) views. 
 
 on the anterior part, where it is moderately thickened, as though for 
 cartilage. The posterior and inner border is quite thin throughout 
 and evenly concave, forming the outer anterior border of the scapulo- 
 coracoidal foramen. The anterior border is sinuous and thinned, 
 having a knife-like edge throughout its whole extent. The exterior 
 border, between the glenoid and suprascapular extremities, is deeply 
 concave, with the mar- 
 gin thickened and 
 convex. The ventral 
 surface of the bones 
 tonus two nearly flat 
 planes, meeting in a 
 straight. prominent 
 ridge, which extends 
 from the ventral side 
 of the anterior border 
 of the glenoid surface 
 to the anterior angle 
 of the ventral ramus. 
 
 The two surfaces meet ., . ,',',„ . 
 
 Ventral extremity ol scapula of PUstosaurus gulo Cope (type 
 
 in a very obtuse specimen), one-half natural size. 
 
 angle. The visceral 
 
 surface is, for the most part, concave. On the ventral ramus this 
 
 concavity is marked, receiving the clavicle on its anterior part. 
 
 There is a sutural roughening continued along the anterior border 
 
42 Field Columbian Museum — Geology, Vol. II. 
 
 to the base of the dorsal ramus, throughout the whole extent of the 
 concave portion of the border. The bone differs from the scapula 
 of Muranosaurus* in the less expanded ventral ramus, which is sepa- 
 rated from its mate by the clavicle and episternum. From the Crypto- 
 clidus\ scapula it differs in having a more slender and elongate dorsal 
 ramus, and in the non-expansion of the ventral ramus. From a 
 scapula of PL mudgei Crag, from the Lower Cretaceous in the 
 University of Kansas Museum, it differs in its much less slender 
 coracoidal and dorsal rami. The bone is also much more slender 
 than in Peloneustet. (See PI. XII.) 
 
 The coracoid is a very large and broad plate, with a slender, 
 blade-like epicoracoid projection. Its glenoid portion is massive, 
 with a smaller humeral articular surface, and a larger scapular facet, 
 meeting each other in a very obtuse angle. The external border is 
 thickened and concave, produced into a considerable projection at 
 the posterior angle. Just before its termination there are several 
 tooth-like projections of small size, evidently for muscular attach- 
 ment. The posterior margin is thin, with rounded angles and a slight 
 concavity between them. Opposite the glenoid articulation the bone 
 is massive, meeting its fellow in a thickened bar with an oblique 
 sutural surface. Immediately posterior to this interglenoid thicken- 
 ing, the bone on the mesial side is very thin, and in the anterior part 
 of this thinned portion, near the middle line, there are two large, 
 well-defined, round foramina that have never before been described 
 in the coracoid, though perhaps indicated in the description of Trin- 
 acrotnerum. The clavicular or epicoracoid process in front is long 
 and thin, with nearly parallel sides, the anterior end slightly expanded 
 and its margin with a cartilaginous border. The sutural surface for 
 the clavicle extends back on the upper surface to nearly midway of 
 the process. The coraco-scapular foramen is elongate in shape and 
 is bounded entirely by the two bones, save for a short distance at the 
 front inner part where the clavicle completes the margin. The cora- 
 coid has the posterior outer angle more produced than in- either 
 Crxptoclidus, Peloneustes or Muranosaurus, and the clavicular process 
 is longer and better developed than has been described in any form, 
 except perhaps in Trinacromerum. 
 
 The clavicle is a thin, concave, irregularly triangular or triradi- 
 ate bone, and is well developed. It lies upon the ventral plate of the 
 scapula and the epicoracoid process of the coracoid, and above the 
 squamous margin of the episternum, a remarkable position for a 
 
 ♦Andrews, Ann. M;ii;. Nat. His. xv, 43c. 
 t Andrews, Ann. Mag. Nat. Hist, xv, 35$. 
 
Apr. 1903. North American Plesiosaurs — Williston. 43 
 
 membrane bone to attain on the visceral side of all three cartilage 
 hones. The anterior border is gently thickened, somewhat sinuous 
 in outline, and is free for a part of its extent. The other borders are 
 
 Fig. 8. 
 
 Diagram <>( pectoral girdle of Dolichorkynchops osborni^ from above; the outlines of con- 
 cealed parts are indicated by dotted lines. lc, episternum (interclavicle); cl., clavicle; sc. % scap' 
 
 ula; <().. coracoid. 
 
 thin, for the most part squamous, and nowhere free, save for a short 
 distance at the anterior end of the coraco-scapular foramen, and the 
 posterior part of the interclavicular foramen. The two bones meet 
 
44 
 
 Field Columbian Museum — Geology, Vol. II. 
 
 in a median symphysis for a short distance back of this interclavic- 
 ular foramen. The under or convex surface appears only for a small 
 space between the ends of the scapulae, epicoracoid processes and the 
 episternum. Its outer extremity extends into a slender process, 
 broken away in the specimen figured, which reaches along the front 
 margin of the ventral ramus of the scapula to the base of the dorsal 
 ramus. (See PI. XIII.) 
 
 The clavicle seems to be the most variable bone in the skeleton ; 
 I know of no form in which it is better developed. In Cryftoclidus it is 
 a small, triangular bone, meeting its mate in the middle line, according 
 to Andrews, the episternum being absent. In Plesiosaurus mudgei 
 Cragin (see PI. XXVII), the clavicle appears to have been smaller 
 and more triangular than in the present species. It is generally 
 assumed that this bone is the real clavicle by Seeley, Andrews, Fiir- 
 bringer and others, and one may, with Andrews, explain its position 
 in relation to the ventral ramus of the scapula by the peculiar method 
 of ossification of that bone. But, can its visceral relations to the 
 coracoid and episternum be explained as easily? It is true that many 
 
 authors call the median, un- 
 paired piece the interclavi- 
 cle, a membrane bone, and, 
 if this origin is accepted, its 
 position in relation to the 
 clavicle is not remarkable. 
 But I am inclined, with Geg- 
 enbaur and Furbringer, to 
 believe that this central piece 
 is really the episternum. a 
 cartilage bone. Andrews 
 described the clavicle in some* 
 forms as showing a sutural 
 tendency with the scapula, 
 and in some forms, as Elas- 
 i)i o$a urns, it seems to become 
 entirely fused with that bone, 
 or if not, has disappeared 
 entirely. 
 
 The episternum (inter- 
 clavicle) is a small, symmet- 
 rical bone deeply emargi- 
 nate in front and behind. The thin squamous margin on each 
 side underlaps the clavicle. These squamous borders seem to have 
 
 Fig. 9. 
 Episternum of Trinacromerum ainmymum Will. 
 one-half natural size. 
 
Apr. 1903. North America** Plrsiosaurs — Williston. 
 
 45 
 
 been covered with cartilage below, leaving a free, convex, ventral 
 surface, elongate oval in shape, including the emarginations, limited 
 by a distinct ridge or angle. The striation of this thinned margin 
 points to a covering of cartilage. The anterior emargination of the 
 bone is narrow and deep, while the posterior one is broader and « \ > n 
 deeper. It differs markedly from the corresponding bone of PL mudgei 
 (see PI. XXVII), in its less broad and deep emarginations. An 
 episternum which I provisionally refer to the species Tr. anony- 
 mini, herewith figured, resembles that of D. osborni more closely. In 
 all three, perhaps belonging to distinct genera, it will be seen that 
 
 Fig. 10. 
 1, Episternum and clavicles of Muratnotatana ; 2. 3. the same of PUsiosaurus, from above and 
 below. After Seelev. 
 
4 6 
 
 Field Columbian Museum — Geology, Vol. II. 
 
 the emargination behind represents a distinct foramen in the com- 
 pleted girdle — the interclavicular foramen, of which the only mention 
 hitherto that I can find is tjy Seeley (Proc. Roy. Soc. Lond. li, p. 140), 
 whose figures I reproduce here. 
 
 In PI. XV is shown the articulated pectoral girdle from below. 
 and in PI. XIV, the same is shown in front view. As a whole, 
 the girdle forms a rather deep trough, with the dorsal rami of the 
 scapula directed upward and somewhat outward. Its exact position 
 in relation to the ribs is difficult to state, but I do not think that the 
 position given in the restoration can be far wrong. The slight 
 
 Fig. 11. 
 
 Sc apuloc lavicular girdle of PUsiosaurtts nuidgci from above; the missing parts restored in 
 
 dotted lines. Ic, episternum; <l .. clavicle; fc., scapula, - co., epicoracoid process. 
 
 degree of curvature of the ribs in the pectoral region must have left a 
 rather angular margin to the thorax on either side, filled in, in part at 
 least, by the cartilaginous continuation of the thoracic ribs, which 
 the preserved ends plainly show were present. The upper surface of 
 the girdle was not hollowed much, if any, longitudinally, so that the 
 base of the neck must have been in life quite deep. 
 
 An examination of the under surface of the girdle, as shown in 
 PI. -XV, furnishes, I think, convincing proof that the space between 
 the scapulae, epicoracoid process and the elliptical lines on the ven- 
 tral surface of the episternum was filled in in life by cartilage, join- 
 ing the coracoid and scapula and covering the squamous portion of 
 the episternum, but leaving the interclavicular foramen free. Ossifi- 
 
Apr. 1903. North American Plesiosaurs— Willis ion. 47 
 
 cation of this cartilage evidently occurs in some forms, uniting the 
 whole into a single ventral plate, which is said to have a sutural con- 
 nection with the epicoracoid processes, forming what Seeley calls the 
 Elasmosaurian type of girdle. Seeley suggests that this cartilage 
 may represent the precoracoid: "In all Plesiosaurs, on the other 
 hand, the precoracoid, if developed, remains cartilaginous ; but I 
 infer that a cartilage always extended from the anterior margin of the 
 coracoid to the anterior extremity of the scapula, and, by ossification 
 of such cartilage, the Plesiosaurian shoulder girdle would become 
 Elasmosaurian."* 
 
 This precoracoid nature of the cartilage is contested by Koken : 
 "The view that the bone considered to be the scapula in the Plesio- 
 saurs also includes the precoracoid is supported neither by compar- 
 ison nor observation. In no reptile has there been shown to be a 
 union of the scapula with the precoracoid more intimate than its 
 union with the coracoid, and its fusion with the scapula without 
 union with the coracoid would be remarkable. I agree quite with 
 Haur, who considers the forked bone of the turtles to be the scapula 
 only, its two branches being homologous with those of the plesiosau- 
 rian scapula. Seeley believes that the precoracoid was cartilaginous, 
 connecting the front end of the coracoid with the anterior end of the 
 scapula, and that this became ossified in the Elasmosaurians in such 
 a way that it was separated from the coracoid by suture, but was 
 fused with the scapula. That is, it is the precoracoids and not the 
 scapulae which meet in the middle line. It seems to me that this 
 would be the method of extension and ossification of the scapulae. 
 Why, then, should we call in the aid of a cartilaginous precoracoid as 
 an unknown quantity, which later becomes indistinguishably fused 
 with the scapula ?"f 
 
 The precoracoid arises from a distinct ossificatory center, when 
 ossified. Is it reasonable to suppose, then, if this is a distinct ele- 
 ment, that any such mode of extension of the scapula as Andrews has 
 shown to be the case in Cryptoclidus oxoniensis\ would occur if there 
 was really a union of scapula and precoracoid? He shows clearly 
 that the scapula increases in length peripherally, and not by the addi- 
 tion of an ossified cartilage. If it arose from a distinct center, as it 
 must, one would certainly expect to find it in a separated condition 
 in the young animal, but this was not the case in the ones that 
 Andrews examined. Furthermore, in what possible way could a carti- 
 
 •Proc. Roy. Soc. Lond. li, p. 138, 1892. 
 
 tKokcn. Zetttchr. Dentscben Geol. GeteJIacb. 1S93. xlv, 346. 
 
 JAnn. Man. Nat. Hbt. 1895. 
 
48 Field Columman Museum — Geology, Vol. II. 
 
 lage bone like the precoracoid get entirely on the outside and seal in 
 a membrane or dermal bone? I would sooner believe that the 
 so-called clavicles are really precoracoids, and for this belief their 
 position on the visceral side of all three cartilage bones, the scapula, 
 episternum and coracoid, would lend some support. In no case, how- 
 ever, can I believe it probable that this cartilage represents the pre- 
 coracoid. 
 
 The same argument will apply in its entirety to the assumption 
 that the ventral ramus of the scapula is in reality the precoracoid. 
 In no specimen has it ever been found as a distinct ossification. It 
 grows peripherally, enclosing the clavicles on their outer side. The 
 elongated clavicles unite by suture with the scapula in the Notho- 
 sauria without the intervention of any precoracoid process. By the 
 reduction of the clavicles and the extension of the acromial process in 
 these animals we would get the Plesiosaurian girdle. Is it necessary 
 to insert a distinct ossificatory element in this development? 
 
 It may be added that Koken believes the precoracoid to be fused 
 with the coracoid. 
 
 I cannot, therefore, believe that the precoracoid is represented 
 by any ossification in the plesiosaurian clavicular girdle. Nor do I 
 believe there is any genetic relationship between the ventral ramus 
 of the Plesiosaurs and that of the Chelonian scapula. If there is, is 
 it not strange that in the one case the branch should lie ventrad to 
 the clavicle and in the other dorsad? I am well aware that in thus 
 concurring in the views held by Seeley, Andrews, Koken, Baur and 
 others, there are pertinent arguments on the other side given by 
 Hulke, and especially Fiirbringer. * 
 
 Pelvic Girdle. — The pubis varies but little from the usual form. 
 It is a broad, flattened plate of bone, thinned throughout, except at 
 the symphysial and acetabular articulations. It is, in general, quad- 
 rilateral in shape, with the anterior inner angle broadly rounded, and 
 the acetabular angle truncated. The posterior and outer borders are 
 both markedly concave, and of about equal length. " The anterior 
 border is more nearly straight and irregular. The inner border is 
 thickened on the posterior third or half, gradually becoming thinner 
 anteriorly. The obliquely truncated sutural surface is much rough- 
 ened. The two bones, when united, must have made an angle with 
 each other of about one hundred and twenty-five degrees. I do not 
 think that there was much cartilage between the two, or that it 
 extended back to the ischial symphysis, though it may. Anteriorly 
 
 Jena. Zeitschr. 1900. p. 332. 
 
Apr. 1903. North American Plesiosaurs — WfLusTON. 
 
 49 
 
 the cartilage continued to the rounded outer anterior angle, where 
 the bone is a little more thickened. The acetabular surface is much 
 the larger of the articulating facets. It meets the smaller and rough- 
 ened facet for the ischium in a very obtuse angle. The bone is more 
 thickened on the outer and posterior parts, that is, near the non- 
 cartilaginous border, than elsewhere. (See PI. XVI.) 
 
 Fig. 12. 
 
 Diagram of pelvic girdle of Delichorhynckops estemi, visceral surface. I'n.. pubis; ist, ischium; 
 ;/.. ilium. < 
 
 The ischium is more elongate and proportionally larger than is 
 usual among plesiosaurs, though of the usual hatchet shape. It has 
 three hon-sutural articular surfaces — the larger middle one, looking 
 directly outward in the articulated ischium; a smaller posterior one, 
 
50 Field Columbian Museum — Geology, Vol. II. 
 
 looking upward; and a small one looking forward and a little down- 
 ward for the pubis. The anterior border is concave, and the portion 
 adjacent to this border is the thickest of the bone. The symphysial 
 border is thickened on the anterior third, gradually thinning posteriorly. 
 This border is obliquely truncated, as in the pubis, anteriorly; poste- 
 riorly the cartilaginous border, moderately thin, is continued around 
 .the inner angle to the outer one, where it meets the free outer border 
 abruptly. The outer border is gently concave in its whole extent, 
 and only a little thicker than the inner portion of the bone. It ends 
 in a right angle. (PI. XVII.) 
 
 The ilium is a small, rod-like bone, moderately expanded at its 
 ischial extremity. Of the two articulating extremities, that for the 
 ischium is much larger than the one for the acetabulum. In the 
 middle of the bone, a cross-section is roundly oval. The upper 
 extremity has a small, flattened, parallelogrammatic surface, which, 
 in the articulated pelvis, looks inward, slightly backward, and 
 perhaps a little downward. The bone when articulated was directed 
 backward at an angle of about thirty degrees, and inward perhaps a 
 little more. There is very little evidence of articulation with the 
 sacral ribs. The union must have been weak and slight. 
 
 The pelvis, as a whole, was troughlike, as was the pectoral girdle. 
 The two bones meet at a considerable angle, and it is also certain 
 that there was a large angle between the ischium and pubis, so that, 
 with the ischial symphysis nearly horizontal, the pubes were directed 
 at a considerable angle downward. This position, indeed, is necessary, 
 since otherwise there would have been a strongly upward turn of the 
 abdominal contour immediately behind the coracoids, and the ischia 
 and pubes will articulate in this position only in this specimen. 
 
 Front Limbs. — The paddle-bones of the specimen were all com- 
 pletely intermingled and displaced, so that none could be referred to 
 its proper limb from the position they were in. 
 
 Apparently nearly all were preserved, though some of them were 
 distorted and crushed. The labor of assorting and correctly locating 
 these parts was very great, especially the phalanges; indeed, of the 
 latter there is little assurance that the final collocation in many cases 
 is correct. Aside from the femora and humeri, the only distinction 
 that could be made between the bones of the front and hind limbs 
 was in the size, always slightly smaller in the hind than in the fore 
 limb. By thus assorting into pairs and assigning the smaller pair to 
 the hind limb it was certain that the bones of the epipodial and meso- 
 oodial regions were correctly placed. The labor was much lightened 
 
Apr. 1903. North American Plesiosaurs — WiLLlSTON. 51 
 
 by the aid of a nearly complete paddle of another species, described 
 further on. This paddle was less compressed and distorted, and I 
 have therefore reserved it for a more full description of the parts and 
 discussion of the functions. 
 
 The humerus of Dolichorhynchops has the head only moderately 
 convex, with its margins rather sharply limited, its greater convexity, 
 as usual, on the radial side; its general surface looks mesad and 
 ventrad at an angle of about forty-five degrees. Its cartilaginous 
 surface is continuous with that of the tuberosity, which has a large, 
 flat surface, directed dorsad and mesad at an angle of about forty-five 
 degrees. The grooves separating the surface from the head are 
 broad and shallow, that of the ulnar side the broader. The anterior 
 border of the bone is concave on the proximal part, gently convex at 
 the middle and shallowly concave on the distal part. The posterior 
 border is nearly straight on the shaft, deeply concave distally. The 
 distal anterior angle is rounded in both specimens. On the distal 
 border two facets are apparent, for the radius and ulna; the rest of 
 this border presents no clear indications of articulations. The 
 pectoral rugosity is strongly roughened, and produced into a broad, 
 low tubercle; the roughening, moreover, is continued obliquely nearly 
 to the other rugosities on the sides. It is situated nearer the head 
 than in Polycotylus. The ulnar rugosity forms a deep pit above the 
 middle of tlie bone, while the radial rugosity is opposite it and much 
 nearer the head of the bone than in Polycotylus. 
 
 Three bones were certainly located in the fore-arm, and a fourth 
 one seems to be represented by a pair of small nodules. The free, 
 emarginate border between the radius and ulna is less apparent than 
 it is in Polycotylus. The relations of all the smaller bones seem to 
 be quite as they are in Polvcotvlus. and the reader is referred to the 
 figures of the two paddles for comparison, in connection with the 
 description of that of Polycotylus. » 
 
 Hind Limbs. — The femur shows the usual plesiosaurian differences 
 from the humerus, in its greater slenderness, slightly greater length, 
 tnore slender shaft and less dilated distal extremity. The anterior 
 border, as seen in the figure, is nearly uniformly concave, terminating 
 in a more pronounced angle than in the humerus. The posterior 
 border is, also, concave throughout to the greatest expansion, which 
 occurs more proximally than in the humerus, and in a rather better 
 marked angle. The rugosities of the under side and margins art as 
 in the humerus, though scarcely as well marked. Whether the bones 
 of the leg and ankle have been correctly located, rather than in the 
 
52 
 
 Field Columbian Museum — Geology, Vol. II. 
 
 fore limb, is impossible to say— the only differences that could be 
 detected are the rather lighter weight or greater slenderness of those 
 located here. Their relations to each other are precisely those of the 
 fore limb. It seems probable that the fourth bone on the posterior 
 side of the first row, articulating with the femur, was wanting in life, 
 or at least was. very small — none were preserved. The fore and hind 
 limbs, as restored, are of the same length. All four paddles were 
 restored as completely as those shown in the figures. 
 
 CIMOL1ASAURUS SNOW1I. 
 
 Skull. — The skull of this species was briefly described by me in 
 the Transactions of the Kansas Academy of Science for 1890, to which 
 some additional observations were made by Cope in the Proceedings 
 of the. American Philosophical Society for 1894, p. 109. I give here 
 a more complete comparative description, in the light of the infor- 
 mation furnished by other known forms, especially DolicJiorJiynchops-. 
 
 Fig.13. 
 
 Skull of Cimoiiasaiirns siwivii Will. Pfn. premaxilla; en., external naris; mix., maxilla; ff. t 
 prefrontal; pof., postfronto orbital; J., jugal; sq.. squamosal; pa., parietal; so., supraoccipital; co., 
 exoccipital; q.. quadrate; qj. quadratojugal; d, dentary; sur., surangular; ang., angular. 
 
 The parietals form a steep, roof-like covering, ascending into a 
 thin, sharp, sagittal crest, extending through nearly their whole 
 length, from the attachment of the squamosals posteriorly as far for- 
 ward as the posterior part of the orbit. This crest, throughout most 
 of its extent, forms a thin, vertical plate, with nearly parallel sides 
 
Apr. 1903. North American Plesiosaurs — WlLLiSTON. 53 
 
 for about two inches, its thickness on the margin varying from two 
 to four millimeters. Posteriorly they expand into a thickened, trian- 
 gular process on each side, projected downward and backward ovei 
 the supraoccipitals for union with the squamosals. Extending the 
 whole length of the crest is a well-marked suture. Near the anterior 
 extremity of the crest is the parietal foramen, which has been closed 
 by compression. 
 
 The postorbital appears as a narrow bar directed outward and 
 downward. Its union with the supraorbital above and the squamosal 
 below is shown in the figure. The bone is triangular in shape, as 
 seen externally, the suture for the jugal extending back horizontally, 
 and is then turned upward at right angles to meet the free margin of 
 the arch. 
 
 The suture separating the jugal from the squamosal begins at 
 the angle of the postorbital suture and runs obliquely downward and 
 backward to meet the lower border of the arch about fifty millimeters 
 back of the teeth. The suture is a jagged one, but its existence as 
 described and figured is beyond doubt. Professor Cope figured it 
 much further back on the arch, but his supposed suture is very plainly 
 a fracture. The bone unites below with the maxilla by a long, nearly 
 horizontal suture, that begins in an angle a little back of the middle 
 of the orbit and joins the alveolar margin near the last tooth. The 
 anterior part of the suture is nearly at right angles to the remainder, 
 joining the orbital margin back of the middle of the orbit. 
 
 The squamosal, or squamoso-prosquamosal, is a large, triradiatt 
 bone joining the jugal and the postorbital anteriorly, the parietal 
 above, the quadrate and quadratojugal below. Cope has figured the 
 upper branch as a distinct bone under the name of supramastoid. 
 This was an error, as has already been stated. At the anterior infe- 
 rior part of the quadrate there is a distinct suture, as has been 
 figured, corresponding to the suture described as existing here in the 
 specimen of Dolichorhynchops. In the figures given of C. snovtii, it 
 was supposed that the quadratojugal was a small element. It now 
 seems probable that its relations to the squamosal are like those of 
 Dolichorhynchops; at least there is an indication that the real suture is 
 continued upward and forward for some distance. The union of the 
 squamosal and quadrate is very much as it is in Dolichorhynchops. 
 
 The quadrate does not seem to differ from that described in Dolt' 
 cftorhynchops. 
 
 The premaxillary is very large and massive. Its dentigerous por- 
 tion is broad and thick, with numerous pit-like depressions. It con- 
 tains six very large and powerful teeth on each side, the maxillary 
 
54 Field Columbian Museum — Geology, Vol. II. 
 
 suture beginning just back of the sixth tooth. The distinguishing 
 suture turns upward and backward to meet the anterior end of the 
 external nares in front of the orbit. Above this, for a short distance, 
 the bone is so crushed that the suture is not determinable with cer- 
 tainty, but the upper end is evident, nearly above the middle' of the 
 orbit. The suture separating the two premaxilla? is distinct 
 throughout. 
 
 The maxilla has on each side sockets for twelve or thirteen teeth, 
 all. except a few of the anterior ones, much smaller than those of the 
 premaxilla, and smaller than those of the mandible in this region. 
 From the nares, which are chiefly excavated from this bone, the 
 suture turns upward and backward for about twelve millimeters, sep- 
 arating the nasals ; it then turns downward and backward to join the 
 anterior orbital margin, uniting with the prefrontal. The lower 
 anterior" margin of the orbit is thus formed by the maxillary plate, 
 which shows a shallow groove. The maxillary plate on the left is 
 smooth and undistorted, the nasal and prefrontal having been sepa- 
 rated at their sutures. There is no indication whatever of a separa- 
 tion into two elements, nor is there any free lachrymal. Posteriorly 
 the maxilla forms a rather broad plate below the orbits, having a 
 convex thinned margin continuous with that of the jugal. Back of 
 the middle on this margin, the suture for the jugal turns directly 
 downward for about twelve millimeters, and then backward in a 
 straight line to terminate just beyond the last tooth. 
 
 That element which, in Dolichorhynchops , is described as the 
 supraorbital, is a much more massive bone in Cimoliasaiirus. It 
 unites with the postorbital by a strong suture, behind the middle of 
 the orbit above, and is not separated by a deep notch. as in that 
 specie's. The bone arches forward and downward to beyond the 
 middle of the anterior part of the orbit, as in DolicJiorhynchops, stand- 
 ing out prominently over the orbit and terminates in a strong suture 
 by which it is united to the ascending plate of the maxilla, as has 
 been described. Its union with the prefrontal or frontal cannot be 
 determined in the crushed state of the specimen. Such relations of 
 a supraorbital bone with the postorbital, maxilla, nasal, etc., are almost 
 inconceivable, but are altogether right for a prefrontal. If this be a 
 prefrontal, then the same element in Dolichorhynchops must also be 
 the prefrontal, and the so-called postprefrontonasal is in reality the 
 frontal, while the anterior prolongation from the parietal is in reality 
 a process from that bone, separating the frontals, a most remarkable 
 arrangement for an)- vertebrate skull. I am forced to believe, how- 
 ever, that such is really the explanation of these bones. 
 
Apr. 1903. North American Plesiosaurs — Williston. 55 
 
 The supraoccipitah are visible from the sick behind and are not 
 covered over by the wing-like expansions of the parietals, as in Doli- 
 chorhynchops. They are paired and separated throughout, as in that 
 genus. Below they unite with the exoccipital, and include a part of 
 the semicircular canals. Above and in front they join the parietals 
 at their posterior margin and not under the roof. The exoccipitals 
 are also visible. The paroccipital process is slender, its posterior 
 margin thin, joining the supraoccipital in an angle without the small 
 excavation which is seen in Dolichorhynchops at this place. 
 
 Lying within the orbit are thirteen thin, bony sclerotic plates, the 
 largest about twenty millimeters in 'diameter, with somewhat crenu- 
 lated margins. The larger number are lying in position, imbricated 
 with each other. 
 
 There are sockets in the mandibles for nineteen or twenty teeth 
 on each side. Those in the upper jaws seem to be the same in num- 
 ber, though the small posterior ones are so covered by the inferior 
 teeth that the number cannot be positively determined. The largest 
 teeth implanted in the upper jaw are those of the premaxilla; back 
 of these there is but a single large tooth, situated just in front of the 
 orbit. The largest teeth of the mandible are the ones corresponding 
 to those of the premaxilla ; the posterior ones, however, are much 
 1 than the corresponding ones of the upper jaw. The anterior 
 teeth, especially, are elongate, conical and lightly recurved. All are 
 sharply pointed, with the crown; within a half or three-fourths of an 
 inch of the socket, finely striated. The largest is that of the pre- 
 maxilla just in front of the maxillary suture, which measures fifty- 
 three' millimeters in length by thirteen in width at the base of the 
 crown. The first tooth in the mandible is fully as long, though a 
 little more slender. 
 
 The pterygoids are so crowded in between the mandibles and 
 maxilla; that only a portion of them is visible. The posterior part 
 joins the quadrate by a stout plate, as in Dolichorhynchops. By the 
 sides of the sphenoids the plates are broad and massive, with a 
 thinned outer crenulated margin. The ectopterygoid unites with the 
 jugal and maxilla. Evidently there are elongated interpterygoid 
 vacuities, as in Dolichorhynchops. 
 
 The mandible, from the tip of the symphysis to the hind extremity, 
 measures '480 millimeters, of which the teeth occupy 320. Its least 
 width, near the middle, is 40 millimeters: its greatest width, just back 
 of the teeth at the coronary eminence, is 75 millimeters. The length 
 of the symphysis is 65 millimeters. The two sides are firmly coOssified, 
 traces of the suture being visible in the posterior part only. The 
 
56 
 
 Field Columbian Museum — Geoloqy, Vol. II. 
 
 sutures separating the angular, surangular and dentary are shown in 
 the figure. 
 
 Cervical Vertebra. — There were twenty-eight cervical vertebrae 
 in a continuous series preserved, the last five or six, owing to 
 exposure, in a less perfect condition: the others complete or nearly 
 so. Traces of the sutures uniting the neural arches with the centra 
 can be observed in the third and fourth vertebrae only. The atlas and 
 axis are so wedged in the compressed occipital region that the former 
 bone can not be distinguished, and the latter is visible in part only. 
 The third vertebrae, herewith figured, differs from the following ones 
 in the greater obliquity of the spine, in the more oblique anterior 
 face of the centrum, in the presence of a conspicuous carina below in 
 front, and in the simple, pointed shape of the single-headed rib. The 
 fourth vertebrae has the neural process less oblique and broader, the 
 carina in the middle of the concavity of the under surface not visible 
 from the side; the rib is broad and of nearly equal width throughout. 
 In the sixth vertebrae and beyond the neural process is broader and 
 nearly vertical; the ribs are broad, with more marked anterior and 
 posterior prolongations distally. The spines increase in width through- 
 out the series, but are only a little longer posteriorly. The posterior 
 centrum is more than three times the length of the anterior ones and 
 the diameter posteriorly is more than twice that anteriorly. The ribs 
 of the posterior vertebrae are but little longer, though much wider, 
 than those of the anterior vertebrae. The following measurements 
 will exhibit these differences in size more exactly: 
 
 Number of Vertebra. 
 
 3 
 
 4 
 
 6 
 
 9 
 
 14 
 
 20 
 
 27 
 
 Length of centrum 
 
 23 
 
 30 
 
 48 
 
 53 
 
 63 
 
 78 
 
 90 
 
 Height of centrum .... 
 
 25 
 
 27 
 
 42 
 
 44 
 
 50 
 
 60 
 
 68 
 
 Height of spine above floor . 
 
 
 
 
 
 
 
 
 of neural canal .... 
 
 55 
 
 46 
 
 47 
 
 47 
 
 50 
 
 62 
 
 
 Width of spine . 
 
 
 24 
 
 36 
 
 40 
 
 42 
 
 65 
 
 
 Length of rib 
 
 
 40 
 
 
 40 
 
 48 
 
 
 
 Width of rib 
 
 
 24 
 
 
 49 
 
 56 
 
 65 
 
 
Apr. 1903. North American Plesiosaurs — Williston. 57 
 
 BRACHAUCHENIUS LUCASI, GEN. ET SP. NOV. 
 
 The specimen upon which this genus and species are based is 
 one of much interest, not only because of its excellent preservation 
 and preparation, but also because of the new features which it 
 presents. It consists of the skull, neck, and larger part of the dorsal 
 column, all lying together in their natural relationships, and all with 
 the ventral surface exposed, in the prepared specimen. The specimen 
 was collected some years ago near Delphos, in Ottawa County, Kan- 
 sas. Its horizon is the Benton Cretaceous. It is now preserved in a 
 wall-case in the National Museum. I desire to express my hearty 
 thanks to the authorities of the National Museum for permission to 
 study and describe the specimen, and especially to Mr. F. A. Lucas 
 for much kind assistance. It gives me great pleasure to honor, in 
 the specific name, one who has done much valuable work in American 
 paleontology. (Pis. XXIV, XXV.) 
 
 Skull. — The palatal surface of the skull lies exposed, with the 
 mandibles in position. There has been but little distortion or dis- 
 placement, the mandibles being slightly depressed and pushed to the 
 left. The limestone matrix 'has been carefully removed from most 
 parts, leaving the bones entirely clean. The sutures are entirely 
 clear, and there are but few adventitious fractures to obscure the 
 relations of the parts. It is certain that additional excavation will 
 reveal further characters of importance, but not many, unless the 
 specimen be entirely removed from the matrix. The specimen as 
 now mounted in the wall slab makes a very interesting and instructive 
 display, but I believe that some day it will be advisable to remove it 
 entirely from its limestone bed and mount it after the manner of a 
 recent skeleton. It was fortunate, however, that this was not done 
 before a careful examination had been made of the natural relations 
 of the bones, as it would have been difficult to believe that the neck 
 comprised but thirteen vertebrae, had not the matrix conclusively 
 demonstrated the fact. It is the shortest-necked plesiosaur known, 
 differing in this respect not greatly from the short-necked aquatic 
 saurians of other orders. 
 
 The pterygoids extend far back to unite with the lower end <>t the 
 quadrates, apparently quite as usual in the plesiosaurs, though tin- 
 precise place of junction is obscured by the mandibles ; the process 
 
58 Field Columbian Museum — Geolooy, Vol. II. 
 
 is slender. The two bones meet in a median suture on the under 
 side of the sphenoid, their posterior border forming a wide and deep 
 concavity. The outer margin of the bones converge from the quad- 
 rates as far forward as the posterior end of the interpterygoid vacui- 
 ties, where they curve outward into the posterior border of the ecto- 
 pterygoid processes. The under surface is shallowly concave on 
 either side back of the vacuities, but in the middle there is a rather 
 strong, obtuse ridge. A little back of the vacuities, on either side, 
 with their origins separated, a narrow and strong ridge arises to 
 curve outward and become lost on the under border of the somewhat 
 descending ectopterygoid process. In front of the vacuities the two 
 bones again meet in a long median suture. The palatal surface here 
 occupies a somewhat higher plane than that of the posterior part, and 
 is flat throughout. The bones of the two sides gradually narrow in 
 width to terminate by an obtuse extremity near the middle of the 
 palate. Between the ectopterygoid processes and between the curved 
 ridges already described there is a narrow, deep vacuity, with two 
 oval, elongated, well-defined foramina or vacuities at the bottom, the 
 " palatonares" of Owen, the "posterior palatine vacuities" of 
 Andrews, the "interpterygoid vacuities" of authors. A discus- 
 sion of their character will find a place further on. The lateral walls 
 of this fossa posteriorly are nearly vertical, but the anterior end of 
 the fossa is but little or not at all excavated above the plane of the 
 palate here. From the anterior end of the median posterior inter- 
 pterygoid suture two sutures diverge, leaving a large angular sloping 
 surface exposed which forms the posterior roof of the fossa ; the bone 
 exposed between the V-shaped sutures is the basisphenoid, and has 
 attached to it by suture the so-called parasphenoid bone in front. 
 Just how the diverging sutures terminate I cannot definitely say. 
 They seem to follow the lower angle of the lateral wall of the fossa 
 as far forward as the middle of the vacuities and thence return to join 
 the parasphenoid suture at the posterior part of the vacuities. If 
 this determination is correct, these projections would correspond to 
 the basipterygoid processes of the lizards. The ectopterygoid pro- 
 cesses of the pterygoids, the continuation of the curved ridges, have a 
 rounded, prominent under border, with a terminal, large, vertical or 
 oblique, abutting, mandibular surface. This ridge and its abutting 
 surface are very much as they are in Pliosaurus, and the whole struc- 
 ture here also reminds one of the crocodiles. 
 
 The transverse, transpalatine or ectopterygoid bone is a rather 
 small, flattened polygonal bone, whose under surface is continuous 
 with that of the palatine and pterygoid in front. It joins the ptery- 
 
Apr. 1903. North American Plesiosaurs — Willistok. 59. 
 
 goid on the inner side and behind, the posterior suture descending on 
 the side of the projecting process of the pterygoid. To what extent 
 the bone enters into the abutting surface for the mandible I could not 
 determine. Anteriorly the bone joins the palatine by a clearly 
 marked suture. Its outer border posteriorly is rounded and seems to 
 be free, forming a part of the border of the posterior palatine vacuity, 
 but this can not be determined without further excavation of the 
 matrix. The outer attachment of the bone (doubtless to the jugal 
 and maxilla) cannot be determined. 
 
 The palatines are long flat bones which meet for a considerable 
 distance in a median suture in front of the pterygoids, a feature hith- 
 erto unknown among the plesiosaurs. In front this median suture 
 divaricates to admit the pointed extremities of the vomers. A little 
 distance from the interpalatine suture, near its middle, there are, on 
 either side, two or three small, round foramina. The outer border 
 of the palatines continues the border of the ectopterygoids throughout 
 and is continuous, apparently with the lateral border of the vomers. 
 How far this apparent border in the specimen represents the real 
 border of the bone cannot be determined without additional excava- 
 tion of the matrix, here filling in a narrow space between the apparent 
 margin and the mandible. It is possible that there may be no free 
 border, though I think it probable that there is a smaller or larger 
 posterior palatine vacuity on each side posteriorly. It is probable 
 that the sides of the bones turn upwards to meet the maxillae in the 
 way they are figured by Sollas in Plesiosaurus.* 
 
 The posterior pointed extremities of the vomits are seen in the 
 middle in front, enclosed between the V-shaped suture of the pala- 
 tines. The suture seems to be visible to the border of the palatine 
 and includes no part of a narial opening. The nares hence must be 
 situated far forward between the vomers and the maxilla 1 . Unfor- 
 tunately this part of the skull has been injured somewhat before 
 removal, and the complete structure here cannot be determined. 
 
 The so-called " parasphetwid" is different from that element in 
 Other plesiosaurs. It is a single bone separating the interpterygoid 
 vacuities. As seen from below, it is spindle-shaped, narrow in the 
 middle, moderately expanded at either extremity. Posteriorly it is 
 joined by a clearly marked suture with the basisphenoid. Anteri- 
 orly it joins the two pterygoids in the entrant angles, but does not 
 extend much, if any, beyond the angle. The vacuities separated by 
 this bone are long and oval, situated at the bottom of the fossa 
 already described, between the pterygoids and in front of the basi- 
 
 •Quart. Journ. Geo!. Soc. 1881. p. 475, '• 12- 
 
60 Field Columbian Museum — Geology, vol. II. 
 
 sphenoid. It would seem that there could be no further question as 
 to the character of these vacuities — simply fortuitous openings — 
 separated by a remarkably persistent, well-ossified parasphenoid, 
 invariably found in all plesiosaurs, but never in their nearest allies, 
 the turtles and nothosaurs. In most of the plesiosaurs in which the 
 palate is known, the openings are situated more nearly upon the 
 plane of the palate, and, though somewhat variable in shape, are 
 always of moderate or considerable size. In this species, however, 
 they are at the bottom of a well-marked, rather deep fossa, with well 
 defined lateral walls and a sloping posterior roof. 
 
 These foramina in the plesiosaur skull were first thought to be 
 the nares by Owen, who, however, confounded the anterior part of 
 the pterygoids with the palatines. Huxley, who was also not clear 
 about the palatines, suggested that the real internal nares were smaller 
 openings situated more anteriorly. Sollas (1. c.) discussed the matter 
 more at length and reached the conclusion that the real internal nares 
 were situated far in front, between the premaxilla and vomer, with 
 the palatines probably entering into the posterior border. Andrews 
 has accepted this location of the nares, and has figured and described 
 the openings in three genera of the plesiosaurs, always bounded by 
 vomer, palatine and maxilla. In DolichorJiyncJiops osborni, however, 
 as seen from the figure and descriptions, these openings can only be 
 situated between the vomers and palatines and at some distance 
 from the maxillae. In my description I accepted these orifices as the 
 true nares, though greatly astonished at their minute size, and 
 although they correspond with similar foramina between the vomers, 
 in the mosasaurs. 
 
 If we are to seek for the nares in their present specimen else- 
 where than in the openings I have described it must be far forward, 
 perhaps in precisely the position assigned to them by Sollas. In all 
 the known forms, with this interpretation, they would be in front of 
 the external nostrils, in the present species far in front. What 
 possible combination of circumstances would have caused the recession 
 of the external nostrils to a place so close to the orbits without 
 affecting the position of the internal openings? I certainly suspect 
 that in this species at least the openings between the pterygoids are 
 the rt-al internal nares. As to the character of the separating element 
 I am forced to the conclusion that Andrews has reached, that it is 
 the parasphenoid. If the element in front called the vomers are 
 rc-ally those bones, and there could seem to be no doubt that they are, 
 then- is nothing else left, save possibly the turbinated bones. 
 The slender bone in precisely similar position in the ichthyosaurs 
 
Apr. 1903. North American Plesiosaurs — Wilms ion. 61 
 
 is usually called the presphenoid. Such perfect and persistent 
 ossification of the parasphenoid, scarcely found elsewhere among the 
 reptilia, unless it be the snakes, is in any case remarkable. Why 
 should it be persistent in separating such persistent foramina, unless 
 the openings were of functional importance? One would expect 
 that the pterygoids would have united along the whole median 
 line, as in the Nothosauria, or that they should have closed up 
 in front of the basisphenoid, as in the Chelonia. Sollas objects 
 to this posterior position of the nostrils, because there is no ossified 
 canal for the air passages, as in the crocodiles; but his specimen, as 
 ours, would call for a canal running in the opposite direction, from 
 the posteriorly situated external nares anteriorly to the internal open- 
 ings, and, in the present species, this canal would have been eight or 
 more inches in length. And why may not the canal have been 
 cartilaginous in either case? 
 
 Mandible. — The mandibles are nearly in place on the under side 
 of the skull. They are a little compressed from above downward. 
 The symphysis is short, the two jaws meeting in a considerable angle. 
 The portion in front of the posterior end of the symphysis has been 
 somewhat injured in the specimen, so that the precise shape and 
 length can not be ascertained. The angular extends posteriorly into 
 a relatively short process; the expansion below the cotylar cavity 
 is rounded. In front of the cavity, the angular extends forward to 
 within six inches of the symphysial angle, terminating in a slender, 
 sharp end. From a little in front of the middle of the ramus it is 
 excluded from the inner surface. In front of the cotylar cavity the 
 greater width of the outer surface is composed of the surangular. 
 Between these two bones, the dentary sends a long, slender process 
 backward to within six inches of the cotylar cavity. 
 
 Length of skull to end of mandible . . . . 1.1 m. 
 
 Length of skull to condyle ........9m. 
 
 Width of skull between outer margins of quadrate . . .28111. 
 
 Vertebr/e. — The atlanto-axial complex is thoroughly united, with- 
 out indications of sutural division. The axial rib appears to be 
 united with the axis only, though it may come in contact with the 
 axial intercentrum. The atlas is convex from side to side, without 
 indication of a median carina. The other cervical centra, as Seen 
 from below, are nearly flat, with a slight convexity in the middle, and 
 a slight concavity on either side before the sutural surface for the rib. 
 This flatness is a natural character and not due to compression. The 
 median convexity increases gradually throughout the cervical series. 
 
62 Field Columbian Museum — Geology. Vol. II. 
 
 Tin- increase in length of the cervical vertebrae is slight, as will be 
 stLii from the table of measurements. The articular margin of the 
 vertebrae, throughout both the cervical and dorsal series, is sharp, 
 not rounded for a continuation of the cartilaginous surface, as is so 
 often the case among plesiosaurs. The ends, as seen in the third 
 vertebra, are distinctly though not deeply concave. The ventral 
 vascular foramina, so characteristic of plesiosaur vertebrae, appear to 
 be wanting throughout the whole series, nor is there the slightest 
 indication of a median ridge and lateral grooves. The lower margin 
 of the rib articulation approaches the ventral plane in the early 
 ■cervicals, but ascends somewhat on the sides of the vertebra in the 
 last cervical. 
 
 Twenty-two dorsal vertebrae are preserved in natural sequence. 
 Because of the decrease in the length of the transverse process in the 
 late dorsals, it does not seem probable that more than eight or ten 
 presacral vertebrae could be missing, making altogether about thirty, 
 the usual number of dorsal vertebrae. The length of the centra 
 increases more rapidly, though gradually, in the early dorsals, and 
 then remains constant throughout the remainder of the series. The 
 centra are deeply concave below and on the sides, expanding out- 
 wardly on the sides above to meet the sutural surface for the arch. 
 The surface of the centra is nearly smooth, with but slight indications 
 of crenulations before the articular margins. 
 
 Ribs. — The ribs throughout are single-headed, and of the usual 
 plesiosaurian type, though proportionally short in the thoracic region. 
 The axial rib is flattened spatulate at the distal extremity; massive at 
 the proximal. The lower surface is nearly flat, the upper surface 
 deeply concave, the anterior border gently, the posterior border deeply 
 concave. The rib of the third vertebra is more expanded distally, 
 with the distal posterior margin somewhat more produced, and the 
 distal border thinned. The fourth rib is more expanded distally, with 
 a more pronounced distal expansion, and the distal border seems to 
 be thickened for cartilage. The next four or five ribs differ only 
 slightly from the preceding ones. The rib of the tenth vertebrae is 
 more elongated and slender. The attachment to the centrum is 
 sessile or nearly so, the head inserted in a shallow pit. In the 
 eleventh vertebra there is a distinct exogenous process, standing out 
 twenty or twenty-five millimeters from the surface of the centrum to 
 the end of which is attached the rib. This process is equally as 
 prominent, or more prominent on the next two centra, the twelfth 
 and thirteenth. The rib of the twelfth vertebra is intermediate in 
 
Apr. 1903. North American Pi.k.sios.urs — Wiiusion. '63 
 
 length between that of the eleventh and of the thirteenth. On the 
 last cervical centrum, the thirteenth, the twelfth rib is long, heavy 
 and stout, more than half the length of the first dorsal. It is nearly 
 as stout as any of the following, but tapers somewhat distally, though 
 ending in a truncated, cartilaginous extremity. The distal end of the 
 eleventh rib is lost. The first dorsal rib resembles the one preceding 
 it, though longer. The second dorsal rib has acquired nearly the full 
 Length of the thoracic series. In the ninth rib there is a beginning ot 
 a diminution in size; the rib is less thick, a little shorter, and less 
 expanded at its extremity. The twelfth rib is completely preserved; 
 it is yet smaller and thinner than the eleventh, though still possessing 
 a cartilaginous extremity. Of the following ribs, only the heads of 
 some are preserved. 
 
 Diapophyses. — The diapophyses occupy an unusually low position 
 on the arch of the whole dorsal series, as do also the cervical ribs. 
 They have not been wholly freed from the matrix, and their relation 
 to the articular process is determinable only in slight part in a few of 
 the posterior vertebrae. The arch, like the cervical ribs, is united by 
 a strong, persistent suture, evidently an adult character, since the 
 sutures of the atlanto-axial complex have been entirely obliterated. 
 The process of the first dorsal is short, compressed, and somewhat 
 expanded at each extremity, it clearly springs from below the dorsal 
 surface of the centrum. As already described, the last cervical rib, 
 but little shorter than the first dorsal rib, is attached to a short 
 process which arises, apparently wholly, from the centrum. The 
 diapophysis of the first dorsal is less than twice the length of this 
 process, and so much like it that its sutural connection with the 
 centrum is the chief distinctive difference. The second dorsal dia- 
 pophysis is a little stouter than, and about twice as long as the first. 
 Its articular surface for the rib is larger, flattened, and looks down- 
 ward and outward. The fourth and fifth processes have attained the 
 maximum size of the series. They have a narrow, concave ventral 
 border, more strongly concave posterior border, a flattened, expanded 
 proximal end for union with the centrum and an expanded distal 
 extremity with its flattened oblique costal surface. Thu height of the 
 process distally, and its expansion beyond the plane of the articular 
 zygapophyses, can not be determined. It is very evident, however, 
 that the diapophyses lie below the plane of the zygapophyses. in 
 which they differ markedly from the diapophyses of Dolichorhyn- 
 ckops, where, throughout most of the dorsal vertebrae, tin van placed 
 wholly above the plane of the zygapophyses. The succeeding dia- 
 
6 4 
 
 Field Columbia^ Museum— Geology, Vol. II. 
 
 pophyses, to the sixteenth dorsal, scarcety differ in their shape and 
 relations to the centrum. These vertebrae may, therefore, be properly 
 called thoracic. From the seventeenth vertebra to the last one 
 preserved, the twenty-second post-cervical, the diapophyses decrease 
 rapidly in size, the last being scarcely more than half the length of 
 the fourth or fifth. In these posterior processes the proximal articu- 
 lation of the arch is as broad as in any of the others, but the distal 
 end of the process is more compressed, with only a small surface for 
 the small presacral ribs. Over the twentieth vertebra the matrix has 
 been cleared away sufficiently to disclose a posterior zygapophysis. 
 The free diapophysis in this vertebra is about fifty millimeters in 
 length, thirty in height, and about twenty in width. The posterior 
 zygapophysis arches upward and backward from the base of the free 
 process. 
 
 MEASUREMENTS. 
 
 Length of Centrum. 
 
 Width of Centrum. 
 
 Length of Rib. 
 
 Atlanto-axis, . . i . go mm. 
 
 
 
 Third cervical, 
 
 
 46 
 
 
 
 Fourth cervical, 
 
 
 46 
 
 82 mm. 
 
 60 mm. 
 
 Fifth cervical, 
 
 
 
 44 
 
 
 
 Sixth cervical,- 
 
 
 
 45 
 
 
 
 Seventh cervical, . 
 
 
 
 47 
 
 
 
 Eighth cervical, 
 
 
 
 50 
 
 84 
 
 74 
 
 Ninth cervical, 
 
 
 
 5° 
 
 
 
 Tenth cervical, 
 
 
 
 50 
 
 
 
 Eleventh cervical, 
 
 
 53 
 
 
 94 
 
 Twelfth cervical, . 
 
 
 58 
 
 
 
 Thirteenth cervical, 
 
 
 60 
 
 
 220 
 
 First dorsal, . 
 
 
 
 64 
 
 85 
 
 260 
 
 Second dorsal, 
 
 
 
 68 
 
 - 
 
 370 
 
 Third dorsal, 
 
 
 
 73 
 
 
 400 
 
 Fourth dorsal, 
 
 
 
 74 
 
 
 490 
 
 Fifth dorsal, . 
 
 
 77 
 
 
 445 
 
 Seventh dorsal, 
 
 
 77 
 
 82 
 
 370 
 
 Twelfth dorsal, 
 
 
 77 
 
 82 
 
 37o 
 
 Twenty-second, 
 
 
 74 
 
 82 
 
 
 LENGTH OF DIAPOPHYSES. 
 
 First, 
 
 Second, 
 
 Third, 
 
 47 mm. 
 65 « 
 
 Fourth, . 
 
 Fifth, 
 
 Thirteenth, 
 
 90 mm. 
 
 95 " 
 
 90 ** 
 
 Eighteenth, 
 
 Twentieth, 
 
 Twenty-second, 
 
 75 mm. 
 65 " 
 60 " 
 
A ik. 1903. North American Plesiosaurs — WlLLlSTON. 65 
 
 Among the characters which have been given in the foregoing 
 descriptions there are some of more than usual importance, of more 
 than generic value. It is quite evident that the form can not be 
 placed in the same family with Dolichorhynchops or Cimeliasaurks 
 snowii. Just what family this may be I can not say at present. It is 
 very evident that we have to do in the plesiosaurs with several dis- 
 tinct families, but the material is hardly sufficient yet to clearly define 
 them. Several names have already been proposed, based upon partial 
 characters, but there is no unanimity in their acceptance, nor can 
 there be until much more is known about these animals than is the 
 case at the present time. 
 
 The essential characters of the present genus, so far as known, 
 may be summarized as follows: Head large and broad; palatine 
 bones broadly contiguous; a strong pterygoid ridge on either side; a 
 deep interpterygoid fossa; neck very short; cervical ribs single- 
 headed; cervical ribs and vertebral arches united by persistent 
 suture; no infracentral vascular foramina. 
 
 Many of these characters, possibly the union of the palatines in 
 the median line, are those of Plwsaurus; but Pliosaurus has the 
 anterior cervical ribs double-headed, a character supposed to be of 
 at least family, possibly subordinal value. Of this, however, I am 
 very skeptical, and it is possible that a final classification may locate 
 this genus with the Pliosauridae. 
 
 It is very evident that the elongation of the neck is a specialized 
 character in the plesiosaurs, since we can not conceive of any animal 
 with so many vertebrae in the cervical region from which these animals 
 could be derived. Considering this character alone, Elasmosaurus 
 would be the most specialized of all the plesiosaurs, and Brae ha 11- 
 chetiius the most generalized. It is a question, however, whether such 
 forms as the present have preserved this primitive character from 
 their terrestrial ancestors, with only a slight increase in the number of 
 the cervical Vertebrae, or whether there has been a secondary reduc- 
 tion in the number from some long-necked ancestor. That the long- 
 necked plesiosaurs are not all specialized throughout, is very evident. 
 In the species of PUsiosaurus, a genus of long-necked forms, the 
 epipodial bones are far more generalized in character than are these 
 bones in the short-necked Polycotylus, where the epipodials have 
 become not only broader than long, but have actually increased in 
 number to four. That an increase of the number in the cervical 
 vertebrae is a specialized character has already been affirmed by Baur, 
 Dollo and Fiirbringer in the Dolichosaurs. 
 
 It seems also evident that monocranial ribs are a specialization. 
 
66 Field Columbian Museum — Geology, Vol. II. 
 
 not only in these, but in other aquatic air-breathing vertebrates, such 
 as the cetacea, some ichthyosaurs and the mosasaurs, due to environ- 
 mental causes. It is true that all the Squamata show the same single- 
 headedness of the ribs, brought about by similar conditions — the lack 
 of the necessity of support of the abdominal organs by the ribs in 
 animals resting prone upon the ground, or in a medium of nearly the 
 same specific gravity as the creatures themselves. 
 
 It is a singular fact that, in many plesiosaurs, vestiges of dicran- 
 ial ribs have been retained in the neck, though such have disappeared 
 elsewhere in the vertebral column; and this character has been 
 retained in both the long-necked and the short-necked types, such as 
 Plesiosaurus and P/iosaurus, though utterly wanting in others, such as 
 Elasmosaurus with seventy-two cervicals and the present with only 
 thirteen. Did the long-necked forms become differentiated before 
 the dicranial character was lost, and have they continued as a distinct 
 phyllum until the character was wholly lost? If so, the short-necked 
 Pliosaurs must represent a distinct branch of the order which has also 
 undergone the same change. 
 
 The Cretaceous plesiosaurs of America, so far as known, are all 
 cercidopleural, while many of the European Jurassic forms are 
 dicranopleural. 
 
 This is the fourth species of plesiosaur that I know from the 
 Fort Benton deposits of Kansas; there are none certainly referred to 
 this epoch from other regions, though Brimosaitrus grandis Leidy is 
 probably of this horizon. The only one of these hitherto described 
 is Trinacromcrum bcntonianum Cragin, a long-headed form with long 
 mandibular symphysis and short neck, a form indeed approaching, 
 possibly identical with DolicJiorhynchops. Another form known of 
 which a considerable part of the vertebral column is preserved at the 
 museum of the University of Kansas, is of great size, the dorsal centra 
 measuring five inches or more in diameter, with a very long neck and 
 small anterior cervicals. The specimen is from near Beloit. It 
 represents a distinct species that may provisionally be referred to 
 Cimo/iasirurus or Brimosaurus. A third form is much smaller, about 
 the size of DolicJioriiyncJiops osborni, with short neck. The episternum 
 is shown in Fig. 9 and the cervical vertebrae and humerus in PI. 
 XXVIII. I suspect that it belongs in Trinacromcrum, though smaller 
 than the type species. I have called it provisionally Trinacromcrum 
 anonxmum n. sp. From all these forms the one described may be 
 at once satisfactorily distinguished by the entire absence of infra- 
 central vascular foramina. 
 
Apr. 1903. North American Plesiosaurs — Williston. 67 
 
 That the species described in the foregoing pages belongs in 
 some genus named but not recognizably described from a later epoch 
 is not probable, though possible. I have therefore given the genus 
 the name Brachauchenius. 
 
 POLYCOTYLUS LAT1P1NN1S. 
 
 Paddle. — Some years ago an excellent specimen of a paddle of a 
 plesiosaur belonging in all probability to Polycotylus latipinnis Cope, 
 was collected by Mr. George R. Allman of Wallace, Kansas, from the 
 upper Niobrara chalk of the Smoky Hill river, east of Fort Wallace. 
 The bones of the paddle were, for the most part, found in their 
 natural relations, but were separated in the collection of them. The 
 radius and ulna of a second paddle, together with some of the smaller 
 bones showed weathering, and doubtless had been picked up from the 
 surface. It has required but little trouble to fit into their natural 
 relations all the bones except most of the phalanges, which, present- 
 ing no lateral surfaces for articulation, could only be located from 
 their other characters. A careful study of these, however, makes it 
 probable that the positions assigned to them in the photograph are 
 for the most part correct. Because of the considerable expansion 
 distally of the long bone, the paddle is supposed to be the front one, 
 but it is quite possible it may be a hind one. PI. XXI. 
 
 The head of the humans is large and broad, of a flattened ellip- 
 soidal form, with the surface nearly evenly convex ; it is slightly 
 crushed dorso-ventrally. The tuberosity, placed at a slight distance 
 beyond the plane of the proximal extremity, is massive. It has two, 
 large, flattened, narrowly separated surfaces for muscular attachment, 
 placed nearly at right angle to the longitudinal plane of the bone 
 and separated from the head by a slight groove on either sick-, that of 
 the ulnar side being the more pronounced. On the ulnar side of the 
 tuberosity there is a slight rugosity, as though for muscular attach- 
 ment. The shaft is narrowest near the upper third of the bone, 
 where a cross-section would be nearly circular, or slightly greater in 
 its dorso-ventral diameter. The anterior or radial border is gently 
 convex on its upper two-thirds, gently concave below to the rectan- 
 gular angle. The posterior border is more deeply concave through- 
 out. The distal border has a deep, cupped, thickened facet at right 
 
68 Field Columbian Museum — Geology, Vol. II. 
 
 angles to the dorso-ventral plane, for the radius ; a second shorter 
 and less thick one for the ulna joins this at a small angle ; beyond 
 this, the thinned ulnar expansion is lost in the specimen, but doubt- 
 less had two facets for the third and fourth bones of the epipodial 
 row. On the ventral surface of the bone above, proximad to the 
 middle, there is a large, stout rugosity for muscular attachment. The 
 very strong muscle attached to it doubtless arose from the ventral 
 surface of the coracoid. On the ulnar border of the bone, at its 
 middle, there is a more pronounced, though smaller rugosity, for 
 muscular attachment. The peculiar tooth-like projections on the 
 outer posterior angle of the coracoid described in Dolichorhynchops 
 osborni probably indicates the origin of the muscle inserted into 
 this* rugosity. It may be called the ulnar rugosity. On the 
 radial border, a little beyond its middle, there is a smaller and less 
 strong rugosity Avhich may be called the radial. The origin of the 
 muscle inserted here probably was on the lower part of the scapula. 
 The dorsal surface of the shaft is smooth, without muscular roughen- 
 ing beyond the tuberosity. The distal portion of the bone is much 
 expanded, thickest toward the radial side, and moderately thinned at 
 the distal outer margin. 
 
 Of the four muscular rugosities, which doubtless furnished 
 attachment for nearly all of the muscles controlling the arm, those of 
 the tuberosity are of course the largest, though the large roughening 
 on the ventral side may have been for the insertion of more powerful 
 muscles, which were of course much more effective from the greater 
 mechanical advantage under which they acted. The movement here, 
 though strong, could not have been through a great range. The 
 smallest of all, and placed much further away from the fulcrum is 
 the radial. The great convexity of the head indicates considerable 
 freedom of rotation. The glenoid surface in the articulated skeleton 
 of Dolichorhynchops looks nearly directly outward. The obliquity at 
 which the head of the humerus is placed as regards the horizontal 
 plane, indicates that the natural resting position of the flipper was at 
 about forty-five degrees downward, but I doubt whether the extrem- 
 ities of the paddles could have been raised much, if any, above a 
 horizontal position. It is further certain that the flippers could not 
 have been brought back against the side of the body. The posterior 
 angle of the coracoid, projecting as it does beyond the plane of the 
 glenoid surface, certainly prevented any great backward movement 
 of the humerus. It seems also evident from this position of the cor- 
 acoid, that the paddle was not so pedunculated as restorations usually 
 have them, but that the humerus was largely or entirely hidden in 
 
Apr. 1903. North American Plrsiosaurs — Williston. 69 
 
 folds of the skin, as was, evidently also the case, not only in the ich- 
 thyosaurs, but also in the mosasaurs. 
 
 The largest bone beyond the humerus is the radius. It is 
 irregularly four-sided in shape; the longest and convex proximal sur- 
 face fits into the radial facet of the humerus; the shortest and non- 
 articular border, that adjoining the ulna, is emargiuated like its 
 opposing border to form with it a small foramen. Doubtless these 
 two emarginations represent the last vestige of the terrestrial type of 
 the t pipodial bones. The outer border of the radius, the second in 
 length, is non-articular and thinned, and has an acute angle proxi- 
 mally. The outer distal margin is thick for articulation with the 
 radiale of the carpus. The inner distal border, next to the shortest 
 of the four, is for articulation with the mediale. 
 
 The ulna is next in size to the radius, and is irregularly six-sided. 
 The largest, proximal border, is convex, like that of the radius, and 
 joins the smaller facet of the humerus. The distal border has three 
 facets of nearly equal length, and joining each other in nearly equal 
 angles. These facets are for the mediale externally, the ulnare in the 
 middle, and for the ulnar supernumerary, internally. On the inner 
 side there is a longer, but thinner border for articulation with the first 
 epipodial supernumerary, while the outer border is emarginated like 
 the opposing border of the radius. 
 
 The next bone of this row, articulating with the humerus, and of 
 considerable size, is one of doubtful homology. I will call it the first 
 epipodial supernumerary. If one follows Marsh in his views of these 
 corresponding bones in Ba/>ta>iodo>i, then this bone is the ulna, and 
 the one here called the ulna is the medial carpal. But this inter- 
 pretation is very doubtful. Zittel thinks this bone in the ichthyosaurs 
 is the pisiform, while Woodward calls it the sesamoid; but I doubt 
 these interpretations as well. Among the cetacea, the mosasaurs, 
 ichthyosaurs and plesiosaurs there is a reduplication of bones, which 
 have been variously explained as a splitting of the phalanges, either 
 directly or through the intervention of the epiphyses. The latter 
 view is hardly possible, since there are no epiphysial ossifications in 
 most if not all these reptiles, and besides, there would not be enough 
 epiphyses on the normal digit to furnish the great number of phalanges 
 seen in some of the forms. The extra digits in some ichthyosaurs 
 are also explained by the longitudinal division of the normal phalanges; 
 but I cannot believe that this is the correct explanation. 1 believe 
 that the supernumerary digits, phalanges, epipodial or mesopodial 
 bones found in such species as this, as well as in most other American 
 plesiosaurs, represent entirely new ossifications in cartilaginous 
 
jo Field Columbian Museum — Geology, Vol. II. 
 
 masses, which originally formed the borders or terminations of the 
 adjacent bones. These, in the case of the phalanges, have become 
 separated to increase the mobility of the fingers, have increased in 
 size and ossified, and have in turn given rise to new cartilaginous 
 extremities, that have separated and become ossified; that is, the 
 growth of the additional phalanges and carpals, as well as the two 
 additional bones of the fore arm, was peripheral. The additional 
 fingers of the ichthyosaur may be also explained in a similar way. 
 The margin of the flipper has become hardened by fibro-cartilage, 
 which by the movement of the fingers was broken into segments, each 
 of which finally took on ossification. A division of the phalanges by 
 segmentation would certainly have to take place immediately in order 
 to preserve the integrity of the paddle as an organ of propulsion. If 
 this explanation be correct, then these additional ossifications in the 
 fore arm in the present form, as well as in the carpus, are not dis- 
 placed elements, but new ones, without homologies. 
 
 To return to the description from this digression, the first 
 epipodial supernumerary is irregularly five-sided in shape, for articula- 
 tion with the carpal, ulna, humerus and second epipodial supernu- 
 merary, the longest, inner border, being thinned and non-articular. The 
 second epipodial supernumerary is smaller than the first, and is some- 
 what elongate, articulating distally with the first supernumerary, 
 proximally with the humerus, and with its longest, somewhat convex 
 and thinned internal border non-articulate. 
 
 There are four bones in the first row of the carpus, and the same 
 number in the second, the inner one of which partakes so strongly of 
 the nature of a phalange that it doubtfully can be called a carpal. 
 The first, or radiate, is a thick massive bone, nearly regularly 
 parallelogrammatic in shape, and articulates with four bones. The 
 broad proximal end articulates with the radius; the distal surface with 
 the first distal carpal; nearly the whole length of the inner side joins 
 the medial carpal, leaving a small space at the distal angle for union 
 with the second distal carpal; the outer border is rounded and non- 
 articulate. The second distal carpal is wanting in this specimen, and 
 has been restored. It must, however, have articulated with the 
 radiale and mediale proximally, the first distal carpal externally, 
 the third distal carpal internally, and the second and third metacarpals. 
 A good figure of this bone of the plesiosaur paddle will be found in 
 Leidy, Cretaceous Reptiles, plate iv, ff. 13 and 14. The third distal 
 carpal begins to assume something of the nature of a metacarpal, 
 though a true carpal; it articulates proximally by two unequal facets 
 with the ulnare and medial carpals; externally with the second distal 
 
Apr. 1903. North American Plbsjosaurs Willistok. 71 
 
 carpal: distally with the fourth metacarpal, and internally with the 
 fourth distal carpal by two facets, leaving an emargination between 
 tlum, which, with the opposing surface, forms a foramen. The fourth 
 hone of this row is, I believe, in reality the fifth metacarpal, which 
 has receded proximally to articulate with the hist row: with this inter- 
 pretation there may have been some displacement of the carpals 
 proximally. The bone is elongate, phalange-shaped, articulating 
 proximally with the ulnare, externally by two facets, having an 
 emargination between them, with the third distal carpal. Distally it 
 articulates with a phalange, and on the outer angle with the fourth 
 metacarpal. 
 
 The metacarpals are shorter than the first phalanges of their 
 respective fingers. The first is nearly square, articulating with the 
 first distal carpal, the second metacarpal and its phalange; the outer 
 border is similar to that of the first distal carpal. The second nn ta- 
 carpal is a peculiar bone, easily recognizable in isolated examples: it 
 joins the first metacarpal externally, the phalange distally, the third 
 metacarpal internally by articular surfaces, emar^inated between 
 them, and proximally by two unequal facets, the first and second 
 distal carpals. The third metacarpal is also closely wedged in 
 between the second and third metacarpals, the phalange and second 
 distal carpal. The fourth metacarpal is scarcely distinguishable from 
 a phalange; while the fifth of the row seems to be a phalange. 
 
 Of the phalanges only those of the first and fifth fingers are cer- 
 tainly placed in the figured paddle : the others must have been, in 
 the living animal, very nearly as they are here figured, but the 
 absence of distinct lateral articular facets renders the assumed loca- 
 tions uncertain. The proximal ends of the outer four of the first row 
 arc in nearly the same straight line, but those of the inner fingers 
 become successively less and less elongate, giving an increased 
 'obliquity of the articulations, and more and more definite interlock- 
 ing of the bones. Those of the first and fifth digits are more or less 
 thinned on tin free borders, while those of the intervening fingers 
 have tin sides more or less flattened, with a greater thickness dorso- 
 \ eiitrally than from side to side. The distal bones, however, become 
 more and more flattened from above. They are all gently hour-glass 
 shaped. There are at least ten phalanges in the first finger, fifteen 
 in the second, and perhaps as many as twenty in some of the others. 
 
72 Field Columbian Museum — Geology, Vol. II. 
 
 POLYCOTYLUS ISCHIAD1CUS, N. SP. 
 
 I give this name provisionally to a species from the Niobrara 
 Cretaceous of western Kansas, represented by a number of bones in 
 the University of Kansas Museum, the most characteristic of which 
 are shown in Pis. X and XXVI. There is no assurance what- 
 ever, however, that they belong in this genus ; on the other hand they 
 may belong with the type species, P. latipinnis, or they may belong 
 to some unrecognized genus. The ischia, it is seen, differ very 
 markedly from the corresponding bones of Dolicharhynchops osbornixn 
 the shorter length of the symphysial portion, in the greater breadth of 
 the neck, and in the smaller extent of the cartilaginous rim posteri- 
 orly. The bones are also more massive and the face for the ilium is 
 larger. The ilia also are materially different, in the greater expan- 
 sion proximally, and in the absence of the lateral angular face dis- 
 tally. They have a somewhat curved neck, with a rounded head 
 showing a cartilaginous surface. The transverse processes of the 
 sacral vertebrae are more massive than in that species, with a consid- 
 erable expansion proximally, a cylindrical shaft and a terminal, some- 
 what oblique face for articulation with the ilium. The somewhat 
 compressed sacral vertebra is shown from its ventral surface. 
 
 A specimen from the Niobrara in the Kansas Museum, comprising 
 a number of caudal vertebrae and a portion of the pelvis, I refer with 
 much more assurance to P. latipinriis Cope. The vertebrae differ very 
 materially from the present, and the probability is, therefore, that P. 
 ischiadicus is not a synonym of P. latipinnis. 
 
 PLESIOSAURUS GOULD1I. 
 
 Plesiosaurus ^w/V/VWilliston, Kansas Univ. Quart, vi, p. 57, Jan. 1897. 
 
 Among the material collected in the Lower Cretaceous shales of 
 Clark county, Kansas, by Prof. C. N. Gould, and now preserved in 
 the museum of the University of Kansas, are the remains of at least 
 three different forms of Plesiosaurs, all, however, represented by 
 rather incomplete material. Portions of one of these forms {Pltsio- 
 saurus mudgei (/) Cr.) are figured elsewhere in this paper; another 
 
Apr. 1903. North American Plesiosaurs — Williston. 
 
 73 
 
 was briefly described by me several years ago under the nam. <>t 
 Plesiosaurus gouldii. The species is referred to PUsiosaurus because 
 no better place is known for it ; in all probability it really belongs to 
 some other genus. The species was based upon several dorsal ver- 
 tebrae in fairly good preservation, one of which, the best, is herewith 
 figured. (PI. XXVII.) 
 
 The specimen shows little compression, and its form is doubt- 
 less normal. The anterior face is rather deeply concave, cordatt in 
 outline, with a small neural depression above. The anterior zyga- 
 pophyses are spout-like, the notch between them not extending 
 further than the middle of the articular surfaces. The spine is 
 rather short and small. The transverse processes are compressed, 
 springing in part below the neural canal from the base of the arch. 
 The body is compressed in the middle, forming an obtusely rounded 
 surface below. About midway on the sides, below the lower root of 
 the transverse processes, the side is pinched in, with a small vascular 
 foramen at the bottom of the depression. 
 
 The vertebra described probably belongs near the sacrum, its 
 measurements are as follows: 
 
 Width of anterior end of centrum 
 
 Vertical diameter, same end 
 
 Length of centrum 
 
 Height of vertebra 
 
 Expanse <>f transverse processes 
 
 Width of neural canal 
 
 Expanse of anterior zygapophyses 
 
 no mm. 
 
 75 
 
 79 
 '75 
 175 
 
 30 
 
 50 
 
 PROPODIAL BONES OF YOUNG PLESIOSAURS. 
 
 It is an interesting fact that isolated propodial bones of young 
 plesiosaurs are not at all rare in the Kansas chalk ; no more so indeed 
 than are bones of the adult animals. I have seen more than a score 
 of such, and four or five are now preserved in the museum of the 
 University of Kansas ; there are many others in the Yale museum. 
 Four of these bones are shown in PI. XXIII; a fifth one, more immature 
 than any of those, is figured in PI. XXII, Figs. 1-4. All such 
 bones are composed of more dense tissue than is observed in adult 
 bones. Especially is the structure dense in the youngest specimi n 
 here figured. In this specimen the head of the bone is not at all dif- 
 
74 Field Columbian Museum— Geology, Vol. II. 
 
 ferentiated, nor are there any muscular markings. On the posterior 
 border, near where the ulnar rugosity should be, there are the open- 
 ings of two large canals, one on either side of the margin (/' and c of 
 the figures). On what seems to be the ventral surface, near the 
 front border of the bone and nearly opposite the other openings, 
 there is a large one with its mouth, as in the others, directed distally. 
 On the dorsal surface, and near the middle transversely, there is a 
 fourth opening, much smaller than the others. All of these canals 
 unite near the center of the bone in a rounded cavity or ampulla, as 
 shown in Figs. 3 and 4. In PI. XXIII, Fig. 1, a large opening is seen 
 on the posterior border below a rugose space, and another opening 
 is seen towards the front leading into a groove. This was apparently 
 a canal leading into a groove on the opposite side of the bone in the 
 uninjured specimen, with another opening corresponding to the fora- 
 men which lead into a groove shown in the photograph on the 
 exposed surface of the bone. The bone was, however, injured before 
 I studied.it, as is indicated by the restored border in the figure. 
 The posterior opening probably corresponds to the united b and c of 
 the other figures. In Fig. 2 of this plate is also seen a foramen on 
 the posterior margin of the bone (the left one of the figure). All 
 these three bones are probably humeri. Figs. 4 and 5 of the plate do 
 not show these canals; from their shape they are probably femora. 
 In Fig. 1, PI. XXII, there is seen at the lower margin a groove 
 (e), partly converted into a canal, which probably corresponds to one 
 or the other of the grooves of Fig. 1, PI. XXIII. I believe this 
 groove corresponds to the ectepicondylar groove or foramen of the 
 chelonia, lacertilia, Belodon, Champsosaurus, and some of the notho- 
 saurs and ichthyosaurs. I may add that a similar groove is sometimes 
 indicated in the humerus of the mosasaurs, as shown in PL XLIV, 
 Vol. IV of the University Geological Survey of Kansas. Why these 
 canals and grooves should disappear in the adult humerus is not 
 apparent : they are doubtless for the passage of vessels. The 
 ampulla at the junction of the four canals in the embryonic bone is 
 between the apices of two conical "epiphyses," the larger epiphysis 
 occupying the chief part of the distal portion of the bone, the smaller 
 one the proximal. The fractured specimen discloses these epiphyses 
 with a smooth rounded surface, as shown in PI. XXII, Fig. 3, 
 the outer part peeling away as does the bark from a tree. 
 
 This ephiphysial-like method of ossification has been compared 
 with a somewhat similar structure in the Ghelonians as an evidence of 
 relationship between the two orders of reptiles. 
 
Apr. 1903. North American Plesiosaurs — Williston. 75 
 
 A PECULIAR FOOD HABIT OF. THE PLESIOSAURS. 
 
 More than twenty years ago, Professor B. F. Mudge published, 
 in the First Biennial Report of the Kansas State Board of Agricul- 
 ture (p. 62), the following: "In the Plesiosaurs we found another 
 interesting feature showing an aid to digestion, similar to that of many 
 living reptiles and some birds. This consisted of well-worn siliceous 
 pebbles, from one-fourth to one-half an inch in diameter. They were 
 the more curious, as we never found such pebbles in the chalk or 
 shales of the Niobrara." The specimens which led to this conclusion 
 were collected while I was a member of Professor Mudge's party, and 
 are now preserved in the Yale collection. Nearly ten years ago some 
 plesiosaur bones collected near Ellsworth, Kansas, from the Benton 
 limestone, were sent to the Kansas University museum, together with 
 a lot of siliceous stones, with a request for information concerning 
 both. At the first opportunity 1 visited the locality whence they had 
 been discovered and collected what had been left of the specimen. 
 The bones were in a poor state of preservation, due to the effects of 
 frost, but by carefully digging over the shale in which they occurred 
 we obtained about one hundred and twenty-five of the pebbles, 
 together with several dorsal vertebra.' and ribs. Some of the pebbles 
 were still attached to the ribs by the original matrix, making it cer- 
 tain that their deposition was contemporaneous with that of the skel- 
 eton. The plesiosaur is one of the largest of the order, the dorsal 
 centra measuring five or more inches in diameter. In all probability 
 the species is identical with that mentioned in the preceding pages 
 as coming from the vicinity of Beloit. It is impossible to 
 determine the genus, and the species is yet undescribed. The 
 pebbles vary in weight from less than one gramme to more 
 than one hundred and seventy grammes. The smaller ones were 
 worn into more or less perfect ellipsoids, but the larger ones are 
 more irregular in shape, having suffered less abrasion. It seems 
 probable that the most of the pebbles had been obtained by the 
 animal from the sea beaches bordering the Black Hills, but not a 
 Jew of them, consisting of red quartzite, are quite identical with the 
 quartzite boulders so often found in the drift of eastern Kansas, 
 which have come from the vicinity of Sioux City, Iowa. 
 
 The specimens show conclusively that the pyloric orifice of the 
 plesiosaurs must have been well provided with a sphincter, and that 
 no solid substances passed into the intestinal canal. One need 
 
76 Field Columbian Museum — Geology, Vol. II. 
 
 never expect to find plesiosaur coprolites containing undigested 
 remains of bones or other solid material. 
 
 The nearest place where the animal could have found such 
 pebbles on the sea beaches must have been several hundred miles 
 away from Ellsworth, where the animal finally perished. We may 
 conclude, hence, that the plesiosaurs were roving animals. 
 
 Since the discovery of this specimen two others with siliceous 
 pebbles have been received at the Kansas University museum, one 
 from the Niobrara of Kansas and the other from the Comanche Cre- 
 taceous of Clark County, Kansas (PI. XXIX.) In neither of these 
 cases were the pebbles worn into such regular figures as in the 
 Benton specimen, and all the pebbles were dark in color, none of 
 them quartzite. 
 
 What the use of these pebbles was I will not venture to say. 
 They may have .served as a sort of weight to regulate the specific 
 gravity of the animals, or they may have been swallowed accidentally. 
 If, as I believe probable, the plesiosaurs were in the habit of feeding 
 upon invertebrate animals, seeking such in the shallow muddy 
 bottoms, the pebbles may have been taken with their food uninten- 
 tionally. I doubt this, however. I may add that all specimens do 
 not reveal similar pebbles. In the specimen of Boliekorhynchops 
 osborni, described in the preceding pages, where one would certainly 
 expect to find them, there were none. Possibly it was only the 
 broad-headed and more omnivorous kinds that resorted to this 
 peculiar diet, the long-snouted types being more exclusively fish-eat- 
 ing in habit. 
 
 Crocodiles and seals are said to have similar habits, but I have 
 not learned the reason therefor. 
 
 Many years ago, a similar habit was recorded of the teleosaurs 
 by Geoffroy St. Hilaire, in the Memoires de l'Acad. des Sci. , xxii, p. 
 48, 1833. Of the plesiosaurs, the only recorded notice, other than by 
 myself, that I can find of such habits is the following by Seeley 
 (Quart. Jour. Geol. Soc, xxxiii, 1877, p. 546): 
 
 "In the lower dorsal region of the animal {Muraenosaurus gard- 
 neirt) about a peck of ovate and rounded pebbles occurred, varying in 
 size from a diameter of a quarter of an inch to a length of nearly two 
 inches. They are chiefly of opaque milky quartz, several are of 
 black, metamorphosed slate, and .a few of altered, fine-grained sand- 
 stone and ironstone, some of the pebbles showing a veined character, 
 such as might be derived from the neighboring Paleozoic rocks of the 
 north of France. Pebbles being of such rare occurrence in thcGault, 
 it would seem natural to account for these associated ones by the 
 
Apr. 1903. North American Plesiosaurs — Williston. 77 
 
 hypothesis that they were swallowed by the animal with food, as is 
 the case with several living reptiles and birds. If this view should be 
 Inlcl admissible, it would suggest that, as the teeth were too small 
 for anything but prehension, a structure analogous to a gizzard or the 
 stomach of an edentate, may have used these pebbles to assist in 
 breaking up or crushing the food on which the saurian lived."' 
 

 
Plate I. 
 Skeleton of Dolichorhynchops osborni, as mounted; 1/16 natural size. 
 
» , 'Wf 4KMMk_ 
 
 WtiA'd 
 
Plate II. 
 
 Skull of type specimen of Dolichorhynchops osborni, from the left (reversed). 
 X7/24. 
 

 
 ' 
 
 
Plate III. 
 
 Skull of Dolichorhynchops osborni. X7/24. 
 
 Fig. i, type specimen, from the right. 
 
 Fig. 2, restoration, from the left. 
 
 ang, angular; d, dentary; eo, exoccipital; ep, epipterygoid;/, frontal ;/, jugal; 
 m, maxilla; », nasal; pa, parietal; pet, petrosal; pt, pterygoid; pi, palatine; pm, 
 premaxilla; pf, prefrontal;^?/, postorbital (postfronto-orbital?); q, quadrate; qj, 
 quadratojugal; sc, sclerotic plates; so, supraoccipital; sq, squamosal; sur, surangu- 
 lar; v, vomer. 
 

 
Plate IV. 
 
 Skull of Dolichorhynchops osborni. X i/3« 
 
 Fig. i, from above. 
 
 Fig. 2, from below. 
 
 bo, occipital condyle; en, external nares; ep, ectopterygoid; /, frontal; in, 
 internal nares (the letters are on the anterior end of the palatine); /, jugal, mx, 
 maxilla; pa, parietal; pf, prefrontal; pm, premaxilla; pt, pterygoid; pof, post- 
 orbital; q, quadrate; qj, quadratojugal; sq, squamosal 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. IV. 
 
 Skull of Dolichorhynchops osborni. 
 

 
Plate V. 
 
 Inner side of the left mandible of various reptiles. 
 Fig. i, Sphenodon. 
 Fig. 2, Chelydra. 
 Fig. 3, Alligator. 
 Fig. 4, Varanus. 
 Fig. 5, Cimoliasaurus snowii. 
 
 art, articular; sur, surangular; ang, angular; c, coronoid; Pa, prearticular; 
 sp, splenial; d, dentary; mg, Meckel's groove. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. V. 
 
 Inner Side of the Left Mandible of Various Reptiles. 
 
Plate VI. 
 
 Fourth to eighteenth cervical vertebrae of DolichorhynchoPs osborni, from 
 below. X4/15. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. VI. 
 
 Cervical Vertebra of Dolichorhynchops osborni. 
 

 
 
Plate VII. 
 
 Seventh to fourteenth cervical vertebrae of Dolichorhynchops osborni, from 
 the side. X4/15. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. VII. 
 
 
 ^S 
 
 
 
 W A 
 
 
 ^F'-.yH 
 
 Br *"' *"-Bl 
 
 Br ''j^i 
 
 
 B^- ' 1 
 
 m/ M 
 
 
 r^^^ fl 
 
 ■f 
 
 W* M 
 
 
 k vvj 
 
 
 
 1 M 
 
 
 
 B wSSrS 1 ? 
 
 bK ■' """ n 
 
 I - ■ 
 
 1 — 1 
 
 ■^v^l 
 
 bbbbbS 
 
 H ' JBfl 
 
 
 
 I 
 
 
 ^r^ 
 
 
 Br "^l 
 
 
 Br a 
 
 Jw fra 
 
 
 
 ^^M . j* ^| 
 
 ^^^^^jr kBs 
 
 
 ■ ' ■ Bj 
 
 ^..:^., 1 
 
 Tf^ 1 
 
 B '~BBBb 
 
 Ih^^^VBI 
 
 B ' "■•— -v* ^B 
 
 ■7 "' ^B 
 
 p ^ 
 
 H ""^ 
 
 
 1 -. stt. . M 
 
 be - r **>. 1H95I? 
 
 ■ > J 
 
 1 ' ^ 1 
 
 km 
 
 ■■■> ^ ^bbS3k?& 
 
 bbbK ' ^1& 
 
 bbh v ^^bH 
 
 
 Bkv ' "^ 
 
 L 1 ^^™j 
 
 bbv "-*^^H 
 
 ^B^^-^^bI 
 
 
 Be^^.m^^_^b1 
 
 Cervical Vertebra of Dolichorhynchops osborni. 
 

 
Plate VIM. 
 Median cervical vertebrae of Dolichorhynchops osborni, from the front. X4/15. 
 
flELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. VIII. 
 
 Cervical Vertebr/e of Dolichorhynchops osborni. 
 
I 
 
 
Plate IX. 
 Posterior cervical vertebrae of DolichorhynchoPs osborni, from behind. 4/15. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. IX. 
 
 Cervical Vertebra of Dolichorhynchops osborni 
 

 
 I 
 
Plate X. 
 
 Left series, distal caudal vertebrae of Dolichorhynchops osborni, from above. 
 XI 1/24. 
 
 Right series, cervical vertebrae of Polycotylus ischiadicus, from below. 
 X 1 1/24. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. X. 
 
 Left Series, Caudal Vertebrae of Dolichorhynchops osborni 
 Right Series, Cervical Vertebra of Polycotylus ischiadicus. 
 
Plate XI. 
 Thoracic and abdominal ribs of Dolichorhynchops osborni. X 1/3. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XI. 
 
 Ribs of Dolichorhynchops osborni. 
 
Plate XII. 
 
 Bones of pectoral girdle of Dolichorhynchops osborni. X7/13. 
 Upper left figure, right scapula, from without. 
 Upper right figure, left scapula, from within. 
 Lower left figure, left clavicle, from above. 
 Lower right figure, episternum, from below. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XII. 
 
 Bones of Pectoral Girdle of Dolichorhynchops osborni. 
 

 
 
Plate XIII. 
 
 Bones of pectoral girdle of DolichorhynchoPs osborni, from above. X3/14. 
 
 Upper left figure, left clavicle. 
 
 Upper middle figure, episternum. 
 
 Upper right figure, scapula. 
 
 Lower left figure, right coracoid. 
 
 Lower right figure, humerus. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XIII. 
 
 
 ^^yt^ 
 
 
 
 
 
 
 L<** jB 
 
 ^ 
 
 ^^L 
 
 
 
 
 H v v 
 
 
 
 
 
 WjE^ 
 
 .-5H 
 
 
 
 
 KI* 
 
 ■ 
 
 M 1 - ' ^^H 
 
 
 
 ■k, t 
 
 
 ^H^ ' ^B H 
 
 
 
 1 
 
 ■ 
 
 
 
 
 ■ 
 
 
 ^■^\. V B 
 
 
 
 HI 
 
 ^^^B 
 
 Blv ^fl 
 
 
 
 ■ 
 
 
 
 Pectoral Girdle of Dolichorhynchops osborni, from Above. 
 
Plate XIV. 
 
 Pectoral girdle of Dolichorhynchops osborni. 
 
 Upper figure, left clavicle, scapula and upper extremity of coracoid, articu- 
 lated, from above. X 1/3. 
 
 Lower figures, scapuloclavicular girdle of same, from in front. X 1/4. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XIV. 
 
 Pectoral Girdle of Dolichorhynchops osborni. 
 
Plate XV. 
 
 Complete pectoral girdle of Dolichorhynchops osborni, from below, articu- 
 lated. X 1/4. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XV. 
 
 Pectoral Girdle of Dolichorhynchops osbobni. 
 
Plate XVI. 
 Pubes of DolichorhynchoPs osborni, from above. X3/8. 
 
Plate XVII. 
 
 Right ischium (left figure) and ilium of Dolichorhynchops osborni, visceral 
 surface. X3/8. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XVII. 
 
 is* 
 
 
 f* fl 
 
 
 
 
 
 fj 
 
 
 
 j5|< 
 
 . V 
 
 
 
 
 ^m y 
 
 
 
 
 
 1 r< i 
 
 
 
 
 
 
 
 
 
 
 Ischium and Ilium of Dolichorhynchops osborni. 
 

Plate XVIII. 
 
 Outlines of pectoral and pelvic girdles of different plesiosaurs. 
 Fig. i, pectoral girdle of Cryf>toclidus oxoniensis, after Andrews. 
 Fig. 2, pelvic girdle of same, after Andrews. 
 
 Fig. 3, pelvic girdle of Cimoliasaurus sp, from a photograph furnished by 
 Prof. Fraas. 
 
 Fig. 4, pelvic girdle of Cimoliasaurus trocha?iterius, after Lydekker. 
 
 Fig. 5, pectoral girdle of Plesiosaurus s/>, from photograph from Prof. Fraas, 
 
 Fig. 6, pectoral girdle of Murcenosaurus, after Andrews. 
 
 Fig. 7, pelvic girdle of same, after Andrews. 
 
 Fig. 8, pelvic girdle of same, from the side, after Andrews. 
 
 ic, epistemum; cl, clavicle; sc, scapula; co, coracoid;/«, pubis; is, ischium. 
 
FIELD COLUMBIAN MUSEUM 
 3. 
 
 GEOLOGY, PL. XVIII. 
 
 Pectoral and Pelvic Girdles of Plesiosaurs. 
 

 
 muni .■■ ,(» ;ekfi 
 
Plate XIX. 
 
 Pectoral and pelvic girdles of plesiosaurs. 
 
 Fig. I, pectoral girdle of Plesiosaurus, after Owen. 
 
 Fig. 2, pectoral girdle of Plesiosaurus, after Woodward. 
 
 Fig. 3, pectoral girdle of Plesiosaurus laticeps, after Owen. 
 
 Fig. 4, pectoral girdle of Elasmosaurus platyurus, after Cope. 
 
 Fig. 5, pelvic girdle of same, after Cope. 
 
 ic, episternum; cl, clavicle; so, scapula; co, coracoid ; /», pubis; is, ischium. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XIX. 
 
 Pectoral and Pelvic Girdles of Plesiosaurs. 
 

Plate XX. 
 
 Limbs, as mounted, of Dolichorhynchops osborni, dorsal surface. X1/4. 
 Left figure, right pectoral paddle. 
 Right figure, right pelvic paddle. 
 
FIELD COLUMBIAN MUSEUM 
 
 GEOLOGY, PL. XX. 
 
 Limbs of Dolichorhynchops osborni. 
 
. 
 
 
 
Plate XXI. 
 Right pectoral paddle of Polycotylus latipinnis Cope, palmar surface. Xl/6. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XXI. 
 
 Paddle of Polycotylus latipinnis. 
 

 •I 
 
 iiiuj-iJn-o: 
 
 
Plate XXII. 
 
 Figs. 1-4, propodial bone of young plesiosaur, from Niobrara Cretaceous. 
 
 X3/4- 
 
 Fig. 5, atlanto-axis of Dolichorhynchops osborni, from the side. X3/4. 
 
 ati, atlantal intercentrum; axi, axial intercentrum; n, atlantal neurapophysis; 
 o, odontoid; ;-, pit for reception of axial rib; na, axial neurapophysis; 2, zyga- 
 pophysis. 
 
FIELD COLUMBIAN MUSEUM 
 
 GEOLOGY, PL. XXII. 
 
 Propodial Bone of Young Pleisosaur. Atlanto-axis of Dolichorhynchops osborni. 
 

 
Plate XXIII. 
 
 Propodial bones of young plesiosaurs, from the Niobrara Cretaceous of Kan- 
 sas. X 1/2. 
 
Plate'XXIV. 
 
 Palatal view of type specimen of Brachauchenius lucasi (redrawn from 
 photograph and sketch). X3/25. 
 
 pt, pterygoid; e.p, ectopterygoid; pa, palatine; ps, parasphenoid; v, vomer; 
 bs, basisphenoid. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XXIV. 
 
 Palate of Brachauchenius lucasi. 
 

 
 ■ 
 
 ! im.nl 
 
 
Plate XXV. 
 
 Posterior cervical and dorsal vertebrae, and ribs of Brachauchenius lucasi, 
 from below. Xi/io. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XXV. 
 
 Vertebr/e and Ribs of Brachauchenius lucasi. 
 

 
Plate XXVI. 
 
 Pelvic bones of Polycotylus ischiadicus Willist., visceral surface. X1/3. 
 is, ischium; /'/, ilium; sp, sacral rib; sv, sacral vertebra. 
 

 
 
 
 bfi£ 
 
 
 
Plate XXVII. 
 
 Fig. i, episternum and portion of clavicles of Plesiosaurus mudgei (?) Cragin, 
 from below. X 1/2. 
 
 Fig. 2, dorsal vertebra of Plesiosaurus gouldii (type specimen), from the 
 front. X1/2. 
 
 Fig. 3, the same, from the side. X 1/2. 
 
 Drawn by Sidney Prentice. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XXVII. 
 
 Fig. 1. 
 
 Episternum and Portion of Clavicles of Plesiosaurus mudgei. 
 
 Fig. ?. Fig. 3. 
 
 Dorsal Vertebra of Plesiosaurus gouldii. 
 

 
Plate XXVIII. 
 
 Trinacromerum anonymum Willist. X3/11. 
 
 Upper figures, parts of ilium and coracoid. 
 
 Lower figures, humerus, as restored, and cervical vertebrae. 
 
HELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XXVIII. 
 
 TRINACROMERUM ANONYMUM. 
 

Plate XXIX. 
 " Stomach pebbles," vertebrae and femur of Plesiosaurus mudgei Cragin, reduced. 
 
FIELD COLUMBIAN MUSEUM. 
 
 GEOLOGY, PL. XXIX. 
 
 
 ^ V 
 
 
 : " 
 
 ^ ] 
 
 ; / "^. 
 
 ***i 
 
 !» a 
 
 aP^T^^I 
 
 
 
 ■ c 
 
 Wt^^r VB "* ^^M 
 
 ^ V^^BT' be 
 
 jBbW : IBHH 
 
 B-BBBf * •• 1 -^b! 
 
 &•>*■ 
 
 ■9» ^ " 
 
 29Jf*? 
 
 V 
 
 
 
 
 ■pt m BB Bi 
 
 'Stomach Pebbles" of Flesiosaur.