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 EXT BOOK 
 
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 COPYRIGHT DEPOSrr 
 
Food AND Dietetics 
 
 BY 
 
 ALICE PELOUBET NORTON, M. A. 
 
 ASSISTANT PROFESSOR OF HOMK ECONOMICS 
 
 SCHOOL OF EDLXATION, UNIVERSITY OF CHICAGO 
 
 DIRECTOR OF THE CHAUTAUQUA SCHOOL OF 
 
 DOMESTIC SCIENCE 
 
 CHICAGO 
 
 AMERICAN SCHOOL OF HOME ECONOMICS 
 
 I9IO 
 
/ 
 
 COPYRIGHT, 1904, BY 
 
 AMERICAN SCHOOL OF HOUSEHOLD EO tf»cMIC3 
 
 COPYRIGHT, 1906, 1910, BY 
 
 HOME ECONOMICS ASSOCIATIO\ 
 
 Entered at Stationers Hall, Londou 
 Ai! Rig^his Reserved 
 
 ©CI.A271990 
 
v>: 
 
 CONTENTS 
 
 Letter to Students .... 
 
 V 
 
 The Food Problem . . . . . 
 
 3 
 
 Cost"* OF Food ...<.. 
 
 7 
 
 Food and the Body ..... 
 
 30 
 
 Food Principles ..... 
 
 . 41 
 
 Carbohydrates ...... 
 
 44 
 
 Fats ....... 
 
 . 48 
 
 Dietary Standards . . . . . 
 
 50 
 
 Special Food Stuffs .... 
 
 . 63 
 
 Meat ........ 
 
 66 
 
 Fish 
 
 . 72 
 
 Eggs ........ 
 
 77 
 
 Milk ....... 
 
 . SO 
 
 Milk Products ...... 
 
 92 
 
 Cereals and their Products 
 
 • 98 
 
 Bread . . . . . . 
 
 106 
 
 Sugar as Food .... 
 
 . 113 
 
 Vegetables ....... 
 
 119 
 
 Fruits ....... 
 
 . 130 
 
 Nuts ........ 
 
 136 
 
 Tea, Coffee, and Cocoa 
 
 . 138 
 
 Adulteration of Food . . . . 
 
 . 158 
 
 Special Diet ..... 
 
 • 173 
 
 Bibliography ...... 
 
 181 
 
 Notes on the Questions 
 
 . 191 
 
 New Methods in Diet Calculations 
 
 197 
 
 Protein Metabolism in its Relation to Di 
 
 etary 
 
 Standards — Otto Folin, Ph.D. 
 
 . 224 
 
 Program for Supplemental Study 
 
 244 
 
 Index 
 
 . 250 
 
AMERICAN SCHOOL OF HOME ECONOMICS 
 CHICAGO 
 
 January 1, 1907. 
 
 Dear M&dair.: 
 
 In the study of the lessons on 
 Pood and Dietetics, full use should be made of 
 the mary interesting and valuable publications 
 of the United States Department of Agriculture 
 These are divided into the popular bulletins 
 and pamphlets sent free to all in the United 
 States and the more technical bulletins for 
 which a nominal price is charged. 
 
 The free publications are included chief- 
 ly in the series of Farmers' Bulletins and in 
 Extracts from Year Books, etc. The "for sale" 
 bulletins are issued by the various divisions or 
 the Department of Agriculture, those on food 
 chiefly by the Office of Erperiment Stations 
 and the Division of Chemistry. 
 
 Any or all of the free publications nay 
 be obtained simply by addressing the Department 
 of Agriculture, Washington, D. C. For the "for 
 sale" bulletins coin or money order must be sent 
 to the Superintendent of Documents, Washington, 
 D. C. Postage stamps are not accepted. 
 
 The full list of free and "for sale" pub- 
 lications will be sent on request by the Depart- 
 ment of Agriculture. A fairly complete list of 
 the publication^ on food is given in the bibliog- 
 raphy, but new toulletins are constantly being 
 published. Their ntimbers, titles and contents 
 are given in the monthly list or new publica- 
 tionfl which is sent free on request. 
 
 Bulletins of the various state agricul- 
 tural experiment stations cannot be obtained 
 Irom the U. S. Department of Agriculture, but 
 summaries are given of the more imT)Ortant of 
 
these in the series of Farmers' Bulletins called 
 Experiment Station Work, the contents of which 
 are given in the list of free publications. 
 
 Of the" "for sale" bulletins, two of the 
 Office of Experiment Stations at least should be 
 sent for — No. 28, American Food Materials, which 
 gives the composition of all ordinary foods, 
 price 5 cents, and No. 129, Dietary Studies in 
 Boston, Springfield, Philadelphia and Chicago, 
 price 10 cents,- interesting in corinection with 
 the cost of food. Farmers' Bulletin No. 142, 
 The Nutritive and Economic Value of Food, should 
 be read in connection with Part I. 
 
 The food problem is a large one and al- 
 though nutrition by no means depends entirely 
 upon the composition of the food eaten, knowledge 
 of the character and coirposition of food i& funda- 
 mental in the selection Of a healthful diet. In 
 the last analysis, the food problem must always 
 be an individual one based on conditions and 
 personal peculiarities. 
 
 If difficulties or questions arise in 
 connection with this series of lessons, renember 
 that you are always privileged to write to the 
 School for assistance and advice. 
 
 Sincerely yours, , 
 
 Director 
 
FOOD AND DIETETICS 
 
 T 
 
 HE problems of the household are more difficult problems 
 
 of To-Day 
 
 to-day than they have ever been, for each ad- 
 vance in science, each modern invention, has brought 
 in its train new responsibilities and new duties. In 
 every department of the administration of the home 
 more knowledge and skill are required than ever be- 
 fore. With the increase of conveniences has come 
 increased care. Standards of living have changed as 
 well, and greater perfection in all household service is 
 demanded of the home-maker. 
 
 We still carry on in the household many of the 
 numerous trades that were formerly a part of the home 
 life, as cooking, cleaning, laundry work, sewing. At 
 the same time more close supervision of the life of 
 the children, mental, moral and physical, is required; 
 more knowledge is needed to control materials if we 
 would have that power over our environment which 
 makes us the masters and not the slaves of our belong- 
 ings ; and the social demands upon time and strength 
 can not be ignored. 
 
 If to-day we would lead "the simple life," it must The 
 be as a result of determined effort, often in the face Life' 
 of more or less conscious opposition on the part of 
 relatives and friends and of society in general. 
 
FOOD AND DIETETICS 
 
 Essentials 
 and Non- 
 Essentials 
 
 The Food 
 Problem 
 
 Yet a simpler life is not to be attained by ignoring 
 the results of science, and refusing to apply the knowl- 
 edge made available by the investigator; but rather 
 by making use of every help that will give knowledge 
 of the materials with which we work, that will culti- 
 vate the power to distinguish between the essential and 
 the non-essential, and that will give control of the 
 situation. 
 
 The food problem is perhaps the most difificult of 
 all the physical' problems that present themselves in 
 the household, partly because it is so vital to the wel- 
 fare of the family, and partly because it is so inclusive. 
 The food question once meant the providing some- 
 thing palatable and presumably wholesome at a cost 
 within one's means. To-day it implies, a knowledge 
 not only of the cost and nutritive value of food mate- 
 rials, their composition and digestibility; but of the 
 balanced ration, the proportion of different food prin- 
 ciples necessary for perfect nourishment, and of the 
 way in which this proportion should be varied to suit 
 the needs of the child or of the aged, of the laborer, 
 or of the student. An understanding of the princi- 
 ples involved in the preparation of food is demanded, 
 as well as a knowledge of food adulterations that will 
 insure pure food materials. 
 
 The importance of the question can scarcely be ex- 
 aggerated. Mrs. Ellen H. Richards tells us that "the 
 prosperity of a nation depends upon the health and 
 morals of its citizens; and the health and morals of 
 
THE FOOD PROBLEM 
 
 a people depend mainly upon the food they eat, and 
 the homes they Uve in. Strong- men and women can 
 not be raised on insufficient food ; good tempered, tem- 
 perate, highly moral men can not be expected from a 
 race which eats badly cooked food, irritating- to the di- 
 gestive organs and unsatisfying- to the appetite. 
 Wholesome and palatable food is the first step in good 
 morals, and is conducive to ability in business, skill 
 in trade, and healthy tone in literature." 
 
 It is quite true that we may put food in a wrong 
 position, making it an end rather than a means in 
 living-. We should eat to live, not live to eat. Yet 
 we must keep in mind that right food, clothing and 
 shelter are the primary conditions of health, and that 
 health is essential to the most complete happiness and 
 to the highest usefulness. 
 
 Some one has said that "well dressed men and 
 women, well fed men and women, are still an ethical 
 possibility of the future." However this may be in 
 regard to dress, certainly an age that has devoted so 
 much time and thought to feeding on the stock farm, 
 so nuich attention to the right nutriment for plants, 
 and that has solved so many difficult problems in these 
 directions, should be able to lay down the principles 
 which govern the diet of human beings. 
 
 While the food question then is by no means the 
 one thing in housekeeping as it is apparently so often 
 considered, it yet is of real and vital importance; and 
 the housekeeper who desires to make the most of her 
 
 A Keans 
 to an End 
 
 Importance 
 of the 
 Food 
 Problem 
 
6 FOOD AND DIETETICS 
 
 opportunities to contribute to the extent of her ability 
 to the welfare of her family, should master the prin- 
 ciples of diet so far as they are known, should keep 
 an open mind toward new knowledge, and should 
 apply with discretion and intelligence the knowledge 
 now available in this direction. 
 
THE COST OF FOOD 
 
 The first practical question that will appeal to the 
 housekeeper in regard to food is its cost. Long before 
 she asks what proportion of carbohydrate, of fat, 
 and of proteid she must provide for her family, the 
 question, "What shall I spend for food?" appeals to 
 her, and indeed she is often forced by absolute neces- 
 sity to decide the question. Later, "How shall I 
 spend?" will be the important problem. 
 
 Two main questions are involved. First, What 
 proportion of the family income may go for food ? 
 What is the relation of the expenditure for food to 
 that for rent, for clothing, for travel and amusement, 
 for books and education ? Second, What is the mini- 
 mum cost per individual of food sufficient to give nec- 
 essary nourishment? How much shall this minimum 
 cost be exceeded for the sake of added attractiveness, 
 increased digestibility, or adaptation to individual 
 taste ? 
 
 Nor is the cost of food a question of raw material 
 alone. The amount of waste must be considered, the 
 cost of the fuel used in cooking, and the cost of ser- 
 vice. These often triple the original cost of the food. 
 
 Mr. Atkinson has said that half the cost of life is 
 the price of food. This broad statement is true only 
 in the case of the small income. A fairer interpreta- 
 tion of the matter is given by Dr. Engel, who has 
 formulated four laws that in the main seem to hold, 
 both in ideal and actual budgets. As quoted in The 
 
 Proportion 
 of Income 
 for Food 
 
 Raw Food 
 Only Part 
 of Cost 
 
POOD AND DIETETICS 
 
 DIVISION OF INCOME CHAET 
 Typical Family of Two Adults and Three Children 
 
 Running Expenses include Wages, Fuel, Light, Ice, Etc. With $1,000 
 Income the Children Would be Educated in the Public Schools. 
 
 The above chart was adapted from a large colored 
 chart prepared under the direction of Mrs. E. H. 
 Richards for the Mary Lowell Stone Exhibit on Home 
 Economics. 
 
COST OF FOOD 9 
 
 Cost of Living, the first of these laws is "that the 
 proportion between- expenditure and nutriment grows 
 in geometric progression in an inverse ratio to well- 
 being; in other words, the higher the income, the 
 smaller is the percentage of the cost of subsistence." 
 That is, while clothing, rent, heating and lighting 
 keep a nearly invariable proportion, whatever the in- 
 come, the proportion expended for food varies from 
 sixty per cent in an income of three hundred dollars 
 to twenty-five per cent or less in the three thousand 
 dollar income. 
 
 In discussing the amount of money needed for lood, cost per 
 it is usual to consider the amount expended for each per Day 
 individual per day. How much is necessary to supply 
 the required nourishment depends upon various factors. 
 The locality will be important. As a rule, country 
 prices are lower than those in the city, while in diflfer 
 ent sections of the same city there may be wide vari- 
 ation. Eastern prices diflfer from those of the middle 
 west, and these again from those prevalent in the far 
 west or the south. In institutions where food is pur- 
 chased in large amounts, the cost is less per person 
 than in the individual household. An absolutely defi- 
 nite statement is, therefore, impossible, but a number 
 of experiments have shown that a suflBcient amount of 
 the simplest raw food material may, under favorable 
 circumstances, be furnished for from eight to ten cents 
 a day per person. This implies the absolute exclusion 
 of all but the cheapest materials. Fifteen cents for 
 
FOOD AND DIETETICS 
 
 standards 
 
 True 
 
 Food 
 
 Economy 
 
 Cost of 
 Cooj^ing 
 
 each person means a less limited choice in raw mate- 
 rials, but the most careful management and the strict 
 denial of anything approaching luxury. For twenty- 
 five cents a day, one may add to the dietary a limited 
 amount of fresh fruit and vegetables in season, coffee 
 and other beverages, a fair supply of milk, and may 
 furnish a satisfactory variety of food, while forty cents 
 per person gives an excellent table with added lux- 
 uries, though it will not purchase fruit out of season, 
 such as strawberries in January, nor give an unlimited 
 supply of high priced game and similar delicacies. 
 
 In deciding what one of these standards to adopt, 
 the number of members in the family and the total 
 amount of income must be considered. The typical 
 economic family, on which estimates are made, is one 
 of five members, two adults and three children, or four 
 adults. The real family often has six or eight mem- 
 bers, and this additional number must modify the 
 application of economic theories to real life. 
 
 It is not desirable to cut down the expenditure for 
 food to the lowest point at which nutritive food may 
 be obtained if the income justifies a larger expendi- 
 ture. Economy docs not mean spending a small 
 amount, but expending money in such a zvay that it 
 may bring in the largest return. • 
 
 The cost of cooking modifies the expenditure for 
 raw material. Often a cheap food, requiring long 
 cooking, is in the end more expensive than a higher 
 priced food requiring only a short cooking. This dif- 
 
COST OF FOOD ii 
 
 ference is particularly marked in the case of such a 
 fuel as gas. With a coal stove careful planning for 
 the utilization of all the heat may mean only the differ- 
 ence between the wasting of heat and the using of it. 
 For example, the beans baking in the oven while iron- 
 ing is going on add practically nothing to the amount 
 of fuel used, while the beans baked in the gas oven 
 must have the cost of the gas consumed added to their 
 cost. It is quite possible that a cheap, tough piece 
 of meat might consume so much gas in the long cook- 
 ing necessary to stew it that its cost would be raised 
 nearly to that of the more expensive cut that it sup- 
 planted. 
 
 Another element in the cost of food is that of the Cost of 
 labor consumed in preparation and in service. The 
 time taken to prepare a certain dish must be added to 
 the cost of the raw materials before we can fairly esti- 
 mate the cost of that dish. It must be remembered, 
 however, that a dish requiring long cooking does not 
 necessarily involve the expenditure of much time in 
 preparation. 
 
 In a certain hotel having a large number of guests 
 it was estimated that the extra time required to add 
 a sprig of parsley -to each plate of meat served meant 
 the employment of an additional helper for the equiva- 
 lent of one day a week. In the private family, the 
 difference between a dinner served in three courses, 
 or in four, means an expenditure of additional time 
 that has a definite money value. 
 
12 
 
 FOOD AND DIETETICS 
 
 Waste 
 of Food 
 
 Amount 
 
 Harmony 
 
 Flavor 
 
 The waste of food must also be considered. This 
 is of two kinds, necessary waste, and needless waste. 
 It is foolish to say, as some have done, that the gar- 
 bage can might be eliminated from our houses if 
 greater care were taken. The parings of potatoes, 
 the husks of corn, the pods of peas, must always be 
 refuse. In one experiment it was found that because 
 of the cost of service, it was cheaper to allow thick 
 parings of potatoes to be thrown away than to pay 
 for the care that would insure thin parings. On the 
 other hand, the head of a certain institution found 
 that the careful paring of the potato meant the actual 
 saving of a large number of bushels each year. Mrs. 
 Richards says, "It is not food actually eaten that costs 
 so excessively ; it is that wasted by poor cooking, by 
 excessive quantity and by purchase out of season when 
 the price is out of all proportion to its value. 
 
 "Good judgment as to the amounts to be prepared, 
 as to the harmony of the meal, the blend of flavor ; as 
 to the right appetizers ; and good humor and cheerful 
 conversation, with the most attractive setting and per- 
 fect serving, will cut down the cost of almost any table 
 one-half. Many seem to hold the idea that hospitality 
 requires the setting of a double portion before the 
 guests, and this alone doubles the cost of food in some 
 families." 
 
 She says again, "In no other departmenr of house- 
 hold expenditure is there so great an opportunity for 
 the exercise of knowledge and skill with so good re- 
 
 I 
 
COST OF FOOD 
 
 13 
 
 suits for pocket and health ; no item of expense is so 
 fully under individual control." 
 
 On the other hand, Thudicum, in his Sf^in't of 
 Cookery, refers to "the delusion of economical cookery 
 with scraps costing notliing." He speaks of what is 
 termed "the fearful waste in English kitchens," and 
 says, "When we proceed to investigate the items of 
 the alleged waste, we find them to consist of stale 
 lumps of bread, bacon rind, and bare bones of boiled 
 or roast joints." He quotes with scorn and denial a 
 prominent medical journal which says, "The French 
 cook makes excellent and nutritious soup out of mate- 
 rials which the English housewife throws away as 
 useless ; while her pot-au-feu is composed of stray 
 scraps carefully husbanded, which cost her nothing, 
 but which, when skilfully combined, constitute a use- 
 ful and inexpensive food." 
 
 Perhaps the truth lies between the two extremes. 
 To set an attractive table costs something in raw food 
 material, in equipment and in service. The snowy 
 table cloth, always spotless, so often suggested in nev»'s- 
 paper articles as a substitute for expensive food, 
 means the expenditure of time, money and energy. 
 The soup made from "scraps" involves expenditure 
 of time and fuel, if not of money with which to pur- 
 chase fresh material. *The cost of saving may out- 
 weigh the cost of material saved. But that there is 
 much unnecessary waste in the average household can 
 not be denied. Nor is the mere money value of the 
 
 Economical 
 Coolrery 
 
 True Cost 
 
Alter 
 Cases 
 
 14 FOOD AND DIETETICS 
 
 material wasted the most serious part. The habits 
 of carelessness and extravagance engendered show 
 themselves in a lack of responsibility for material and 
 indifiference toward useless expenditure of time and 
 energy as well as money, and in general thoughtless- 
 ness. 
 Conditions How the money to be expended shall be distributed 
 
 between different food materials must be largely a 
 matter for the individual housekeeper since conditions 
 vary so greatly. As a rule, vegetable foods are 
 cheaper than animal. This may be counter-balanced 
 by the more easy digestibility of the animal food, as 
 we shall see in a later discussion. Whether one food 
 or another is the cheaper source of a particular food 
 principle depends upon the percentage composition and 
 comparative cost of these foods. As is seen in Table 
 I, potatoes at two cents per pound, i. e., 30 cents per 
 peck, cost almost twice as much, so far as actual food 
 value is concerned, as rice at five cents per pound. 
 When rice is ten cents per pound, as it is in many 
 places at present, and potatoes are one cent a pound, 
 conditions are reversed. Sweet potatoes at five cents 
 a pound must be definitely considered as a luxury when 
 white potatoes may be had for one cent at the same 
 place. 
 
COST OF FOOD 
 
 IS 
 
 TABLE I 
 
 Some Important Foods Considered as to Their Nutritive and 
 Economic Values. 
 
 
 .a 
 
 
 si 
 
 a> 
 
 o 
 
 =« P. 
 
 U U Qi 
 
 rt-O p, 
 
 gp. 
 
 Nuts (peanuts, edible por- 
 tion) 
 
 
 9.2 
 
 25.8 
 
 38.6 
 
 24.4 
 100 
 75.1 
 74 6 
 78.5 
 79 
 59.1 
 
 5 
 
 13.7 
 12.9 
 
 3560 
 
 Sugar (granulated) 
 
 
 1857 
 
 Cornmeal (bolted) 
 
 
 13.9 
 
 12.5 
 
 13.7 
 
 12.4 
 
 13.2 
 
 55 
 
 45 
 
 67.1 
 
 87 
 
 44.5 
 
 60 
 
 8.9 
 
 11.3 
 7.1 
 7.8 
 
 22 3 
 
 16 
 
 13 
 1.8 
 3.3 
 .7 
 1 
 
 2.2 
 1.1 
 .9 
 .4 
 1.8 
 1.5 
 4 
 
 .1 
 4 
 .5 
 .9 
 
 1655 
 
 Wheat flour (roller process) . 
 Rye flour 
 
 
 1645 
 1630 
 
 Rice. . . 
 
 
 1630 
 
 Legumes (dried ) 
 
 
 1590 
 
 Meats (as purchased about) . 
 Fish (fresh) 
 
 13 
 30 
 15 
 
 928 
 388 
 
 Potatoes 
 
 325 
 
 Milk 
 
 335 
 
 Bananas 
 
 40 
 25 
 
 390 
 
 Fruit (apples, grapes, etc.) . . 
 
 285 
 
 Wheat flour at 3 cents per pound furnishes 300S calories for 3.6 cents. 
 
 Cornmeal at 3 " " " " " " " 5.4 •' 
 
 Wheat flour at 4 " " " " " " " 7.3 " 
 
 Rice at 5 " " " " " " •' 9.3 " 
 
 Potatoes at 1 " " " " " " " 9 " 
 
 , Legumes at 8 " " " " " " " 15 " 
 
 Milk at 3 " " " " " " " 18 
 
 Potatoes at 3 " " " " " " " I8 •' 
 
 Nuts(kernels)atl6cents " " " " " " 19 " 
 
 Cheese (American pale) at 14 " " " " " 20 " 
 
 Fruit at 3 cents per pound " " " " 31 " 
 
 Milk at 3^ (7 cents a qt.) " " " " 33 " 
 
 Beef (medium fat)at 15 cents (15^ bone) " " " " 47 " 
 
 Beef (sirloin) at 35 cents pe/ pound " " " " 69 " 
 
 Eggs at 25 cents per dozen " " " "115 " 
 
 (From The Cost of Food, by Mrs, Ellen H. Richards.) 
 
i6 FOOD AND DIETETICS 
 
 Finding The most satisfactory way to get at the cost of food 
 
 of Food per individual in a family is to keep careful accounts 
 over a considerable period of time, both of the actual 
 expenditure for food, and of the number of meals 
 served. To make an experiment for a definite time, 
 one month for instance, look over the material on 
 hand, estimating as accurately as possible the amounts 
 of flour, of sugar, of spices, etc. At the end of the 
 month, again take account of stock and estimate the 
 value of the materials on hand. Add the difference 
 if there is less, and subtract the difference if there 
 is more, to the amount expended during the month, 
 and the result will be the cost of the food. 
 
 The following tables are records of actual expendi- 
 ture for food. Table II gives the expenditure in two 
 institutions in an eastern city, where, under the direc- 
 tion of an expert, effort was made to provide a suffi- 
 cient amount of food at the lowest price. 
 
 The left-hand table gives the expenditure for food 
 in a house of correction and the right-hand table for 
 that in an orphans' l-\pme. In this table it will be 
 noticed that one of the largest expenditures was for 
 milk. The cost for food at the officers' table was 
 about the same in both institutions. Provisions were 
 bought at wholesale prices, 
 
 '^A 
 
COST OF FOOD 
 
 It 
 
 TABLE II 
 
 Average Daily Cost of Food Materials per Person in Two Public 
 
 Institutions in Boston. 
 
 
 Inmates 
 
 Officers 
 
 Inmates 
 
 Officers 
 
 Number of Persons Fed 
 
 523 
 Cents 
 4.67 
 
 0.93 
 
 2.23 
 0.46 
 0.36 
 
 0.63 
 
 0.38 
 26 
 0.03 
 0.04 
 
 73 
 Cents 
 23.13 
 1.14 
 0.36 
 3.13 
 3.16 
 0.75 
 0.13 
 0.04 
 0.04 
 0.67 
 0.06 
 0.57 
 0.48 
 0.36 
 0.04 
 
 333 
 
 Cents 
 1.59 
 
 0.16 
 3.75 
 0.07 
 1.88 
 0.37 
 0.13 
 0.04 
 0.29 
 
 0.17 
 0.03 
 
 35 
 Cents 
 19.60 
 
 1 29 
 
 Meat and flsh (fresh or salt) 
 
 Eggs 
 
 Cheese 
 
 20 
 
 Milk. 
 
 5 02 
 
 Butter and Lard 
 
 2 97 
 
 Flour, cornmeal, crackers 
 
 Oatmeal, hominy, rice 
 
 1.19 
 0.35 
 
 Peas, Beans 
 
 11 
 
 Tapioca, sago, cornstarch 
 
 Sugar 
 
 0.08 
 1.27 
 
 Dried fruits 
 
 24 
 
 Potatoes .. .. 
 
 53 
 
 Fresh vegetables 
 
 38 
 
 Apples 
 
 0.11 
 
 Molasses. 
 
 06 
 
 
 
 Cost per day per person 
 
 9.86 
 
 33.85 
 
 8.37 
 
 33.40 
 
 (From Report of Institutions Commissioner of the City of Boston 
 for 1897.) 
 
 Table III is a record from the middle west, and is 
 taken directly from the expense account of three col- 
 lege girls who were trying to keep the cost of living 
 as low as possible. There is no pretense to an ideal 
 diet. Probably it was low in proteid, but the girls 
 lived and apparently thrived upon jt^ 
 
 Experience 
 of College 
 Girls 
 
 .<< 
 
18 
 
 FOOD AND DIETETICS 
 
 TABLE III 
 Weekly Expense Account for Food for Three People. 
 
 Second Week in 
 Navy Beans 
 
 October 
 
 1903. 
 
 .... .25 
 . .. .0.5 
 
 Third Week in 
 Bread 
 
 October 
 
 1903. 
 
 .05 
 
 Grapes 
 
 Bananas 
 
 
 35 
 
 Butterine 
 
 
 .... .20 
 .20 
 
 .15 
 
 Meal, corn 
 
 Raisins 
 
 
 10 
 
 Apples 
 
 Bananas .... 
 
 
 20 
 
 .... .10 
 .10 
 
 Crackers 
 
 Bread 
 
 
 .10 
 
 .10 
 
 Bread 
 
 Cheese 
 
 
 20 
 
 Flour 
 
 
 .10 
 
 Meat. 
 
 
 13 
 
 Crackers 
 
 
 .... .10 
 .25 
 
 Milk 
 
 
 .51 
 
 
 Meat 
 
 Cranberries . 
 
 
 15 
 
 Beef 
 
 
 .... .40 
 
 07 
 
 20 
 
 .13 
 
 .10 
 
 Salt pork. 
 
 Cranberries 
 
 Crackers 
 
 
 10 
 
 .10 
 
 Butter. 
 
 Oleo. . . 
 
 
 .20 
 
 Butter 
 
 
 . . -20 
 05 
 
 Pork 
 
 
 .05 
 
 
 Bread 
 
 
 .10 
 
 Ce'ery 
 
 
 .... .05 
 JS1 
 
 Salt 
 
 
 10 
 
 Milk 
 
 
 
 
 $3.16 
 
 f2.59 
 
 Second Week in 
 Bread. 
 
 April 
 
 191)4. 
 
 .15 
 
 Third Week in April 
 Soda crackers 
 
 nm. 
 
 .10 
 
 Pork, fat 
 
 
 .05 
 
 
 .10 
 
 Radishes 
 
 
 .05 
 
 Can Tomatoes 
 
 10 
 
 
 
 \h 
 
 Ham 
 
 .15 
 
 Grapes 
 
 Crackers . 
 
 
 .20 
 
 10 
 
 .05 
 
 Bi'ead 
 
 05 
 
 Oranges 
 
 .20 
 
 
 Beans 
 
 .05 
 
 Honey 
 
 Beefsteak . . 
 
 
 .12 
 
 .10 
 
 Crackers 
 
 10 
 
 Eggs .... 
 
 .18 
 
 Crackers 
 
 
 .20 
 
 Flour 
 
 .10 
 
 bananas 
 
 
 .08 
 
 Bread 
 
 .05 
 
 Oranges 
 
 
 .10 
 
 Apple butter 
 
 Nuts 
 
 10 
 
 
 
 .05 
 
 .03 
 
 Beef boil 
 
 
 .30 
 
 40 
 
 
 .15 
 
 Potatoes 
 
 Sugar 
 
 Blackberries 
 
 . . .25 
 
 Bread 
 
 
 . .05 
 
 .ao 
 
 Strawberries 
 
 
 .10 
 
 Beans 
 
 05 
 
 Bread 
 
 
 05 
 
 Pork steak 
 
 « .10 
 
 Mnk .. .... 
 
 
 .51 
 
 
 .10 
 
 Apple butter 
 
 
 10 
 
 Hamburg steak 
 
 .15 
 
 
 
 J2.91 
 
 Butter 
 
 .25 
 
 
 Milk 
 
 51 
 
 
 63.07 
 
 Total cost for three people for twentj'-eight days . 
 Average cost for one person for one day, , 
 
 .$11.83 
 0.141 
 
COST OF FOOD 
 
 19 
 
 Table IV shows the expenditure in a summer home 
 in the mountains. In this case no effort was made 
 to reduce expense by excluding articles desired, but 
 true economy was practiced in careful planning of 
 meals and in utilizing all material. 
 
 Liberal 
 Table with 
 High Prices 
 
 TABLE IV 
 
 Expenditure During the Summer of 1903, in a Mountain Town in New 
 
 England, Some Miles from a Railroad. 
 
 
 Lbs. 
 
 Proteid 
 
 Fat 
 
 Carbohyd'te 
 
 Fish 
 
 44 5 
 
 5 9345 
 . 24.3.59 
 .088 
 .0805 
 13.616 
 2.3775 
 1.3.52 
 11.680 
 564 
 8.915 
 
 2.057 
 25 9495 
 
 .022 
 
 .1065 
 49.681 
 
 .3615 
 1.327 
 3.719 
 
 .303 
 3.775 
 
 
 Meats 
 
 83 
 
 4 
 
 3 
 
 343 
 
 38 
 
 16 
 
 151 
 
 87 
 
 2.50 
 
 88 
 
 5 
 1 
 
 16 
 5 
 
 
 Soups 
 
 
 Dried Fruit 
 
 Dairy 
 
 2.6735 
 14 3.54 
 
 Cereals 
 
 Bakeries 
 
 Sugar and starches 
 Fruit 
 
 19.099 
 
 10. 597 
 
 116.717 
 
 11 349 
 
 Vegetables 
 
 36 06 
 
 
 
 
 293 Days (1 person) 
 Each day per pers'n 
 
 1011.64 
 3.45 lbs. 
 
 68.866 
 106 5 grams 
 3.76 oz. 
 
 87.444 
 135.17 grams 
 4.78 oz. 
 
 210.8495 
 326.1 grams 
 11.51 oz. 
 
 Total cost,»$ii4.i4. Cost per day, per person, $0.39. 
 The number of meals served was 878. This is taken as 
 equivalent to 293 days for one person. 
 
 The prices of some of the chief articles of food 
 are given here. 
 
 Beef roast 20 cents per pound 
 
 Beefsteak.. ..28 
 Lamb roast. .18 
 Lamb chops . . 25 
 Veal " ..20 
 
 Chicken .25 
 
 Fowl 20 
 
 Halibut 16 
 
 Salmon 30 cents per pound 
 
 Haddock 6 ' 
 
 Potatoes 20 and 25 cents per peck 
 
 Cream 25 cents per quart 
 
 Milk 5 " 
 
 Butter 38 " " pound 
 
 Eggs. ,,38 and 30 cents perdoaeQ 
 
20 
 
 FOOD AND DIETETICS 
 
 The following tables give in detail the weight and 
 composition of the various food used. 
 
 Fish 
 
 
 Lbs. Prot. 
 
 Fat 
 
 Carb. 
 
 Mackerel 
 
 12% 1 
 4 
 6 
 
 85i 
 2 
 
 1^ 
 2K 
 3 
 2 
 4 
 
 275 
 
 613 
 
 918 
 
 693 
 
 233 
 
 0835 
 
 225 
 
 763 
 
 324 
 
 93 
 
 .525 
 
 .356 
 
 .264 
 
 .0165 
 
 .004 
 
 .003 
 
 .0135 
 
 .009 
 
 .078 
 
 .788 
 
 
 Salmon 
 
 
 Halibut 
 
 
 Haddock 
 
 
 Dressed Cod 
 
 
 Lobster 
 
 
 Blue tish 
 
 
 Cod (salt) 
 
 
 Herring 
 
 
 Sardines 
 
 
 
 
 
 44.5 5 
 
 9345 
 
 2.057 
 
 
 
 
 Meats 
 
 Steak 
 
 Lamb 
 
 Veal 
 
 Chicken 
 
 Pork (salt) 
 
 Ham 
 
 Fowl 
 
 Bacon 
 
 Lard 
 
 SI. Ham.... 
 Pot. Ham.. 
 
 Chicken 
 
 Corn beef . . 
 Dried beef. 
 Tongue, Ox 
 
 Lbs. 
 
 83.88 
 
 Prot. 
 
 3.405 
 
 7.006 
 
 954 
 
 2.984 
 
 .106 
 2.978 
 
 .483 
 4.095 
 
 .192 
 095 
 .128 
 1.052 
 .393 
 .390 
 
 24.259 
 
 Fat 
 
 Carb. 
 
 Soup 
 
 
 Lbs. 
 
 Prot. 
 
 Fat 
 
 Carb. 
 
 Julienne 
 
 1 
 
 .027 
 036 
 .025 
 
 .023 
 
 
 Tomato 
 
 
 Corn 
 
 
 
 
 4 
 
 .088 
 
 .023 
 
 T— .■>€■) 
 
COST OF FOOD 
 
 21 
 
 Dried Fruit 
 
 
 Lbs. 
 
 Prot. 
 
 Fat 
 
 Carb. 
 
 Seed raisins 
 
 3 
 
 'A 
 
 .078 
 .0025 
 
 .099 
 
 ,0075 
 
 .1065 
 
 3.383 
 
 Citron. J 
 
 .3905 
 
 
 3% 
 
 .0805 
 
 3.6735 
 
 Dairy 
 
 
 Lbs. 
 
 Prot. 
 
 Fat 
 
 Carb. 
 
 Eggs.. 
 
 37 6 
 
 240. 
 
 38.5 
 
 3. 
 
 34. 
 
 3.643 
 
 7.920 
 
 .962 
 
 .751 
 
 .34 
 
 3.313 
 
 9.60 
 
 7.033 
 
 .847 
 28.9 
 
 
 120 qts. milk 
 
 13 00 
 
 19'/i qts. cream 
 
 1.732 
 
 Cheese 
 
 .623 
 
 Butter 
 
 
 
 
 
 343.1 
 
 13.616 
 
 49.681 
 
 14.354 
 
 Cereals 
 
 , 
 
 Lbs. 
 
 Prot. 
 
 Fat 
 
 Carb. 
 
 Rice 
 
 454 
 4 
 1 
 1 
 12 
 ■i% 
 2 
 
 .126 
 .484 
 .105 
 .11 
 1.104 
 .390J4 
 .558 
 
 .004^ 
 
 .072 
 
 .014 
 
 .014 
 
 .328 
 
 .021 
 
 .008 
 
 1 098 
 
 Wheat. 
 
 3 008 
 
 Sh. Wheat 
 
 .779 
 
 Farina 
 
 .763 
 
 Corn Meal. 
 
 9 048 
 
 Hominy 
 
 2.765 
 
 RiceFl 
 
 1.638 
 
 
 .28 
 
 2.377/, 
 
 .361^ 
 
 19.099 
 
 BaKeries 
 
 
 Lbs. 
 
 Prot. 
 
 Fat 
 
 Carb. 
 
 U. Biscuits 
 
 2 
 6 
 3 
 1 
 2 
 
 1 
 
 .196 
 .486 
 .130 
 .066 
 .134 
 .334 
 .106 
 
 .183 
 
 .414 
 
 .173 
 
 .140 
 
 .193 
 
 .10 
 
 .137 
 
 1 463 
 
 Bread 
 
 3.253 
 
 Gin. Snaps 
 
 1 .53 
 
 Van. Cr. 
 
 .716 
 
 Mis. Cookies ... 
 
 1.448 
 
 Water Cr. 
 
 1.514 
 
 Saltines ... 
 
 .685 
 
 
 
 
 16 
 
 1 .353 
 
 1.337 
 
 10.. 597 
 
FOOD AND DIETETICS 
 
 Sugars and Starches 
 
 
 Lbs. 
 
 Prot. 
 
 Fat 
 
 Carb. 
 
 2 qts. Molasses 
 
 6 
 40 
 
 8 
 
 1 
 70 
 15 
 
 3 
 
 3 
 3H 
 
 .144 
 
 .403 
 7.70 
 3.07 
 .304 
 .343 
 .008 
 333 
 .588 
 
 .027 
 
 .63 
 
 .385 
 
 .037 
 
 .008 
 
 4.158 
 
 Sugar 
 
 40. 
 
 1 gal. Svrup 
 
 11.016 
 
 Maccaroni. 
 
 3.223 
 
 S. D. Flour 
 
 43.08 
 
 F. M. Flour 
 
 10.785 
 
 Rye Flour 
 
 2.361 
 
 Spaghetti 
 
 1.536 
 
 Honey 
 
 1.624 
 
 Chocolate . . 
 
 1.317 
 1 .535 
 
 .657 
 
 
 .287 
 
 
 
 
 151 i/t; 
 
 11.680 
 
 3.719 
 
 116 717 
 
 Fruit 
 
 
 Lbs. 
 
 Prot. F 
 
 at 
 
 Carb. 
 
 Oranges 
 
 3 
 
 6 
 
 1 
 
 1 
 
 12 
 
 7 
 25 
 
 3 
 
 1 
 
 5 
 
 V2 
 
 4 
 3 
 4 
 1 
 4 
 2 
 
 2 
 
 .034 
 .06 
 .015 
 
 006 
 024 
 
 .348 
 
 
 .510 
 
 Currants 
 
 .128 
 
 
 .017 
 
 .036 .... 
 
 01 
 
 126 
 
 Melons (13) 
 
 ..553 
 
 
 .05 
 
 
 .03 
 
 Apples 
 
 .100 
 .02 
 
 125 
 
 3.. 550 
 
 Plums . 
 
 .403 
 
 Bananas 
 
 .019 
 .017 
 .065 
 .003 
 .016 
 .009 
 .028 
 .003 
 .044 
 .013 
 .014 
 .013 
 
 009 
 
 01 
 
 08 
 
 003 
 
 013 
 
 004 
 003 
 004 
 002 
 002 
 012 
 
 .■?n5 
 
 .55 
 
 
 .126 
 
 Grapes 
 
 .960 
 
 
 .071 
 
 
 .388 
 
 
 .138 
 
 
 .433 
 
 
 .180 
 
 Cherries 
 
 .844 
 
 
 1.690 
 
 
 .216 
 
 
 .108 
 
 
 
 .; 
 
 87 
 
 ..5fit 
 
 11 349 
 
COST OF FOOD 
 
 Vegetables 
 
 Sweet Pot... 
 
 Beets 
 
 Potatoes 
 
 Peas — 
 
 Beans 
 
 Squashes 
 
 Cabbage 
 
 Tomatoes 
 
 Carrots 
 
 Olives 
 
 Mushrooms . 
 
 Baked beans . . . . 
 Asparagus Tips 
 
 Corn 
 
 Split Peas.. 
 
 Di-ied beans 
 
 Lbs. 
 
 Prot. 
 
 Pat 1 
 
 31 
 
 .93 
 
 .656 
 
 30 
 
 .480 
 
 .03 
 
 mA 
 
 3.062 
 
 .26 
 
 29 
 
 2.03 
 
 1.18 
 
 5 
 
 .115 
 
 .15 
 
 2 
 
 .028 
 
 .01 
 
 10 
 
 .160 
 
 .30 
 
 20 
 
 .18 
 
 .08 
 
 2 
 
 .022 
 
 .008 
 
 1 
 
 .008 
 
 .202 
 
 2 
 
 .07 
 
 .008 
 
 20 
 
 1.38 
 
 .800 
 
 10 
 
 .210 
 
 .330 
 
 1 
 
 .031 
 
 .011 
 
 i 
 
 .984 
 
 .04 
 
 1 
 
 .225 
 
 .015 
 4.08 
 
 250.5 
 
 8.915 
 
 Carb. 
 
 13 051 
 
 2.910 
 
 5-430 
 
 4.901 
 
 .370 
 
 .180 
 
 .560 
 
 .780 
 
 .186 
 
 .08 
 
 .136 
 
 3.920 
 
 .220 
 
 .197 
 
 2.480 
 
 .659 
 
 36.060 
 
 As an example of fairly attractive menus with low 
 priced foods, the following" extract from Bulletin No. 
 129 of the Office of Experiment Station, U. S. De- 
 partment of Agriculture, by Miss Bertha M. Terrill, 
 may be of interest : 
 
 "In February, 1902, the students of the Bible Nor- 
 mal College, situated then in Springfield, Mass., voted 
 to save a sum of money,- which they desired to raise 
 for a special object, by reducing the cost of their table 
 board. They had been paying $3 per week for table 
 board at the time, or very nearly 43 cents per person 
 per day, which of course included the cost of fuel, 
 preparation, and service, estimated to be 10.6 cents 
 per person per day. Learning that it has been found 
 possible to provide a balanced and nourishing diet for 
 10 cents per man per day for the raw food, they en- 
 tered eagerly into an experiment with a diet to cost 
 that amount for food materials only, the cost of prep- 
 
 A Typical 
 Investigation 
 
24 FOOD AND DIETETICS 
 
 aration, etc., to remain the same as before, making 
 the total cost of the daily food as served 20.6 cents 
 per person, or 22.4 cents less than their ordinary diet. 
 There were 30 students interested in this project, and 
 it was planned to continue the investigation three days, 
 as this would suffice to save the $20 desired." * * 
 The menus tor the different days covered by the 
 study were as follows: 
 
 SATUBDAT, FEBRUARY 8. 
 
 Break fast.~0?iimeRl and top of milk, fish cakes, toast (with a little 
 butter) , prunes, milk and cereal coffee. 
 
 Dinner.— Beef soup, croutous, beans (baked with pork), brown bread, 
 apricot shortcake. 
 
 Supper.SandwicheH (cheese and jelly), wlilte and graham bread (no 
 butter), sliced bananas, milk. 
 
 SUNDAY, FEBRUARY 9. 
 
 Breakfast.— Corn-menl mtish and top of milk, baked beans, buns, 
 milk and cereal coffee. 
 
 i)inn€r.— Split-pea soup and crackers (crisped), potted beef, brown 
 sauce, baked potatoes, bread, rice with milk and sugar. 
 
 /S'w;;;?^/-.— Bi-own-bread sandwiches (with a little butter), white-bread 
 sandwiches with date and peanut filling without butter, cocoa, popcorn 
 salted. 
 
 MONDAY, FEBRUARY 10. 
 
 Breakfast.— Oa,tmea,l with top of milk, cream toast, cereal coffee. 
 Dinner. — Baked-bean soup, crisp crackers, Hamburg steak balls, 
 brown sauce, hominy, turnip, peanuts and dates. 
 
 Supper.— Fota,to and beet salad, gingerbread, cheese, bread, milk. 
 
 TUESDAY, FEBRUARY 11. 
 
 Breakfast.— Wheat breakfast food and dates, creamed codfish 
 mufi&ns (with little butter) , milk and cereal coffee. 
 
 Dinner.— Beef Stew with biscuits, bread pudding, bread. 
 
 Supper.— Scn.l\o-ped meat and potato, bread (with butter), prunes 
 chocolate candy "fudge." 
 
COST OF FOOD 25 
 
 WEDNESDAY, FEBBUABY 12. 
 
 Jir€akfast.~Oa,tTae?d with top of milk, hash, corn cake, milk and 
 cereal coffee. 
 
 Z>i/i/i.fr.— Vegetable soup, croutons, baked stuffed beef's heai't, brown 
 sauce, rice, cornstarch blanc mange, caramel sauce. 
 
 Supper.— Fotato and celery salad, white and graham bread, fried corn- 
 meal mush, sirup, 
 
 THURSDAY, FEBRUARY 13. 
 
 Breakfast. — Corn-meal mush with top of milk, hashed meat on toast, 
 milk and cereal coffee. 
 
 Z'in.n.e;'.— Salt salm^on, drawn butter sauce, baked potatoes, parsnips, 
 bread, evaporated apple shortcake. 
 
 Supper.—Cold sliced beef's heart, creamed potatoes, cocoa, bread 
 (white and graham), ginger snaps. 
 
 "The family in this experiment consisted of 30 stu- ^j^^ 
 dents — 26 women and 4 men — ranging in age from 25 Family 
 to 45 years. Considering the 4 men as equivalent to 
 5 women as regards food consumption, the family for 
 six days was equivalent to 186 women for one day. 
 
 "The cost of the diet, 9.4 cents per woman per day, cost of 
 was just within the limit set, but the quantities of nu- 
 trients and energy (75 grams of protein and 2,243 
 calories) were somewhat smaller than was intended. 
 
 "The low cost of the diet in this experiment was 
 made possible by the selection of simple and intxpensive 
 food materials and by reducing the quantities of some 
 foods commonly used rather abundantly, as meat and 
 butter. Most of the students felt quite satisfied with the 
 food. The curtailing of the amount of butter served 
 at the table was considered the greatest deprivation; 
 a small pat, about half the customary size, being 
 served to each where butter is indicated with bread on 
 the menu. 
 
 Food 
 
26 
 
 FOOD AND DIETETICS 
 
 Economy 
 
 and 
 
 Nourishment 
 
 Dainty 
 Serving 
 
 "The importance from the standpoint of economy 
 of selecting- foods which are nourishing rather than 
 those having a low food value but which please the 
 palate and add to the attractiveness of the diet, is 
 illustrated by a dietary study made of a family in New 
 Jersey in which it was found that $2.16 was expended 
 in three weeks for oranges and $3 for celery, making a 
 total of $5.16 for these two articles, which together 
 furnished only 150 grams of protein and 6,445 calories 
 of energy. During the same period $5.16 was also 
 expended for cereal foods and sugars, which supplied 
 3,375 grams of protein and 184,185 calories of energy, 
 or about twenty-five times the amount furnished by 
 the oranges and celery. Of course, the sum expended 
 for these articles was not excessive and they undoubt- 
 edly helped to make the diet palatable and pleasing, a 
 by no means unimportant consideration, but it is evi- 
 dent that they were not economical sources of nutri- 
 tive material. 
 
 "In the present investigation it was found to be 
 well worth while to use special care in arranging the 
 dishes for serving, that they might be as appetizing in 
 appearance as possible. Much care was also ob- 
 served in avoiding waste both by careful preparation 
 and by the use of all 'left overs.' " 
 
 In the following table is given the details of cost, 
 weight and nutritive value of the food used in this 
 investigation. 
 
COST OF FOOD 
 Weights and Cost of Food and Nutrients 
 
 27 
 
 Food consumed during the entire 
 ■study (6 day.si. 
 
 Cost, 
 
 nutrients, and fuel value 
 per woman per day. 
 
 Kinds and amounts. 
 
 o 
 o 
 
 4J 
 
 M 
 
 o 
 o 
 
 2| 
 
 
 4'^ 
 
 
 ANIM.^L, FOOD. 
 
 Beef: Hearts, 111b., 38c. ; round, 
 10.5 lb., *1. 05; rump. 101b., 80c. : 
 shank, fore, 3 lb.; brisket 
 (Stew), 7.25 lb., 50c 
 
 Dols. 
 
 2,73 
 
 .60 
 
 .82 
 .33 
 
 2.25 
 .30 
 
 2.70 
 
 Cts. 
 
 1,5 
 
 .3 
 
 .4 
 
 .2 
 
 1.2 
 
 3 
 
 \A 
 
 Gnis. 
 
 15 
 1 
 5 
 
 Gnis. 
 
 19 
 8 
 2 
 
 6 ms. 
 
 Cal- 
 ories. 
 
 329 
 
 Pork: Bacon, 3 lb., 30c.; salt 
 pork. 2 lb., 18c. ; lard, 1 lb., 12c,. 
 
 Fish: Cod, salt, 4 lb., 42c. ; salm- 
 on, salt, 5 lb. , 40c 
 
 Eegs. llb.,33c 
 
 Butter, 9 lb., $2.25 
 
 75 
 
 38 
 
 ...... 
 
 17 
 
 19 
 
 2 
 
 20 
 
 "26 
 
 169 
 
 Cheese, 2 lb., 30c 
 
 22 
 
 Milk, 210 1b., *2.70. 
 
 350 
 
 
 
 Total animal food 
 
 9.73 
 
 5.2 
 
 39 
 
 70 
 
 26 
 
 883 
 
 
 
 
 VEGETABLE FOOD. 
 
 Cereals: Corn meal, 101b., 29c.; 
 pop corn, 1 lb., 5c.; hominy, 
 1.44 lb., 5c.; oatmeal, 4.5 lb., 
 15c. ; rice, 4 lb., 28c.; graham 
 flour, 10 1b., 35c.; white flour. 
 66 lb., jfl.55; crackers, Boston, 
 75 lb., 4c 
 
 2.06 
 1.60 
 
 3.36 
 
 1,07 
 7.69 
 
 1.4 
 .9 
 
 1.3 
 
 .6 
 
 27 
 1 
 
 7 
 
 1 
 
 4 
 1 
 
 1 
 2 
 
 t 
 17H 
 
 51 
 
 41 
 13 
 
 856 
 
 Sugars, starches, etc.: Sugar, 
 granulated, 20 lb., $1 ; mo- 
 lasses, 2. 33 lb., 36c. ; cornstarel,!, 
 0.33 lb., 2c.; cocoa, 1 lb., 17c.; 
 chocolate, 0.121b., 5c. 
 
 329 
 
 Vegetables: Beans, lima, 2 lb., 
 18c.; beans, pea, 2.44 lb.. 10c. ; 
 beets, 1.25 lb., 4c.; cabbage. 5 
 lb., 10c. ; carrots, 1.25 lb., 2c.; 
 celery, 2.061b., 10c. ; par.snips, 
 4.69 lb.. 15c.; peas, split, 1.69 
 lb.. 13c. ; potatoes. 801b., $1.47; 
 turnips, 5.5 lb., 7c. 
 
 201 
 
 Fruits, nuts, etc.: Apricots, 1.5 
 lb., 17c.; bananas, 7 lb., 30c.; 
 dates, 2 lb.. 12c. ; prunes, 2 lb., 
 18c.: raisins, 0.25 lb., 2c.; pea- 
 nuts, 2 lb.. 25c.; crab-apple 
 jelly,0.2 lb., 3c 
 
 74 
 
 
 
 Total vegetable food 
 
 4.3 
 
 36 
 
 8 
 
 386 
 
 1,360 
 
 Total food 
 
 17.42 
 
 9,4 
 
 75 
 
 78 
 
 312 
 
 2.243 
 
28 
 
 FOOD AND DIETETICS 
 
 Chart of Composition of Foods 
 
 Non-nutrients. 
 
 [^22 
 
 Water. Refuse. 
 
 Fiiel valne. 
 Calories. 
 
 Ifutlienta. elc, p. ct. 
 
 Fuel value of 1 Tb. 
 
 20 30 40 50 60 70 80 90 
 400 800 1200 IBOO 2000 2400 2800 3200 3G0O 40.00 
 
 150 
 
 Ojetera 
 
 .xkes 
 
 Beans, dried 
 
 Saga)- 
 
 
 ':ywmm 
 
 'Wlitioatb&ue. 
 
COST OF FOOD 
 
 ■ Chart of Pecuniary Economy of Food 
 
 /Mkut. Rtti Carhohydrates FiulValuJSi 
 
 29 
 
 FOOD MATERIALS 
 
 rrut 
 
 &M»i 
 
 worths. 
 
 a. 
 
 ^.towna 
 
 H 
 
 baf. »x£avn. 
 
 1>i4 . i&}JSau, 
 
 WL 
 
 o^t^iA^UxHy, Cc^ 
 
 e&t'H, CMn/ 
 
 ia^^jaMJaif 
 
 iTinr 1 
 
 ^COMV <V**VO*«^ 
 
 ^djjfA^.J^ua&.AttMJ 
 
 eo^^c&.iiMcS 
 
 0.\jflk4A«, a -ytv^v^urtt? 
 
 , ^itnXe ^fA4x/tXf 
 
 %JOCuy 
 
 ISL 
 
 6aflp . tf u/ivt* .d(K « 
 
 •ns««tXw 
 
 tVtm." 
 
 (3Ut; nvt«£ 
 
 i^<4V»9 . iiO!9^Xt . a^AA.xi 
 
 C^vC< 
 
 eJotakM/O, W*</nt* .fe*votaw 
 
 From Farmers* Bulletin, No. 142, 
 
Composition 
 
 Function 
 of Food 
 
 root) AND THE BODY 
 
 It is impossible to decide intelligently how the money 
 available for food shall be distributed among different 
 food materials without understanding something of the * 
 composition of these food materials, and of the rela- 
 tion of food to the 'needs of the body. Experience has 
 taught us many things, but the accumulation of experi- 
 ence needs interpretation by definite scientific knowl- 
 edge. Until lately this knowledge was in the hands 
 of only a few, and even then in so indefinite a form 
 that it was not available for the housekeeper, no mat- 
 ter how well trained, and hardly for an educated phy- 
 sician. 
 
 Much progress has been made, but even to-day the 
 housekeeper is often a little slow in availing herself 
 of the knowledge she needs. This is partly because 
 of the common feeling that what our fathers and 
 mothers knew is enough for us, and partly because so 
 much of the information is still locked up in more or 
 less technical books, and the ordinary housekeeper, 
 even though she be well educated, has not the key. 
 It is to furnish the key to some of this knowledge 
 that this series of lessons is written. 
 
 We all know in a general way that food nourishes 
 us and makes us strong. But when we try to inter- 
 pret this general idea into specific terms we find that 
 we do not realize its meaning. Nothing is in the strict 
 sense a food unless it performs at least one of three 
 
 30 
 
FOOD AND THE BODY 31 
 
 functions, (i) that of building the body, (2) furnishing 
 heat, and (3) giving power to work. 
 
 The first function of food, that of building the body, Building 
 
 1-1 • 1 M 1 1 Foods 
 
 IS exercised not only in the growing child, where 
 the material that can be transformed into bones and 
 muscles, blood and nerve tissue, must be furnished by 
 food, but in the adult, since even after growth has 
 ceased, the constant waste of the body tissue must be 
 repaired by food. So far as this function is concerned, 
 the composition of the body must determine to a great 
 extent the kind of material that may be used as food. 
 It is easy to see that the body can be built only by 
 foods containing the same elements, and that the pro- 
 portion of these elements must bear some relation to 
 their proportion in the body. It is reasonable to ex- 
 pect that the elements are combined in food in a way 
 similar to that in which they are combined in the 
 body 
 
 The body of a man of average weight has been esti- composition 
 mated to contain the following amounts of the various °^ *^® ^"^^ 
 combinations known as the proximate principles ; 
 
 Water 108 lbs. 
 
 Mineral matter 11.00 
 
 Proteid 29.75 
 
 Fat 5.00 
 
 Carbohydrates f .25 
 
 Total 154.00 
 
 .It will be judged from this that so far as the organic 
 food principles proteid, carbohydrate and fat 'are con- 
 cerned, proteid holds the chief place as a tissue former. 
 
32 
 
 FOOD AND DIETETICS 
 
 Fuel and 
 
 Energy 
 
 Foods 
 
 Not only must the body have its actual material 
 furnished by the food, but from this also must be 
 derived its energy. 
 
 Heat 
 
 Work 
 
 ATWATER'S RESPIRATION CALORIMETER. 
 
 A Man Lives in the "Box" for Days and the Actital Heat and Energy 
 
 Obtained from the Pood Consumed is Determined. (Seepage53.) 
 
 The two forms of energy with which we are espe- 
 cially concerned in our study of the body are heat 
 and power to work. 
 
 Heat is required to maintain the body temperature 
 necessary in order that the processes of life may be 
 carried on. 
 
 The work performed may l)e considered as of two 
 kmds, internal and external. The internal work is 
 that used in maintaining the different functions of 
 
FOOD AND THE BODY 
 
 33 
 
 the body itself. The beating of the heart, breath- 
 ing, the absorption of food, all require the expenditure 
 of energy ; this internal work requires a large portion 
 of the available power. ' As in all machines, energy is 
 lost in the form of radiant heat, but the body 4s con- 
 sidered an efficient machine because a larger propor- 
 tion of energy is available for external work than in 
 most engines constructed by man. 
 
 The amount of energy required for external work is 
 a variable factor, and the work to be done is conse- 
 quently important in determining the amount of food 
 necessary. 
 
 So far as present knowledge goes, we may say that 
 the energy of the body is derived from the oxidation 
 (or combustion) of food that takes place in the tis- 
 sues of the body. The process is undoubtedly a corh- 
 plex one, far from the simple union of the food with 
 the air we breathe, and probably implies the actual 
 building of the food into body substance, but we are 
 concerned chiefly with the final result rather than the 
 process by which it is reached. 
 
 All combustible substamces have what is known as 
 potential energy. This might be defined as stored-up 
 energy. It implies that energy from some exterior 
 source has" been used in producing the substance in 
 its present form. For instance, heat from the sun 
 has been utilized in the formation of the starch or 
 proteid in the plant, and this energy is again set free 
 in the oxidation or the decomposition of the substance. 
 
 External 
 
 Work 
 
 Variable 
 
 Source of 
 Energy 
 
 Potential 
 Energy 
 
34 FOOD AND DIETETICS 
 
 Potential energy may perhaps be most easily under- 
 stood by thinking of one form of it, energy of position. 
 A weight lifted to a height has by virtue of its place 
 a certain amount of potential energy. The fall of the 
 weight from its position will convert its potential 
 energy into active or kinetic energy by which work is 
 accomplished. 
 
 The waste materials of the body have little or no 
 potential energy, and the outgo of the body differs in 
 this important respect from its income. If the foo4 
 taken in is only partially oxidized, the waste material 
 still contains some energy, and this potential energy 
 must be substracted from that of the income in order 
 to find the amount available for the use of the body. 
 Unit of The value of a food to produce heat and mechanical 
 
 Entergy energy is measured by the amount of heat that may be 
 produced by it, and the unit of measure is the calorie. 
 A calorie is the amount of heat required to raise about 
 one pound of water four degrees Fahrenheit, or, 
 accurately, the amount of heat required to raise 
 one kilogram of water one degree centigrade. This 
 is the large calorie, and it is sometimes written with 
 a capital C to distinguish it from the small calorie. 
 The small calorie has a value one-thousandth as great. 
 The term used in this paper means the large calorie. 
 It has been found that there is an exact quantitative 
 relation betwen heat and work, expressed by the term 
 mechanical equivalent of heat. Experiments have 
 shown that about 778 foot-pounds of work are con- 
 
FOOD AND THE BODY 
 
 35 
 
 sumod in heating- one pound of water one degree Fahr- 
 enheit, or 1400 foot-pounds in heating the same amount 
 of water one degree Centigrade. In other words, the 
 same amount of energy would be ex- 
 pended in heating a pound (about one 
 pint) of water one degree Fahrenheit, as 
 in raising a weight of 778 pounds one 
 foot, or a weight of one pound 778 feet. 
 By the same calculations a calorie is 
 equivalent to 3,087 foot-pounds. The 
 calorie then is used as a convenient meas- 
 ure not only of quantity of heat, hut of 
 mechanical energy, or pozver to tvork. 
 
 One g-ram of proteid has been found to The "Bomb" of 
 
 ~ '; a Bomb Cal- 
 
 yield 4.1 calories; a gram of carbo- orimeter. 
 hydrate yields the same amount, while a 
 gram of fat yields 9.3 calories. Or more than twice 
 as much heat can be obtained from a given amount of 
 fat as from the same amount of either proteid or carbo- 
 hydrate. 
 
 The number of calories any particular food will 
 yicl 1 theoretically is determined by the use of the 
 bomlj c?.Iorimeter. A portion of food of a given 
 weight is enclosed in an iron shell or "bomb," which 
 is then immersed in a given amount of water and the 
 temperature of the water taken. By means of an 
 electric spark the contents of the bomb are ignited and 
 burned, and the temperature of the water is again 
 taken at the end of the combustion. For instance, 
 
 Mechanical 
 Equivalent 
 of Heat 
 
 Bomb 
 Calorimeter 
 
36 
 
 FOOD AND DIETETICS 
 
 if the burning of one gram of meat raised the tem- 
 perature of one kilogram (about two pounds) of watel 
 seven degrees Centigrade, that amount of meat would 
 be said to yield seven calories. 
 
 CHART OF HEAT AND ENERGY 
 Values in Calories of some Common Foods 
 
 Coloriee 'r^ I 
 
 MILK 
 
 BUTTER 
 
 CHEESE 
 
 EOGS 
 
 BEEF fe.TjQir, atea}4 
 
 BEEE (TooTidi 
 
 MOTTONf LEG 
 
 FOWL 
 
 COD (boneless salt) 
 
 CODtfrosKl 
 
 OVSTERS 
 
 APPLES 
 
 BANANAS 
 
 SUGAR 
 
 FLOUR G~^l.^e) 
 
 FLOUR fcT^trre wKcse 
 
 BREAD 
 
 CRACKERS 
 
 MACARONI 
 
 CORN MEAU 
 
 RICE 
 
 POTATOES. 
 
 DRIED BEANS" 
 
 DRIED PEAS 
 
 LETTUCE 
 
 ALMONDS 
 
 RAISINS 
 
 CHOCOLATE 
 
 lb -60O I2OO I500 2000 2500 300O 3500 
 
 
 ^^ 
 
 
 ^ggi 
 
 
 
 1^^ 
 
 ■ 
 
 
 ■^ 
 
 
 
 
 
 1 
 
 
 
 ■^^^1 
 
 ■ 
 1 
 
 
 i^i 
 
 
 ^^^ 
 
 a. 
 
 
 
 SI 
 
 SI 
 
 ^ 
 
 S 
 
 ■^ 
 
 
 ■ 
 
 ^^^ 
 
 = 
 
 
 r- 
 
 Digestibility 
 
 The chart given shows the number of calories yield- 
 ed by several different foods. 
 
 There is one factor that is often not sufficiently 
 considered in determining the amount of energy obT" 
 
FOOD AND THE BODY 
 
 27 
 
 tainable from food. A food may yield excellent re- 
 sults in the calorimeter and yet be of little service 
 in the body because of its lack of digestibility. It is 
 
 CHART OF COMPOSITION OF FOODS 
 Percentage of Nutrients of Edible Portion, i. e., Without Bone, etc. 
 
 loy aax 30/^ vy. st>y^ ^ty. toy, aox oox too?g 
 
 MILK 
 
 BUTTER 
 
 CHEESE 
 
 EGGS 
 
 BilEF (sirloin steaK) 
 
 BEEF (round) 
 
 MUTTON LEG 
 
 FOWL 
 
 CODfboneless salt) 
 
 CODCfresH) 
 
 OYSTERS 
 
 APPLES 
 
 BANANAS 
 
 SUGAR 
 
 RLOURfwh,td 
 
 FLOURfentire wheat) 
 
 BREAD 
 
 CRACKERS 
 
 MACARONI 
 
 CORN MEAL 
 
 RICE 
 
 POTATOES 
 
 DRIED BEANS 
 
 DRIED PEAS 
 
 LETT UCE 
 
 ALMONDS 
 
 RAISINS 
 
 CHOCOLA~E 
 
 PROTEID t^-^'"'''i CARBOHYDRATE I 
 F'AT [ril|l||||||| WAT E R [ 
 
 ASH ■ 
 
 by no means the food we eat but the food we'assi>nilate 
 that nourishes us. The portion of food that is really 
 absorbed by the body differs greatly under different 
 conditions and with different food materials. Many 
 
38 
 
 FOOD AND DIETETICS 
 
 Digestibility 
 of Food 
 
 careful experiments have been made of late, and more 
 will be made to determine the amount assimilated in 
 different cases. This element of digestibility is fre- 
 quently not taken into account, and the value of a 
 food is estimated wholly from its chemical composition. 
 
 Some reasons for this are the great difficulty in de- 
 termining the digestibility of a food, the fact that 
 this digestibility may vary from time to time according 
 to the condition of the body, and the fact that the 
 personal equation enters largely into the matter. 
 
 The accompanying tables showing the comparative 
 digestibility of some common foods are therefore 
 merely a general statement, and represent average re- 
 sults. 
 
 Table of Digestibility and Fuel Value per Pound of Nutrients in Dif- 
 ferent Groups of Food Materials. (Atwater.) 
 
 
 Protein. 
 
 Fat. ICarbohydr'ts 
 
 Kind of food. 
 
 Disesti- 
 bility. 
 
 Fuel 
 
 value per 
 
 pound. 
 
 nisestl- 
 lility . 
 
 Fuel 
 value per 
 pound. 
 
 Digesti- 
 bility. 
 
 Fuel 
 value per 
 pound. 
 
 Meats aud ti.sh 
 
 Per 
 cent. 
 
 97 
 97 
 97 
 97 
 85 
 78 
 
 Calories. 
 
 1.940 
 1.980 
 1.940 
 1.940 
 1.7.50 
 1.570 
 
 Per 
 
 cent. 
 
 95 
 95 
 95 
 95 
 90 
 90 
 
 Calories. 
 
 4.040 
 4.090 
 3.990 
 4,0.50 
 3.800 
 3,800 
 
 Per 
 cent. 
 
 98 
 98 
 98 
 98 
 98 
 97 
 98 
 98 
 95 
 90 
 97 
 97 
 
 Calories. 
 1.730 
 
 EgRS 
 
 Dairy prodiTcts,- 
 
 1,730 
 1,7.S0 
 
 Animal food (of mixed diet) . . 
 
 Cereals 
 
 tiegumes (dried) 
 
 1,730 
 1,860 
 1,840 
 
 Sugars 
 
 1,750 
 
 Starches 
 
 
 
 
 
 1,860 
 
 Vegetables . 
 
 83 
 85 
 84 
 92 
 
 i.iio 
 
 1,.520 
 1.840, 
 1.820 
 
 90 
 90 
 90 
 95 
 
 3,800 
 3,800 
 3.800 
 4.0.50 
 
 1,800 
 
 
 1,630 
 
 Vegetable foods (of mix 'd diet) 
 Total food (of mixed diet) .... 
 
 1,830 
 1,8-30 
 
FOOD AND THE BODY 
 
 39 
 
 Table of Comparative Digestibility, Commencing with the Most 
 
 Digestible and Ending with the Least Digestible of Meats 
 
 and Other Common Animal Food, 
 
 Oysters. 
 
 Soft-cooked eggs. 
 
 Sweetbread. 
 
 White fish, boiled or broiled, such 
 
 as bhietlsh, shad, red snapper, 
 
 weakfish, smelt. 
 Chicken, boiled or broiled. 
 Leanroast beef or beefsteak. 
 Eggs, scrambled, omelette. 
 Mutton, roasted or boiled. 
 Squab, partridge. 
 Bacon. 
 Roast fowl, chicken, capon, 
 
 turkey. 
 (From W, Gilman Thompson.) 
 
 Tripe, brains, liver. 
 
 Roast lamb, 
 
 Chops, mutton or lamb 
 
 Corned beef. 
 
 Veal. 
 
 Ham. 
 
 Duck, snipe, venison, rabbit, and 
 
 other game. 
 Salmon, mackerel, herring. 
 Roast goose. 
 Lobsters and crabs. 
 Pork. 
 Smoked, dried, or pickled flsh 
 
 and meats in general. 
 
 It should be noticed that the fuel value obtained in 
 the body from the various classes of foods is somewhat 
 less than the theoretical amount mentioned on page 
 35, because they are not completely digested and as- 
 similated nor completely oxidized, in the body. The 
 following values are used in Ae U. S. Government 
 reports as representing average conditions : ' 
 
 Proteid, fuel value, 4 calories per gram, or 1,820 calories per pound. 
 Fats, fuel value, 8.9 calories per gram, or 4,040 calories per pound. 
 Carbohydrates, fuel value, 4 calories per gram, or 1,820 calories per pound. 
 
 The foods that are particularly useful in furnishing 
 heat and energy for the body, the carbohydrates and 
 fats, are frequently called the fuel foods, although 
 proteid can act as fuel just as readily as can these. 
 Since the proteids, however, have a more important 
 function and are most expensive, the other foods are 
 used as proteid sparers. The amount of these fuel 
 foods that IS to be taken depends not upon the amounts 
 
 Fuel Value 
 in the Bod'< 
 
 Fuel and 
 
 Energy 
 
 Foods 
 
40 FOOD AND DIETETICS 
 
 present in the body, but upon the amount of heat and 
 energy to be produced. 
 The Body The Comparison is frequently made between the 
 An Engine body and an engine, the food representing the fuel, 
 the air taken in through the lungs representing the 
 draft, the waste matters of the body corresponding to 
 the smoke and ashes from the engine fire. In many 
 I ways this is a helpful comparison, but we need to keep 
 in mind the essential differences between the human 
 body and the mechanical engine as well as their like- 
 ness. Combustion in the body is much slower than 
 in the machine, and is therefore not accompanied by 
 light, though by the oxidation of the same amount of 
 fuel the same total amount of heat is produced. Oxi- 
 dation in the body takes place not in one central cavity, 
 but in every tissue, and, most important of all, the' 
 fuel furnished the body probably becomes part o| 
 its own substance before it is oxidized. Moreover if if? 
 is not sufficient in amount- the waste of tissue proceeds 
 faster than its repair, and there is a constant loss of 
 body substance. 
 
FOOD PRINCIPLES . 
 
 In this and other series of lessons we have already 
 discussed the food principles to some extent. Let us 
 consider them now somewhat more in detail. 
 
 PROTEIDS 
 
 The proteids are more difficult to understand than 
 the other food principles hecause different members 
 of the class seem at first sight to have little in com- 
 mon. A few simple experiments that will isolate some 
 typical proteids in a more or less pure state will serve 
 to give a clearer image. 
 
 To a quarter of a cup of flour add very slowly a 
 tablespoon of water and stir it until the flour is com- 
 pletely moistened, then work the dough in the hands 
 until it becomes smooth and elastic, and finally wash 
 it under cold water until fresh water added no longer 
 grows milky. This w'ill take from fifteen to twenty 
 minutes. If a little iodine is at hand add a drop. If 
 no blue color appears the starch is all washed out. 
 There will be left in the hands a sticky, elastic mass, 
 called gluten. Save part of this for comparison with 
 other proteids and bake the rest in a hot oven. 
 
 Add a little acid, such as lemon or vinegar, to some 
 milk, and heat it gently. Wash the curd thus formed 
 in order to separate it from the whey. The curd is 
 chiefly composed of casein. 
 
 With ^a. knife scrape a piece of lean meat until the 
 tender -.muscle fibre is separated from the firm white 
 
 41 
 
 Different 
 Proteids 
 
 Gluten 
 
 Casein 
 
FOOD AND DIETETICS 
 
 Myosin 
 
 Legumin 
 
 Composition 
 of Proteids 
 
 connective tissue. The fibre represents one of the 
 chief proteids of meat, called myosin. Beside the glu- 
 ten, the casein, and the myosin, put the white of an 
 Qgg, and you have before you the four chief represen- 
 tatives of the proteids of our food. 
 
 If we could add to them legumin, the proteid found 
 in peas, beans, and other members of the pulse fam- 
 ily, we should have a fifth important member of the 
 class. 
 
 If we compare these substances, we shall find that 
 although at first they seem very different, they yet 
 have certain properties in common. All, for instance, 
 to a greater or less extent, show the elasticity and 
 tenacity that is so marked in gluten ; all of them are 
 toughened by a high temperature ; and all when dried 
 may be ground to .powder similar in texture and ap- 
 pearance. 
 
 These physical likenesses, however, would hardly 
 be sufficient to place these substances in one group. 
 It is only when we consider the chemical composition 
 of each and the function that each has in the body 
 that we are justified in classing them together as pro- 
 teids. Proteids are substances containing the elements 
 carbon, hydrogen, oxygen, nitrogen, sulphur and fre- 
 quently phosphorus. They alone of the food princi- 
 ples are able to supply nitrogen, one of the essential 
 elements in all living things, whether animal or vege- 
 table, and one that we are forced to obtain from our 
 food, since, although we are surrounded by an atmos- 
 
FOOD PRINCIPLES 
 
 43 
 
 phere that is nearly four-fifths nitrogen, we cannot 
 utihze it in this form. 
 
 Beside the true proteids, there are certain other sub- 
 stances which also contain nitrogen, but which are 
 classed separately because they cannot alone supply 
 the nitrogen needed by the body, though they can re- 
 place part of the proteid in the diet, and perform its 
 function. Gelatin is one of the best known of these 
 substances. They are called gelatinoids or albumin- 
 oids. Ossein, of which bone is largely composed, ker- 
 atin, the horny material present in the hair and in the 
 horns and hoofs of animals, collagen, forming the 
 greater part of the connective tissue of meat, are all 
 representatives of the same class of substances. All 
 these named may be changed into gelatin by boiling. 
 
 Certain other nitrogenous substances called extrac- 
 tives, are present in some foods. These may help give 
 the flavor to meat. They form the chief ingredient of 
 the extracts of beef on the market; and it is these 
 that give the chief value to beef tea and to clear soup. 
 The extractives act as stimulants rather than as true 
 foods since they neither build tissue nor act as fuel, 
 but they seem to play some role in digestion. 
 
 The proteids, gelatinoids, and extractives, are 
 sometimes classed together under the general name 
 of protein. This is the usage of the United States 
 Government pamphlets. The nomenclature applied 
 to the nitrogenous substances is very confusing, since 
 each author seems to have adopted his own. Albumi- 
 
 Gelatln 
 
 Extractives 
 
 Nomen- 
 clature 
 
44 
 
 FOOD AND DIETETICS 
 
 noid, for instance, is sometimes used to designate the 
 true proteids, and sometimes is applied to the gelatin- 
 oids. Proteid is sometimes used in a much more Hm- 
 ited sense than we have given to it, including only 
 certain classes of the substances ordinarily designated 
 by the term. 
 
 In studying the subject, therefore, one must first 
 of all ascertain the writer's use of terms. 
 
 CAEBOHYDRATES 
 
 Composition The carbohydrates are so 
 
 called because they arc 
 composed of the elements 
 carbon, hydrogen and oxy- 
 gen, the last two in the pro- 
 portion in which they are 
 found in water. This last 
 statement, although it is 
 generally made in defining 
 carbohydrates, is not strict- 
 ly true, since a few of the 
 less common members of 
 the class are found to vary 
 somewhat from this pro- 
 portion'. 
 The principal carbohydrates may be classed in three 
 groups. The following table shows the chief "Mem- 
 bers of these different groups, so far as our food is 
 concerned. 
 
 Grains of Potato Starch. 
 
rOOD PRINCIPLES 
 Classification of Carbohydrates 
 
 4S 
 
 ^tarch {or Amylose) 
 Group. 
 
 C. H.„ 0,„ 
 Starch 
 Dextrin 
 Cellulose 
 Gums 
 Glycogen 
 
 Cane Sugar (or Sucrose) \ Grape Sugar (or Glucose) 
 Group. i Group. 
 
 „ , Grape Sugar 
 
 Malt Sugar (Maltose) I (Dextrose) 
 
 Milk Sugar (Lactose) | Fruit Sugar (Levulose) 
 
 C,2 H.,.. O,, 
 Cane Sugar (Sucrose) | 
 
 That the second and third groups bear a definite 
 
 Qi^^ o 
 
 Corn Starch. Rice Starch. 
 
 (From Hygiene, by Parks.) 
 
 chemical relation to the first may be seen by a com- 
 parison of their formulae. 
 
 Starch is the most important of the carbohydrates 
 from the standpoint of food. It is familiar to us all 
 as the fine, white, glistening powder of "corn starch" 
 and of laundry starch. We ma}' easily, by washing it, 
 obtain it also from grated potatoes and from flour. 
 Starch is found only in the vegetable kingdom, and 
 is" manufactured b3' green plants and stored in differ- 
 ent parts of the plant in the form of tiny grains lying 
 within the plant cells. 
 
 starch 
 
46 
 
 FOOD AND DIETETICS 
 
 structure 
 of Starch 
 
 Starch Grains 
 
 The Structure of these grains has been very hard 
 to determine because of their minuteness. It was 
 thought for a long time that 
 thfey were composed of a celki- 
 lose envelope enclosing the true 
 starch, and that by the action 
 of water and heat these grains 
 swelled and the cellulose en- 
 velope burst. 
 
 A later theory was that the 
 starch grain was built up in 
 alternate layers of starch cellu- 
 lose and starch granulose. 
 
 The late work of a German 
 botanist, Meyer, seems to show 
 that the grains are in the form 
 of sphero-crystals, each made 
 up of many tiny particles. These 
 radiate from a center, and at the same time are arranged 
 in concentric layers. The particles are of two kinds 
 called by Meyer alpha-amylose and beta-amylose. 
 These may be compared to the starch cellulose and 
 starch granulose of the older theory. Upon the appli- 
 cation of heat and moisture the beta-amylose swells 
 and becomes gelatinous, forming a solution. The 
 alpha-amylose is affected only by a temperature much 
 above the boiling point, or by long continued heating. 
 The starch grains in different plants differ much 
 in form, size and general appearance, as shown in the 
 
 Bean Starch. 
 
rOOD PRINCIPLES 
 
 A7 
 
 illustrations. The relation of the difference in struc- 
 ture to digestibility is not well determined. 
 
 Dextrin is a substance having the same general 
 Composition as starch, but unlike it in some of its 
 properties. It is chiefly important to us in that it is 
 an intermediate product of the change of starch into 
 sugar. 
 
 Glycogen is the form in which carbohydrate is 
 stored in the bodv until it is needed for use. It is 
 
 Dextrin 
 
 Diasiaiu Representing the Supposed Structure of a Sphero-Crystal of 
 
 Starch, Showing Radial and Concentric Arrangement. 
 
 From A. Meyer. 
 
 found chiefly in the liver and is sometimes called ani- 
 mal starch. 
 
 Cellulose is so slightly digested that we do not put 
 it in the list of human foods, yet it is important from 
 two standpoints. First, it gives the necessary, bulk 
 to food ; and second, it so encloses the nutrients in 
 vegetables and fruits that it must be definitel}- con- 
 §idgred in cookery, 
 
 Cellulose 
 
48 
 
 FOOD AND DIETETICS 
 
 Composition 
 
 Water and 
 Mineral 
 Matter 
 
 Nutrient 
 Katio 
 
 Allied to the gums are the pectose and pectin that 
 are concerned in the making of jelly from fruit juice. 
 The gelatinous substance obtained from Irish moss 
 also belongs in this class. The sugars will be dis- 
 cussed under the special foods. 
 
 FATS 
 
 The fats, like the carboh_\drates, are composed of 
 carbon, hydrogen and oxygen, but with these elements 
 in very different proportions from that in which they 
 exist in the carbohydrates. There is a much larger 
 proportion of carbon with less oxygen than in starch 
 and sugar, and this accounts for the readiness with 
 which they burn and the intense heat that we get from 
 them. They are of both animal and vegetable origin. 
 Those which are liquid at ordinary temperature we 
 often speak of as oils. 
 
 In discussing the value of' a food we commonly con- 
 sider only the organic principles. Although water is 
 absolutely necessary it is so easily supplied and so 
 abundant that we do not have to consider whether or 
 not it is present in our food as we purchase it. This 
 is not true of mineral matter to so great an extent, but 
 it is largely so, except in the case of growing children. 
 The mineral matter will, as a rule, take care of itself if 
 we provide the other substances needed. 
 
 By food value or nutritive value we ordinarily mean 
 the amount of organic nutrients present in the foodo 
 In determining the importance of any particular food, 
 we consider not only the total amount of the nutrients 
 
of Foods 
 
 FOOD PRINCIPLES " 49 
 
 present, but the relation that the proteid bears to the 
 other nutrients. This is often called the nutrient ratio. 
 The nutrient ratio of potatoes, for example, containing 
 two per cent of proteid and eighteen of starch, is i 
 to 9. In reckoning this ratio, fat is changed into its 
 starch equivalent, that is, one part of fat is considered 
 equal to two and a quarter of starch. 
 
 The following classification of the food principles classification 
 may help to fix in the mind their relationship. 
 
 Nutritive Ingredients (or Nutrients) of Food 
 
 r I Proteids, e.g., albumin, casein. gluten, etc. 
 
 I Nitrogenous < Gelatinoids, e.g., gelatine, etc. 
 
 Organic. -j (Extractives. 
 
 [Non-nitrogeneous-} Carbohydrates, e.g., sugar, starch. 
 
 inorganic, j^^^-^r^al matters. 
 
 Use of Food Principles in the Body 
 
 Proteid Forms tissue. \ 
 
 eg , white (albumen) " \ 
 
 of eggs, curd (casein) I All serve as 
 
 of milk, lean meat, / fuel to yield 
 
 gluten of wheat, etc. I energy in the 
 
 Fats Are used or stored as fat / forms of heat 
 
 e.g., fat of meat, but- \ and muscu- 
 
 ter, olive oil, oils of I iar power 
 
 corn and wheat, etc. / 
 
 Carbohydrates Are used or transformed into fat. / 
 
 e.g., sugar, starch. etc. 
 
 Mineral matters (ash) . . Share in forming bone, assist in digestion, etc. 
 e.g., phosphates of 
 lime, potash, soda, 
 etc. 
 
Amount 
 
 of Food 
 
 Required 
 
 Food for 
 
 Different 
 
 Ages 
 
 DIETARY STANDARDS 
 
 In addition to a knowledge of food constituents, 
 of the proportion of which these exist in our food, and 
 of the use of food in the body, we need to know the 
 amount of food necessary to supply our daily needs 
 under different conditions. Many factors will influ- 
 ence not only the total amount of food that we need, 
 but also the proportions in which we shall use the pro- 
 teids, the carbohydrates and the fats. The flesh weight 
 of the body is important in deciding the amount of 
 proteid (that is, the muscle weight, not the total 
 weight of the body) since the greater the flesh weight 
 the greater the nitrogenous waste. The shape of the 
 person, whether tall or thin, or short and plump, in- 
 fluences the amount of fuel food required, since the 
 amount of surface exposed affects the loss of heat. 
 The degree of activity has an important influence upon 
 the amount of all the food principles. Variations in 
 climate to a certain extent affect the amount of heat 
 to be produced in the body, and occupation also has 
 an important influence. 
 
 The age of the individual is, within certain limits, 
 one of the greatest factors. The growing child needs 
 a large amount of building material, while the old 
 person needs distinctly to lessen the tissue building 
 foods. The accompanying diagram gives an idea of 
 the way in which these proportions vary with different 
 ages. It will be seen that the proportion of proteid is 
 jpuch greater in comparison with other food materials 
 
DIETARY STANDARDS 51 
 
 in the case of the child than of the adult. The total 
 amount of food is also greater in proportion to body- 
 weight in the child than in the adult. Although not 
 shown in the table, mineral salts are needed in large 
 proportion in the child's diet, while they may well be 
 cut down in the diet of the old. The amount of food 
 needed increases rapidly from birth to about four 
 
 Y«»r5 of 
 • a ' 
 
 Age 
 
 ? '0 ? 
 
 » . 
 
 . ; 
 
 . , 
 
 J 5S « 
 
 „ 
 
 
 e 
 
 !J 56 to < 
 
 • « 
 
 • 1 
 
 J It,- «« 
 
 •3«0 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 •* 4 ft 
 
 
 
 
 
 
 / 
 
 \ 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 / 
 
 
 V 
 
 i>>^ 
 
 
 
 
 
 
 
 
 
 
 
 
 g 
 
 
 
 
 
 y 
 
 
 
 
 
 
 ~~~ 
 
 ■^^N 
 
 -'■I 
 
 
 
 
 
 
 
 
 * 3«0 
 
 
 
 
 
 / 
 
 
 
 
 
 
 
 
 
 <i3 
 
 t""' 
 
 
 
 
 
 
 
 
 
 
 
 / 
 
 
 
 
 
 
 
 
 
 
 
 "->, 
 
 
 
 
 
 
 
 
 
 / 
 
 
 
 
 
 
 
 
 
 
 
 
 
 "^ 
 
 ■^ 
 
 
 
 ^ 5 C- 
 
 E SCO 
 
 
 
 
 / 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 s 
 
 
 E 
 
 
 
 / 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 k " 
 
 U 
 
 
 
 / 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 X 
 
 ^ 
 
 
 
 — 
 
 
 
 .P-al 
 
 ^ 
 
 Zip 
 
 
 
 
 
 
 
 
 .0 
 
 
 
 .— ^ 
 
 
 „^ 
 
 ■ — ' 
 
 
 ■^ 
 
 
 
 ■ 
 
 
 — ■ 
 
 
 — . 
 
 ^ 
 
 
 ' 
 
 
 
 —— 
 
 
 
 
 
 
 
 
 
 
 
 
 — ■ 
 
 
 ...^ 
 
 
 ■"*" 
 
 •-•i 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 "^ 
 
 ' — 
 
 i* U 9a 30 
 
 Years oF Age. 
 
 Diagram Showing the Varying Amounts of Food Principles Required 
 at Different Ages. 
 
 years of age, very slowly from four to about ten, with 
 a rapid increase from this time to twenty-four. From 
 ten to twenty-four the carbohydrates should increase 
 in amount more rapidly than the other food principles. 
 To put in terms of the nutrient ratio the difference 
 between the diet of the child and that of the adult — 
 in the adult diet the ratio is about 1 15.3 ; in the diet o£ 
 ^he child, I \^.\, 
 
 Nutrient 
 Ratio 
 
5^ 
 
 FOOD AND DIETETICS 
 
 standard 
 Dietaries 
 
 Experimental 
 Dietaries 
 
 These statements are of course true only approxi- 
 mately, yet one familiar with children must recognize 
 in them a fair generalization from the facts. 
 
 The proportions of the different food principles 
 needed daily constitute the dietary, and dietary stand- 
 ards have been made up taking into account as far as 
 possible these different conditions. These dietaries 
 are sometimes called experimental, and sometimes sta- 
 tistical, according to the method used in formulating 
 them. An experimental dietary is the result of care- 
 ful observations of the effect of different proportions 
 of food nutrients upon an individual under determined 
 conditions. The statistical dietary is the outcome of 
 the study of the actual ration of large numbers of peo- 
 ple. Each of these has its drawbacks. In the first 
 case it is difificult to decide how far the result is due 
 to individual idiosyncrasy, and a large number of ex- 
 periments must be tried before the personal factor 
 can be eliminated. In the second case it is hard to 
 determine whether some variation in the diet might not 
 produce 'better results. 
 
 An example of the first method of formulating die- 
 taries is that of Professor Atwater's respiration calori- 
 meter, sometimes called "the man in a box," described 
 in one of the government pamphlets. A small room 
 was constructed in the laboratory with flues arranged 
 to bring in fresh air and to carry off the products of 
 respiration. Each of these flues was arranged so that 
 
 the temperature and composition of the air entering 
 
DIETARY STANDARDS 53 
 
 and going out might be determined.* A man lived in 
 this room for several days at a time, his food being 
 given to him by means of slides in a double wall. A 
 sample of each food given was analyzed and a determi- 
 nation of the number of calories yielded by it made by 
 means of the bomb calorimeter. All food taken was 
 carefully weighed, and the excreta of the body were 
 analyzed so that an accurate estimate could be made 
 of the total income and outgo of the body. See illus- 
 tration on page 32. . 
 
 Many statistical dietaries have been taken, some of statistical 
 -the most valuable being those of the German army. 
 Experiments have been made there as to the effect of 
 the addition of certain articles of food to the diet, and 
 the conclusions have been of much value. Similar 
 dietary studies have been made at many schools and 
 universities. 
 
 From a careful comparison of dietaries made up 
 in these two ways certain standards have been deter- 
 mined upon. The American standards vary in some 
 important points, notably in the amount of fat used, 
 from those of Europe. Some of these dietaries are 
 given here. 
 
 Dietaries 
 
54 
 
 FOOD AND DIETETICS 
 
 standard Dietaries 
 
 Voit 
 Woman at moderate work (German) . . . . 
 
 Man at moderate work (German) 
 
 Man at hard work (German) 
 
 Playfair. 
 Man with moderate exercise (English) . . 
 
 Active laborer (English) 
 
 Hard-worked laborer (English) 
 
 Atwaier. 
 Woman with light exercise (American) . 
 
 Man with light exercise (American) 
 
 Man at moderate work (American) 
 
 Man at hard work (American) 
 
 2r. 
 
 ai 
 
 28 
 
 
 1 O eS 
 
 ^ t« 
 
 
 
 IFLhO 
 
 fees 
 
 93 
 
 44 
 
 118 
 
 56 
 
 H5 
 
 100 
 
 119 
 
 51 
 
 156 
 
 71 
 
 185 
 
 71 
 
 80 
 
 80 
 
 100 
 
 100 
 
 125 
 
 125 
 
 150 
 
 150 
 
 'ts 
 
 400 
 500 
 450 
 
 "3 3 g 
 
 O !- 03 
 
 H a I o 
 
 536 I 2425 
 674 I 3055 
 G05 I 3370 
 
 2300 
 2815 
 3520 
 4060 
 
 531 
 
 701 1 
 
 568 
 
 795 1 
 
 568 
 
 834 
 
 300 
 
 460 
 
 360 
 
 560 
 
 450 
 
 700 
 
 500 
 
 800 
 
 Chittenden's 
 Experiments 
 
 There are twenty-eight and thirty-four hundredths 
 grams (28.34) in one ounce. A man at moderate 
 work requires, therefore, according to the American 
 standard, about four and one-half ounces of proteid, 
 four and one-half ounces of fat, and nearly a pound 
 of carbohydrate daily. 
 
 The dietary standards that we have been considering 
 are those that have been accepted generally since work 
 of this kind was first begun. Some late experiments 
 conducted at Yale University by Professor Chittenden 
 and others, indicate that a much smaller amount of 
 food, especially of proteid, may better serve the pur- 
 poses of the body, than the larger amounts indicated 
 in these standards. The experiments were carried out 
 upon men representing three different classes of in- 
 diyi(hials, The first class was composed chiefly of 
 
DIETARY STANDARDS 
 
 55 
 
 professors and instructors. The second represented 
 the moderate worker. The third class were trained 
 athletes. The experiments covered a period of five 
 months, and the proteid taken daily varied from about 
 thirty-five to fifty grams per day, while the total num- 
 ber of calories yielded was from twenty-five to twenty- 
 eight hundred a day. The general conclusion drawn 
 from these experiments is that under ordinary condi- 
 tions of life, with an ordinary amount of work, bodily, 
 health and vigor are maintained as well, if not better, 
 on a minimum proteid diet than on the amount given 
 in the generally accepted standards. 
 
 Some careful experiments and analyses recently 
 made by the physiological chemist. Dr. Otto Folin, at 
 the McLean Hospital, Waverly, Mass., indicate that 
 about twenty grams of proteid represents the actual 
 daily proteid wastes of an average sized man under 
 ordinary conditions. That is, only about three-fourths 
 of an ounce of proteid material is necessary per day in 
 an adult to rebuild the nitrogenous tissue of the bodv 
 that wears away through use.* 
 
 Such radical differences from standards found bv 
 long experience to give good results in health and 
 strength must be considered very carefully before be- 
 ing accepted. But in this as in many other ways, we 
 may be obliged to revolutionize our ideas of food. 
 
 We must not fail to distinguish between the amount 
 of proteid required and the amount of food containing 
 proteid. If, for example, meat be supplied containing 
 
 *See Report of the Lake Placid Conference on Home Economics, 1905, 
 and .\merican Journal of Physiology, March, 1905. 
 
 Dr, Folin's 
 Experiments 
 
 Amount 
 of Food 
 to Furnish 
 Required 
 Proteid 
 
56 
 
 FOOD AND DIETETICS 
 
 Example for 
 Practice 
 
 Calculations 
 
 Balanced 
 Batlon 
 
 i8 per cent of proteid (a fair average), a little more 
 than a pound and a half of the meat will be required 
 to furnish the four and a half ounces of proteid. 
 Bread containing 9 per cent of proteid would be re- 
 quired to the amount of three pounds. Nearly two 
 pounds and a quarter of eggs, with 13.1 per cent of 
 proteid, or about eighteen eggs, would be necessary 
 to supply four and a half ounces of pure proteid. 
 
 Taking the percentage composition from the accom- 
 panying table, calculate the amount of milk that would 
 be required daily to furnish four and a half ounces 
 proteid. How much potato would be required ? How 
 much corn meal? 
 
 Calculations: From the table, milk is found to con- 
 tain 3.3% of proteid or i oz. contains .033 oz. protein. 
 To furnish 4.5 ozs. would require 
 
 4-5 -^ -033 = 136+ 
 As a pound contains 16 ozs., 136 oz.=8^ lbs. A pint 
 of milk weighs about i lb., so about 4>4 quarts would 
 be required to provide 4.5 ozs. of proteid. 
 Potatoes as purchased contain 1.8% proteid. 
 4.5 ^ .018 = 250 
 250 oz. ^ 15 lbs. (aprox.) 
 A bushel of potatoes weighs about 60 lbs., conse- 
 quently about one peck of potatoes would be required. 
 Corn meal contains, 8.9% proteid and by the same 
 calculations 3 lbs. 2 ozs. will be found to contain 
 4.5 ozs. of proteid. 
 
 It is by no means a matter of indifference whether 
 the proteid be derived from any one of these food 
 
DIETARY STANDARDS 57 
 
 materials, or from a mixture of different ones. The 
 other food ingredients present must be taken into 
 account. For example, the three pounds of bread 
 
 Composition of the Edible Portion of Some Common Foods 
 
 
 P. 
 
 < 
 
 a> 
 P. 
 
 S 
 cS 
 
 u 
 
 ft 
 •6 
 
 c 
 
 
 
 u 
 
 <v 
 
 is 
 
 us 
 
 11 
 
 
 
 u 
 
 p. 
 
 
 
 Milk 
 
 0.7 
 3.0 
 3.8 
 1.0 
 1.0 
 1.1 
 1.0 
 1.0 
 19.0 
 0.9 
 1.1 
 0.3 
 0.5 
 
 87.0 
 11.0 
 34.0 
 73.7 
 61.3 
 65.5 
 63.3 
 63.7 
 55.0 
 83.5 
 88.3 
 84.6 
 75.3 
 
 3 3 
 
 1.0 
 
 25.9 
 
 13 4 
 
 19.0 
 
 30.3 
 
 18.7 
 
 19.3 
 
 37.3 
 
 16.7 
 
 6.0 
 
 0.4 
 
 1.3 
 
 4.0 
 85.0 
 33 7 
 10.5 
 19.1 
 13.6 
 17.5 
 16.3 
 0.3 
 0.3 
 1.3 
 0.5 
 0.6 
 
 5.0 
 
 "2!4" 
 
 "3'3 ■ 
 
 13.0 
 
 31.0 
 100.0 
 
 75.1 
 
 71 9 
 
 53.1 
 
 71.9 
 
 74 1 
 
 75.4 
 
 79.0 
 
 18.4 
 
 59.6 
 
 62.0 
 3.9 
 
 17.3 
 
 76.1 
 
 30.3 
 
 335 
 
 Butler 
 
 3.605 
 
 Cheese 
 
 1,950 
 
 Eggs 
 
 720 
 
 Beef (sirloin) 
 
 1,155 
 
 Beef (round) 
 
 950 
 
 Mutton (leg) ^ 
 
 Fowl . 
 
 1,085 
 1,045 
 
 Cod (boneless salt) 
 
 Cod (fresh) 
 
 490 
 335 
 
 Oysters 
 
 230 
 
 Awnles 
 
 290 
 
 Bananas 
 
 460 
 
 Sugar 
 
 1,857 
 
 Flour (white) 
 
 Flour (entire wheat) 
 
 Bread . . . .■ 
 
 0.5 
 1.0 
 1.1 
 1.8 
 1.3 
 1.0 
 0.4 
 1.0 
 3 5 
 3.9 
 0.9 
 2.0 
 3.3 
 3.3 
 
 12.0 
 11.4 
 35.3 
 
 6.8 
 10.3 
 13.5 
 13.3 
 78.0 
 13.6 
 
 9.5 
 94.7 
 
 4.8 
 14.6 
 
 5.9 
 
 ii.4 
 
 13.8 
 9.2 
 
 10.7 
 
 13.4 
 9.2 
 7.8 
 2.3 
 
 22.5 
 
 21.6 
 1.2 
 
 21 
 2.6 
 
 12.9 
 
 i.6 
 
 1.9 
 1.3 
 8.8 
 0.9 
 1.9 
 0.3 
 0.1 
 1.8 
 1.0 
 0.3 
 
 54 9 
 3.3 
 
 48.7 
 
 1,650 
 1,675 
 1,315 
 
 Crackers 
 
 1,905 
 
 Macaroni 
 
 1,665 
 
 Corn meal 
 
 1,655 
 
 Rice 
 
 1,630 
 
 Potatoes 
 
 385 
 
 Dried Beans 
 
 1,605 
 
 Dried Peas 
 
 1,655 
 
 Lettuce 
 
 90 
 
 Almonds 
 
 3,030 
 
 Raisins 
 
 1,605 
 
 Chocolate 
 
 3,860 
 
 
 
 (See pages 36 and :^7 for charts giving graphic representa- 
 tion of these foods.) 
 
 would furnish also more than a pound and a half of. 
 
 carbohydrates, a great excess of the required 
 
 amount. The meat would vary in fat, but estimating 
 
58 roOD AND DIETETICS 
 
 the per cent as twenty, the pound and a half would 
 yield four and eight-tenths ounces, more than would 
 be required for the day. The quantities used of these 
 dififerent foods must then be so adjusted that the nu- 
 trients will be in approximately the right proportion. 
 The deciding- upon these different quantities from the 
 percentage composition of the food is the essential 
 point in calculating dietaries. 
 Use of The question will probably come to each one — of 
 
 le anes j^^^ much practical use for the everyday housekeeper 
 is this study of dietaries. In the first place, it would 
 mean the expenditure of a great deal of time if one 
 should undertake to determine each Hay's rations in 
 this way. In the next place, it is impossible to know 
 the actual composition of the food J:hat we eat, except 
 in a few cases. We may be fairly sure of the com- 
 position of the Qgg, but when meat varies in proteid 
 from 12 per cent to 22 per cent as it does according 
 to the Atwater analyses, how are we to determine 
 the composition of the particular cut that we are using 
 to-day? IMoreover, even if our meal were prepared 
 so that the exact proportions of nutrients were fur- 
 nished, it is quite possible that one member of the 
 family might eat too large a proportion of the pro- 
 teids and another too much of the carbohydrates. 
 
 Another element of uncertainty lies in the difference 
 in composition between cooked and uncooked food. 
 Rice, for example, according to the tables, contains 
 79 per cent of carbohydrate and 7.8 per cent of pro- 
 
DIETARY STAXDARDS 59 
 
 tcid. I'ut it you will weigh a cup of rice l)cfore it 
 is cooked, and the same rice after it is cooked, you will 
 find that it has gained perhaps four times its original 
 weight. In other words, a quarter of a pound of 
 cooked rice will only furnish about a fourth as much 
 nutrient as a quarter of a pound of rice without the 
 added water. Often we can allow for this difference 
 in the cakulation of our dietary ; but sometimes we 
 know too little about the changes which take place 
 in cooking to do this. Finally, even if we know 
 exactly what we eat we do not know what we assimi- 
 late. Is there, then, any use in the dietary standard ? 
 
 In two ways it is of great service. In the first place, variation 
 it is a standard by which we may test our diet if we standard 
 extend our experiment over a sufficiently long period. 
 At the beginning of a month let us take account of 
 stock, estimate the amount of food materials on hand, 
 and then keep careful account for a month of all food 
 brought into the house ; at the end of the month we 
 will again estimate what we have on hand and in this 
 way ascertain the amount of raw material used. 
 Table I\', with the details which follow, gives an 
 example of a carefully calculated dietary. The com- 
 position of the various foods was taken from Bulletin 
 No. 28 of the office of Experiment Stations, U. S. De- 
 partment of Agriculture.* If, on calculating the food 
 value of the different materials, we find that for the 
 
 * "The Chemical Composition of American Food Materials" which 
 maj' be obtained by sending live cents j/i. (Y>m to the U. S. Department 
 oX Agriculture, Office of Experiment Stations, Washington, D. C. 
 
6o rOOD AND DIETETICS 
 
 number of persons served we liave a distinct varia- 
 tion from the standard diet, we can legitimately con- 
 clude that there is something- wrong. If, for ex- 
 ample, we find that the amount of proteid calculated in 
 our food materials is twice as much as that supposed 
 to be required, we shall conclude that either our fami- 
 lies must be using a much larger amount of proteid 
 than would be conducive to the best health, or there 
 must be much unnecessary waste, and in either case, 
 an investigation would be needed. 
 Errors in Another wav in which the dietary standard is of 
 
 Dietaries _ , " . . . ; 
 
 especial service, is in enabling us to judge what error 
 in diet is responsible for some particular weakness or 
 peculiarity in any member of the family. A girl of 
 fourteen may be unusually thin or may appear lan- 
 guid and tired, and everything point to improper feed- 
 ing as the cause. The first thing to do in this case 
 w'ould be to see whether the child's diet were deficient 
 in any one of the three nutrients, and if so bring the diet 
 up to the standard. In dealing with abnormal condi- 
 tions, then, or with large masses of people, or with 
 diet over an extended length of time, the dietary 
 standards may be applied to great advantage. It is 
 not necessary to apply it strictly to each individual 
 at each meal. 
 
 The calculation of a few dietaries is very useful 
 in giving us a definite idea of the general composi- 
 tion of foods, and so making it easier to estimate the 
 amount of different nutrients which we are providing 
 
DIETARY STANDARDS 
 
 6i 
 
 at ordinary meals, without the tcdiousness of reckon- 
 ing each meal in detail. 
 
 In such calculations the following' factors are used 
 to reduce the results to the standard of one man at 
 moderate work. 
 
 Factors used by the U. S. Department of Agriculture in Calculating: 
 Meals Consumed in Dietary Studies. 
 
 Man at hard muscular work requires 1.3 the food of a man at moderately 
 active muscular work. 
 
 Man with light muscular work and and boy 1516 years old require 0.9 
 the food of a man at moderately active muscular work. 
 
 Man at sedentary occupation, woman at moderately active work, boy 
 13-14, and girl 1516 years old require 0.8 the food of a man at moderate- 
 ly active muscular work. 
 
 Woman atlightwork, boy 13, and girl 13-14 years old requireO.7 the food 
 of a man at moderately active muscular work. 
 
 Boy 10-1 1 and girl 10-13 years old require 0.6 the food of a man at moder- 
 ately active muscular work. 
 
 Child 6-9 years old requires 0.5 the food of a man at moderately active 
 muscular work. 
 
 Child 2-5 years old requires 0.4 the food of a man at moderately active 
 mitscular work. 
 
 Child under 2 years old requires 0.3 the food of a man at moderately 
 active muscular work. 
 
 Factors 
 
 In making dietary studies all food used should be 
 weighed, but the following data may be of use for 
 approximate home calculation : 
 
 I measuring cupr:r}/ pint. 
 i6 tablespoons^ I cup. 
 3 teaspoonsrr:! tablespoon. 
 A cup of water weighs aboiit 8.3 oz., of milk 8.6- oz., of 
 cream 8.4 oz., of butter 8.4 oz., of lard 7.5 oz., of sugar 8 oz., 
 and a tablespoonful of the foregoing weighs about 0.5 oz. A 
 cup of meal weighs 5 oz., of sifted flour 4 oz., of oatmeal 2.7 
 oz., of cream of wheat 6 oz. A cubic inch of meat or butter 
 weighs about 0.5 oz. An egg without shell weighs 1.6 oz. A 
 slice of bread Yz in. thick weighs i oz., a heaping teaspoonful 
 of sugar 0.4 oz. 
 
 Home 
 
 Studies 
 
62 FOOD AND DIETETICS 
 
 Since the foregoing was written, Professor Irving 
 Fisher of Yale University has devised a compara- 
 tively simple method of calculating individual 
 dietaries. His method is given in full in Bulletin 
 No. 13, "Food Values," of the A. S. H. E, and in the 
 supplement to this series of lessons. Before going 
 further it is well to become familiar with this method. 
 
 Instead of starting with the percentage composi- 
 tion by weight of foods, the basis is percentage by 
 "food units" or fuel and energy value, or in other 
 words, by calories. This does away with the varying 
 amounts of water contained in food which, while ab- 
 solutely necessary, has no fuel value and the method 
 ])laces the fats on the same basis as the carbohydrates 
 and proteins. 
 
 A table is given showing the average food units 
 required for men, women and children, based on 
 Professor Chittenden's standards. 
 
 After becoming familiar with this method, the 
 approximate total food value of one's daily diet may 
 be reckoned mentally and the proportion of the three 
 chief food principles may be obtained with but little 
 figuring. 
 
 Note the additional work required by this method 
 in connection with Question 21 of this lesson p. 217. 
 
TEST QUESTIONS 
 
 The following questions constitute the "written reci- 
 tation" which the regular members of the A. S. H. E. 
 answer in writing and send in for the correction and 
 comment of the instructor. They are intended to 
 emphasize and fix in the memory the most important 
 points in the lesson. 
 
FOOD AND DIETETICS 
 
 PART I 
 
 Read Carefully. Tlie Department of Agriculture Bulletin No. 
 142, "The Nutritive and Efouomic Value of Poo;l," should be studied 
 in connection with this lesson. Make your ansivers full and complete. 
 
 I. 
 
 What to-day is included in the food problem? 
 
 2. What factors affect the proportion of the income 
 
 spent for food? 
 
 3. At current prices in your locality, give a list of 
 
 foods you would provide for a day's ration at 
 20 cents per person for raw food material. x\t 
 30 cents. At 40 cents. 
 
 4. To what extent can waste in food be eliminated? 
 
 5. How do animal and vegetable foods compare in 
 
 cost? 
 
 6. Which would be the cheaper source of proteid, 
 
 beefsteak at 25 cents per pound, milk at 8 cents 
 per quart, bread at six cents per pound, corn 
 meal at 4 cents per pound? Give details of 
 calculations. 
 
 7 . How is the heat and energy of the body produced ? 
 
 8. What is meant by the term calorie? How is it 
 
 that mechanical energy can be measured by 
 this unit? 
 
 9. How does the amount of heat produced by pro- 
 
 teid compare with that obtainable from an 
 equal amount of starch? With that from an 
 equal amount of fat ? 
 
FOOD AND DIETETICS 
 
 10. W'liat relation has digestibility to food value? 
 
 11. W'liat are the five food principles? Give their 
 
 functions. Which of the food principles is 
 most important? 
 
 12. What is meant by proteid? Name the most com- 
 
 mon representatives of the class found in food. 
 
 13. If possible, perform the experiments in separat- 
 
 ing some of the proteids as described and 
 report. 
 
 14. How does gelatine differ from the true proteids? 
 
 How may it be obtained? 
 
 15. What is the most important carbohydrate from 
 
 the standpoint of food ? WHiat is its source ? 
 
 16. How do fats differ from carbohydrates? 
 
 17. What is meant by food value? By nutrient ratio? 
 
 18. How are dietary standards determined? 
 
 19. What factors affect the amount and proportion 
 
 of food needed? 
 
 20. Of what practical value to the housekeeper are 
 
 dietary standards? 
 
 21. Calculate the amount of proteid, carbohydrate, 
 
 and fat in your own diet for one day as nearly 
 as you can. Give details of calculation. 
 
 22. What questions have come to you in the study 
 
 of this lesson? 
 Note. Question 21 is optional. After completing the test 
 sian vour full name. 
 
FOOD AND DIETETICS 
 
 PART II 
 
 SPECIAL FOOD STUFFS 
 
 In the selection of foods one of the questions that 
 will come up will be that of the relative value of ani- 
 mal and vegetable foods. An increasing number of 
 people are confining their diet largely, if not exclu- 
 sively, to vegetable products, while others add to these 
 such animal substances as do not imply the taking 
 of life, such as milk and eggs. Is a mixed diet essential 
 for health? Or may we at will choose exclusively 
 from the animal or the vegetable kingdom? 
 
 Certain broad distinctions between animal and vege- 
 table food will immediately present themselves. 
 Speaking generally, animal foods are richer in nitrog- 
 enous matter, while vegetal:)le foods are the chief 
 source of carbohydrates. This becomes much more 
 evident if we compare the two in a dry condition. 
 Alilk, for instance, makes a poor showing in proteid 
 as compared with dried peas and lentils, or even with 
 rice. But if we take the total solids of the milk as a 
 basis of comparison, eliminating the 87 per cent of 
 water, the case is quite otherwise. This is the fair 
 method, for the dried peas and rice absorb many times 
 their weight of water in the process of cooking, so 
 that the analysis of the raw material is quite different 
 from that of the cooked food. 
 
 Animal 
 and 
 
 Vegetable 
 Food StufFs 
 
 Distinction 
 
^4 
 
 FOOD AND DIETETIC^ 
 
 CaTl>ohydrates 
 
 Comparative 
 Cost 
 
 Hutchison gives the following' composition of a few 
 typical dried foods: 
 
 One hundred parts of dried lean beef contain 89 parts of 
 proteid. 
 
 One hundred parts of dried fat beef contain 51 parts of 
 proteid. 
 
 One hundred parts of dried pea flour contain 27 parts of 
 proteid. 
 
 One hundred parts of dried wheat contain 16 parts of 
 proteid. 
 
 One hundred parts of dried rice contain 7 parts of proteid. 
 
 To this we may add: 
 
 One hundred parts of dried milk contain 25 parts of 
 proteid. 
 
 On the other hand we find our carbohydrates almost 
 wholly in the vegetable kingdom. Milk is the only 
 important exception to this. In milk, dried, we find 
 38 parts of carbohydrate to 100 of the total solids. 
 
 Another difference between animal and vegetable 
 food is found in their comparative cost. Animal food as 
 a rule is much more expensive than vegetable. This 
 is not difficult to understand when we remember that 
 our animal food has been put through a further pro- 
 cess of manufacture than the vegetable food. If the 
 grain raised, instead of going directly to man as food, 
 is used to feed cattle, and these in turn are slaughtered 
 to furnish nourishment for human beings, the process 
 necessarily adds to the cost of the food. This pro- 
 cess, as well as the fact that plants are in general 
 builders of material, while animals break down the 
 complex compounds built up by the vegetables," is 
 graphically shown by the accompanying diagram. 
 
SPECIAL FOODS 
 
 The same intermediate process which adds to the 
 cost of food increases also its digestibihty, though the 
 less complete absorption by the system of vegetal)le 
 
 Digestibility 
 
 Animal L,ifp 
 
 .%'• 
 
 >^^ 
 
 Cycle of Lite 
 
 than of animal proteid seems to lie in the fact that in 
 the plant the proteid is enclosed within cellulose walls 
 and ordinary processes of cooking do not always free 
 it, rather than in any difference in the proteids them- 
 selves. 
 
 In deciding from which kingdom we shall choose 
 
66 
 
 FOOD AND DIETETICS 
 
 Source of 
 Proteid 
 
 Vegetarian 
 Diet 
 
 Structure 
 
 our diet, we consider almost wholly the proteid. As 
 we have seen, carbohydrates must necessarily he ob- 
 tained chiefly from veg-etahle sources, and it seems 
 to be a matter of indifference whether the fat of the 
 diet is of animal or vet;-etable orig-in. With the. addi- 
 tion of milk, butter, cheese, and eggs, it is not diffi- 
 cult with care to provide a satisfactory dietary without 
 the use of meat. 
 
 The case is different when vegetables form the only 
 source of food sui)plies. Because of the great excess 
 of carbohydrates and the presence of indigestible mat- 
 ter in the form of cellulose, a great bulk of food must 
 be taken in order to get the necessary proteid. As a 
 matter of fact, nearly all purely vegetarian diets are 
 deficient in proteid. The extra cost of the animal pro- 
 teid is justified by its availability since it may be ob- 
 tained without an excess of other substances and since 
 it is easily assimilated. 
 
 MEAT 
 
 In the ordinary family the greater part of the pro- 
 teid diet is probably furnished by meat, so that a 
 knowledge of the composition and nutritive value of 
 this article of food is important. The structure of the 
 meat may be best seen if one with a sharp knife scrapes 
 a small piece of meat, thus separating the muscle fibre 
 from the white connective tissue. Under the micro- 
 scope the muscle fibre is seen to consist of bundles of 
 smaller fibres held together by delicate connective tis- 
 sue in which fat cells are imbedded. These muscle 
 
MEAT 
 
 67 
 
 fibres vary in length in different kinds of meat, and 
 the length of fibre probably plays some part in the 
 digestibility of the meat— the short fibre meats being 
 the more digestible. 
 
 The toughness or tenderness of meat 
 depends partly upon the muscle fibres 
 and partly upon the connective tissue, 
 though as a rule the same conditions 
 that have made the connective tissue 
 tough and strong will have had a sim- 
 ilar though less effect upon the muscle 
 fibre. In general the muscles that are 
 most used or most exposed to wind 
 and weather will be both tougher and 
 richer in flavor than those not so ex- 
 posed. The young animal will, of 
 course, have more delicate tissues and me\t 
 less toughened fibres than the older or „ Fibre 
 harder worked animal. c Connectiug 
 
 The composition of different pieces of 
 meat, even from the same animal, differs greatly, the 
 proteid of beef, for instance, varying all the way from 
 twelve per cent to twenty-one, according to the cut of 
 meat and to the feeding of the animal from which it 
 is obtained. 
 
 The proteids of meat include a number of different 
 substances, the chief of which are fibrin, myosin and 
 albumin. After the animal is killed the myosin coagu- 
 
 Composition 
 
 Proteids 
 of Meat 
 
68 
 
 FOOD AND DIETETICS 
 
 Albumen 
 
 Flavor 
 
 Fat of 
 Meat 
 
 lates, thus causing the hardening of the muscle, known 
 as rigor mortis. In this condition the meat is very 
 tough, and the hanging of meat is practiced in order 
 to give time for th? disappearance of this rigor by the 
 re-sokition of the myosin. 
 
 The presence of albumin in the meat can be easily 
 shown by soaking a small portion of the meat in water 
 for a few minutes, and then heating this water. The 
 albumin dissolves in the water and coagulates upon 
 heating just as white of egg would do under similar 
 conditions. The scum that forms in the water when 
 a piece of meat is boiled, is largely this same albumin. 
 Beside the true proteids, gelatine may be obtained 
 from meat in varying quantities. The connective tis- 
 sue upon boiling beconies gelatine, and it is due to 
 this as well as to the gelatine obtained from the bones 
 that water in which meat has been cooked so often 
 sets into a jelly. The col^r of meat is due largely to 
 the same substance that gives the color to blood, 
 haemoglolnn. Its lluvor depends chielly upon the 
 nitrogenous substances called extractives, though the • 
 characteristic taste of pork and mutton is caused partly 
 by the fats they contain. These extractives have no 
 real food value, but act as stimulants. 
 
 The fat in meat varies even more in amount than the 
 proteid ; beef, as purchased, containing from five and 
 eight-tenths per cent to more than forty per cent. 
 
 Even in meat that appears lean much fat is present 
 lying between the muscle fibres. This may be seen 
 
MEAT 
 
 69 
 
 upon heating the meat hi water, when globules of fat 
 appear from even the leanest meat. The solidity of 
 the fat is due chiefly to the stearin that is present. 
 
 The amount of water in meat varies very much. 
 A lean cut of beef may have as much as seventy-five 
 per cent of water, while a fat piece might not contain 
 more than fifty per cent. In general the more fat the 
 less water there is present, so that in buying it is 
 economy to select meat that is moderately fat. 
 
 From the standpoint of digestibility, meat is an ex- 
 cellent food. It is among the most easily digested of 
 the proteid foods. As a rule raw meat is more digesti- 
 ble than cooked, and rarely cooked meat more digesti- 
 ble than that which is well done. The cooking of 
 meat has its value not in adding to the digestibility 
 but in developing flavor, so that the meat becomes 
 more palatable ; and in rendering it more safe, by de- 
 stroying certai^i parasites that are sometimes present 
 in raw meat, particularly in pork, and bacteria that 
 under certain circumstances may cause dangerous de- 
 composition. 
 
 There is much difference in the digestibility of dif- 
 ferent meats. Pork is ranked among the less digestible 
 meats, since it requires a longer time for complete 
 digestion than do other varieties. This is probably 
 due to the large amount of fat closely combined with 
 the muscle filjres. Bacon fat, on the other hand, from 
 its different form, is generally found to be easily di- 
 gestcd. 
 
 Water 
 
 Factors in 
 Dieestibility 
 
70 
 
 FOOD AND DIETETICS 
 
 Effects of 
 Cooking 
 
 Losses in 
 Boiling 
 
 Mutton and beef stand equally well in this respect. 
 As has been suggested before, short fibred meats are 
 in general more easily digested than long fibred ones, 
 yet veal is an exception to this. Hutchison explains 
 this by suggesting that the fibres of veal easily elude 
 the teeth on mastication, and that the comparatively in- 
 sipid character of the veal fails to excite a free flow 
 of gastric juice. It would seem that this absence of 
 extractives would be the more important factor. 
 
 How far the cooking of meat alters its chemical 
 composition is not wholly determined. Some inter- 
 esting e^cperiments at the University of Illinois have 
 taught us much about the losses that take place in 
 the cooking. It is shown that in whatever way meat 
 is cooked, there is much loss of weight, amounting 
 either in boiling or in roasting to a fourth or even 
 a third of the original weight. This loss is partially 
 proteid and fat, but consists still more largely of water. 
 The loss of water appears to be caused partly, at 
 least, by the hardening and consequent contraction 
 of the muscle fibre, the water being mechanically 
 forced out. 
 
 An interesting experiment has been tried in regard 
 to the effect of salt in preventing or accelerating the 
 losses in meat. A salt solution was prepared, having 
 the same density as that of the juices of the meat, and 
 a piece of meat was boiled in this. It was found that 
 a very small amount of the juices of the meat were lost 
 in the water and practically none of the salt penetrated 
 
MEAT 
 
 7t 
 
 into the interior of the meat. The conclusion drawn 
 was that very little interchange of the water and the 
 meat juices could take place unless the medium in 
 which the meat was cooked was either less or more 
 dense than the meat juices themselves. 
 
 Meat does not form a cheap source of proteid food, 
 but the cost can be lessened very much by care in 
 selecting the cheaper cuts. As a rule these cheaper 
 parts need longer cooking than the more expensive 
 tender cuts, and, as has been suggested before, the 
 fuel must be taken into account in estimating their 
 cost. Where the cheapness of the meat is not counter- 
 balanced by the additional expense of the fuel a great 
 variety and a satisfactory diet may be obtained with 
 only the occasional use of the more expensive portions. 
 As has been said, the nutritive value of the cheaper 
 parts is as great as that of the more tender portions. 
 
 The nutritive value of meat soups, broths and ex- 
 tracts has been much discussed. Often in estimating 
 this value too little allowance has been made for the 
 method used in preparation. A clear soup contains a 
 very small amount of real food. * Its value lies in the 
 extractives that give it flavor, and in the small amount 
 of gelatin that it contains, and in its power to stimu- 
 late the flow of the gastric juices, and so whet the 
 appetite rather than satisfy it. The meat from which 
 such a soup has been made still contains a large por- 
 tion of its nutritive value, and although because of its 
 lack of flavor it cannot be used as it is, it may be 
 
 Cost of 
 Meat 
 
 Soups 
 
 and 
 
 Broths 
 
 Extractives 
 
72 
 
 FOOD AND DIETETICS 
 
 Extracts 
 of Meat 
 
 Beef 
 Juice 
 
 Nutritive 
 
 Value and 
 
 01gestibillty 
 
 made palatable and attractive by the addition of spice 
 or seasoning, or by its combination with a small por- 
 tion of fresh meat. Unless large quantities of soup 
 are made, it ought to be possible, in the ordinary 
 household, to utilize the soup meat in some way. 
 
 The commercial extracts of meat are similar to 
 clear soup in that they contain practically nothing but 
 the extractives. A more nutritious broth may be 
 made if the meat, cut in small pieces, is allowed to 
 soak for some time in cold water and then is heated 
 to a low temperature, not above i8o degrees Fahren- 
 heit, and kept at this point for some hours. Toward 
 the end of the process the broth may be brought to the 
 boiling point for a few minutes in order to dissolve all 
 the gelatin possible. The brown flecks of albumin 
 that form must be served in the broth and not be 
 strained out. Even made in this way, the value of 
 the broth is small compared with that of meat, but it 
 is much greater than that of the clear soup. 
 
 Raw beef juice is valuable as a food. If the beef 
 be cut small, and thoroughly pressed, a much larger 
 amount of proteid is obtained than by any other treat- 
 ment. The round of beef, very slightly broiled and 
 pressed, may yield as much as seven per cent of pro- 
 teid and four per cent of extractives. 
 
 FISH 
 
 One of the most natural substitutes for meat is 
 fisli. Its nutritive value is much like that of meat, al- 
 though it contains a somewhat smaller proportion of 
 
FISH 73 
 
 proteid. It also has the advantage of being as a rule 
 easily digested, and so is particularly adapted to the 
 needs of a person of sedentary habits. It is probably 
 tliis fact that has given rise to the false idea that fish 
 is a particularly good brain food. As a matter of 
 fact, it is no more a brain food than meat or eggs or 
 any other proteid food. The cost of fish is generally 
 less than that of meat, so that it furnishes a cheap 
 source of the necessary proteid. The value of fish 
 depends, however, upon nearness to the source of sup- 
 ply much more than does that of meat, since fish de- 
 teriorates rapidly upon keeping. 
 
 For food purposes we may divide fish into white classification 
 and fat fish ; or we may take Hutchison's classification 
 of, (i) fish with more than five per cent of fat, 
 such as eels, salmon and herring; (2) fish with from 
 two to five per cent of fat, as halibut and mackerel ; 
 and (3) fish with less than two per cent, such as cod 
 and haddock. Fish with a small amount of fat is 
 more easily digested than the more oily variety. Be- 
 side the proteid and fat in the fish, we obtain a certain 
 amount of gelatine. The sturgeon furnishes isin- 
 glass, a very pure variety of this substance. 
 
 In estimating the cost of fish, allowance must be cost 
 made for the large amount of waste so that the price 
 per pound tells by no means the whole story of its 
 value from an economic standiioinl. The follow- 
 ing analysis by Miss Williams shows the waste in 
 
 of Fish 
 
Variety 
 in Diet 
 
 Shell 
 Fish 
 
 74 FOOD .-LVD DIETETICS 
 
 cooked fish as served at the table, and also the amount 
 of nutrient present. 
 
 Composition of Fish 
 
 Fish 
 
 Part analyzed 
 
 Per cent 
 
 Waste. 
 
 Bones, 
 
 etc. 
 
 Per cent 
 Gelatin 
 
 Per cent 
 Water 
 
 Per cent 
 Nutrients 
 
 Sai'dines . 
 
 Whole 
 
 4 91 
 
 5 99 
 8 33 
 
 11.66 
 10 51 
 15.99 
 
 6.13 
 35.10 
 21.50 
 81.20 
 
 6.84 
 
 
 42.17 
 61 06 
 67.12 
 53.29 
 65.21 
 63.78 
 67 68 
 46.46 
 61.29 
 53 09 
 69.35 
 79.85 
 61.18 
 77 71 
 &5.20 
 
 53.93 
 
 
 Section 
 
 0.53 
 0.55 
 1.09 
 0.35 
 0.43 
 33 
 80 
 0.86 
 59 
 0.03 
 
 32.03 
 
 Trout 
 
 Eels. 
 
 Whole 
 
 Head s removed 
 
 Whole 
 
 24.10 
 33 96 
 24 03 
 
 Cod. 
 
 Section 
 
 19.79 
 
 Salt cod 
 
 Section 
 
 25.85 
 
 Haddock 
 
 Whole 
 
 17.64 
 
 Whiting. .. 
 Tuvbot .... 
 Halibut. 
 
 Whole 
 
 16 35 
 
 Anterior and head. . 
 Section 
 
 15.13 
 23.78 
 
 Plaice 
 
 Flesh ... . 
 
 20.14 
 
 Soles 
 
 Whole 
 
 23.03 
 
 0.74 
 
 12.06 
 
 Oysters 
 
 Smelts 
 
 Shell contents 
 
 22 29 
 
 Whole 
 
 is 86 
 
 6 38 
 
 15. 56 
 
 Fish, beside being an economical source of nitroge- 
 nous substances, has much value in satisfying the 
 demand for variety in food. Any lack in nutrients is 
 frequently supplied by the sauces with whicli it is 
 served, and by the fat used if it is fried. It would 
 seem to be an error from the standpoint of food values 
 to serve a rich sauce with a fish like salmon that 
 already contains a high proportion of proteid and a 
 large amount of fat, but an egg sauce served with a 
 light fish like cod or haddock has its justification, not 
 only in the additional flavor imparted, but in the addi- 
 tional food value. 
 
 Ovsters may be taken as a good type of the various 
 shell fish that we use. The analysis of oysters shows 
 a composition somewhat similar to that of milk, 
 
FISH 75 
 
 although they are higher in nitrogen and lower in fat 
 than milk. 
 
 Average Composition of Oysters. (Langworthy.) 
 (Exclusive of liquid.) 
 
 Water 88. .S 
 
 Nitrogenou.s sub.stances 6 1 
 
 Fat 1.4 
 
 Carbohydrates 3.3 
 
 Salts 1,9 
 
 When milk is seven cents a quart and oysters are 
 twenty-five, the amount of food material purchased for 
 a given amount differs greatly in the two. When oys- 
 ters are fifty cents a quart they must be distinctly re- 
 garded as a luxury, used for the purpose of provid- 
 ing variety, and not as a valuable source of food. 
 Oysters are one of tlie few animal foods that contain 
 a large amount of carbohydrates. These are present 
 in the liver of the oyster in the form of glycogen. 
 
 The oyster is especially easy of digestion, but this 
 digestibility is lessened by cooking. This is particu- 
 larly true when the oyster is overcooked. An object- 
 tion to the use of the raw oyster is that during the 
 so-called fattening of the oyster, that is done in shal- 
 low water, it may become contaminated with typhoid 
 germs derived from sewage. Some noted epidemics 
 have been traced to this source. This simply means 
 that greater care should be taken in the supervision 
 of such a food supply in order that it may be protected 
 from such possible contamination. 
 
 Of other shell fish commonly used, clams have a 
 Similar composition to that of oysters, but contain 
 
 Comparative 
 Cost 
 
 Digestibility 
 
 Clams 
 Lobsters 
 
1^ 
 
 FOOD AND DIETETICS 
 
 Dried and 
 
 Smoked 
 
 Fish 
 
 Cooking 
 
 a toiig-her muscle, while lobsters and crabs are g-en- 
 erally considered somewhat indigestible because of 
 the firmness and compactness of their fibre. The dif- 
 ficulty here seems partially at least to be the failure 
 to properly masticate the flesh, as is true in so many 
 other cases, and also the difficulty of obtaining' the 
 food in an absolutely fresh condition. 
 
 Dried and smoked fish deserve a place in the diet 
 for the sake of variety, and because, since the water has 
 been eliminated, a large amount of food material is 
 obtained for a small amount of money. The use of cer- 
 tain varieties of canned fish has become general. Sal- 
 mon is perhaps the most satisfactory of these. Special 
 care should be taken in using canned fish to remove it 
 immediately from the can after it is opened, and to use 
 it within a short time. Fish that has been frozen 
 should be cooked immediately after thawing, since it 
 decomposes much more rapidly than fish which has 
 not been frozen. 
 
 Fish, particularly some varieties, such as cod, occa- 
 sionally contains parasites, but these are destroyed by 
 thorough cooking. It is essential that all fish used 
 should be thoroughly cooked, although this does not 
 mean that it should be cooked at a high temperature. 
 A temperature of from i8o to 200 degrees Fahrenheit 
 continued long enough to coagulate the proteid and 
 render the fish opaque instead of clear, gives far more 
 satisfactory results than boiling. 
 
 As in other cooking of flesh, this principle is appar- 
 ently violated when fish is cooked in a hot oven, or 
 
FISH 
 
 f? 
 
 fried, but as a matter of fact, the violation is only 
 true so far as the outside layers are concerned, and 
 this sacrifice is made in order to keep the shape of the 
 fish and to develop the flavor. 
 
 Comparative Costs of Protein and Energy as Furnished by a Number 
 of Food Materials at Certain Prices 
 
 Kind of Food Material. 
 
 I I Cost of 
 
 Price perl protein 
 pound. per 
 pound. 
 
 Codfish 
 
 Codfish steaks 
 
 Bluetish 
 
 Halibut 
 
 Cod, salt 
 
 Mackeral, salt 
 
 Salmon, canned 
 
 Oysters, "solids" (30 cents per quart).. 
 Oysters, "solids" (60 cents per quai-t) . . 
 
 Beef, sirlolD 
 
 Do 
 
 Beef, round 
 
 Beef, stew meat 
 
 Beef, dried "chipped" 
 
 Mutton chops (loin) 
 
 Mutton leg 
 
 Pork roast (loin). 
 
 Pork, smoked ham 
 
 Milk (7 cents per quart) — 
 
 Milk (6 cents per quart) 
 
 Lobster 
 
 Wheat flour 
 
 Corn meal 
 
 Potatoes (90 cents per bushel) 
 
 Potatoes (45 cents per bushel) 
 
 Cabbage 
 
 Corn, canned 
 
 Apples 
 
 Bananas 
 
 Strawberries 
 
 From F'ish as Food 
 
 EOOS 
 
 Cents. 
 10 
 13 
 13 
 18 
 
 7 
 10 
 12 
 \5 
 30 
 25 
 20 
 U 
 
 5 
 25 
 20 
 23 
 13 
 23 
 
 3H 
 
 3 
 18 
 
 3 
 
 2 
 
 I'A 
 
 Yx 
 
 2K 
 10 
 
 W2 
 
 7 
 7 
 
 $0.94 
 
 .71 
 
 1.22 
 
 1.18 
 
 .44 
 
 .68 
 
 .55 
 
 2.50 
 
 5.00 
 
 1 53 
 
 1.23 
 
 .77 
 
 .36 
 
 .97 
 
 1.54 
 
 1.48 
 
 .85 
 
 1.65 
 
 1.06 
 
 .91 
 
 3.05 
 
 .27 
 
 .23 
 
 '.9& 
 
 .44 
 
 1.79 
 
 3.57 
 
 5.00 
 
 8.75 
 
 7.00 
 
 Cost of 
 energy 
 per lOOO 
 calories, 
 
 SO. 49 
 .36 
 .59 
 .38 
 23 
 !ll 
 .13 
 .65 
 
 1.30 
 .26 
 .21 
 .16 
 .07 
 .33 
 .14 
 .35 
 .09 
 .13 
 .11 
 .09 
 
 1 24 
 .03 
 .01 
 .05 
 .03 
 .20 
 .23 
 !07 
 •23 
 .38 
 
 One of the most general substitutes for meat is the 
 egg. One would at first thought expect eggs to be 
 of much the same composition as milk, since each fur- 
 
 Composltion 
 
78 
 
 FOOD AND DIETETICS 
 
 White 
 
 and 
 
 Yolk 
 
 nishes food for the growing- animal, but when tlie 
 (hfferent conditions are considered, the reason for the 
 variation in this respect is readily seen. The egg must 
 contain a large an^iount of nourishment in the most 
 compact form. It nuist furnish all the materials nec- 
 essary for growth, but it does 
 not need to provide for activ- 
 ity to the extent that milk 
 does. Consequently we find 
 the carbohydrates wholly ab- 
 sent, and a much larger pro- 
 ])ortion of solid material than 
 is present in milk. The solids 
 are in the form of proteids, 
 fourteen and eight-tenths per 
 cent ; fat, ten and a half per 
 cent ; and mineral salts, one 
 per cent. This refers to the 
 edible part only. 
 The white of the Qgg contains twelve per cent of 
 proteid, with practically no fat and a small amount of 
 mineral matter, while the yolk has sixteen and two- 
 tenths per cent of proteid and almost thirty -two per 
 cent of fat. 
 
 The greater part of the mineral salts are also in the 
 yolk, although the sulphur that causes the blackening 
 of the silver spoon with which we cat our egg is 
 chiefly in the white. 
 
 (Aftor Hutoliisiin.) 
 
 Diagram showing Composi- 
 tion of White and Yolk of 
 an lOgg. 
 
EGGS 79 
 
 While eggs form a valuable meat substitute, it is 
 difficult to use them wholly in the place of meat, since 
 it takes so many eggs to equal a pound of meat. From 
 eight to nine eggs constitute a pound. If the eggs 
 have the composition given and meat contains eighteen 
 per cent proteid, it would require about twelve eggs 
 to furnish as much proteid as one pound of meat ; and 
 one who would have no difficulty in eating half a 
 pound of beefsteak at a meal, would not wish to eat 
 an equal weight of eggs. 
 
 Eggs like meat need to be supplemented by carbo- 
 hydrate material. Bread and eggs furnish a satis- 
 factory combination as well as bread and meat. Raw 
 eggs are usually considered more easily digested than 
 cooked eggs, although some experiments show that 
 the cooked egg leaves the stomach in a shorter time 
 than the uncooked. This is explained by the state- 
 ment that the raw egg is digested largely in the in- 
 testine. Its failure to excite the secretion of gastric 
 juice in the stomach makes it possible to use raw eggs 
 in the diet when the stomach requires rest. 
 
 Hard cooked eggs take a longer time to digest than Digestibility 
 those lightly cooked, but from recent government 
 experiments they seem to differ little in the complete- 
 ness with which they are digested, an egg boiled three 
 minutes having 8.3 per cent of its nitrogen undigested 
 at the end of five hours ; one boiled for five minutes 
 having 3.9 per cent undigested, and one boiled for 
 twenty minutes having 4.2 per cent remaining. Eggs 
 
8o FOOD AND DIETETICS 
 
 cooked at i8o degrees Fahrenheit for five and ten min- 
 utes respectively were totally digested in five hours. 
 Possibly the rapidity of the digestion of the hard 
 cooked egg may depend on the fineness of mastication. 
 Cost Whether eggs are to be used freely depends largely 
 
 upon their price. Eggs at fifteen cents a dozen may 
 be so used, while at fifty cents a dozen they can not be 
 regarded as an economical source of food. 
 
 MILK 
 
 Milk is often called a perfect food. This is true, 
 
 however, only in a limited sense. Hutchison gives 
 
 five tests of a perfect food. 
 
 Tests of First, such a food must contain all the nutritive 
 
 a Perfect 
 
 Food constituents required by the body ; proteids, fats, 
 
 carbohydrates, mineral matter and water. 
 
 Second, it must contain these in their proper rela- 
 tive proportions. 
 
 Third, it must contain, in a moderate compass, the 
 total amount of nourishment required daily. 
 
 Fourth, the nutritive elements must be capable of 
 easy absorption, and yet leave a certain bulk of un- 
 absorbed matter to act as intestinal balance. 
 
 Fifth, it must be obtainable at a moderate cost. 
 
 Of these tests milk meets only the first perfectly. 
 It contains the two proteids, casein and albumen. It 
 contains the fat so familiar to us in the form of cream 
 and butter. The carbohydrates are represented in it 
 by milk sugar or lactose. The mineral salts are par- 
 
MII.K 
 
 ticnlarly valual)le, and consists chiefly of calcium 
 compounds, includiui;- calcium ]diospliatc. 
 
 When we come to the second test, we find a differ- 
 ent condition. An average sample of milk contains 
 87 per cent of water, three and three-tenths per cent 
 proteid, four per cent fat, and 
 five per cent carbohydrate, 
 with seven-tenths of one per 
 cent mineral matter. This pro- 
 portion is of course right for 
 the young animal, who de- 
 mands a large proportion of 
 muscle-building food, but it is 
 far from a desirable propor- 
 tion for the adult. 
 
 Remembering that the nu- 
 trient ratio is about one to 
 five, or to put it in another 
 form, that the adult requires ' ofMUk. 
 
 approximately five times as much carbohydrate (or its 
 equivalent) as proteid, we see that milk must be sup- 
 plemented by some food containing a large proportion 
 of carbohydrate before it can adequately supply the 
 needs of the adult. As a matter of fact, experience 
 has taught us to use with milk such a food as bread, 
 thus supplying the needed starchy material. 
 
 The third condition is not met better than the second. 
 At least four quarts of milk a day would be necessary 
 for the complete nutrition of a healthy man doing a 
 
 (After HutchiBon.) 
 
 Composition of a Glass 
 
 Proportions 
 of Nutrients 
 
 Nutrient 
 Ratio 
 
82 
 
 rOOD AND DIETETICS 
 
 moderate amount of muscular work. Milk also is lack- 
 ing- in the bulk of unabsorbed matter that it leaves. 
 Cost The fifth condition may or may not be fulfilled. In 
 
 the city the price of milk is too high for it to be 
 an economical source of food if used exclusively. On 
 the other hand in the country the price of milk is 
 often so low that this condition might be fulfilled. 
 
 A comparison of the food value obtained from one 
 pound (a pint) of milk and from that of a similar 
 weight of some common article of food, is given, 
 with the cost of each at prices taken from two dififer- 
 ent sections of the country : 
 
 Comparative Food Value of Milk 
 1 lb. of milk f lU'iiishes .03'! lbs. proteid .04 lbs. fat .0.5 lbs. carbohydrate 
 1 '• " sirloin steak " .165 " " .Ifil " " no 
 
 1 '■ " eggs(8eggs) " .131 " " .(«3 
 1 '• " bread " .092 " " .013 
 
 
 no 
 ..5311b 
 
 , 
 
 
 . 
 
 
 1 ■' •' potatoes " .018 " " .001 
 (one 60th bu.) 
 
 
 .147 
 
 
 
 
 From milk at (M per qt. or .03 per lb.) 
 " (.07 .035 •• ••) 
 
 1 11). 
 1 '■ 
 
 of pro 
 
 teid 
 
 costs 
 
 $ .60 
 1.06 
 
 " sirloin steak at .18 a lb. 
 
 1 '• 
 
 
 ' 
 
 
 
 1.09 
 
 " .25 " 
 
 1 " 
 
 
 ' 
 
 
 
 1..53 
 
 " eggs at (.15 per doz. or .10 per lb.) 
 
 '• (.36 .24 " " ) 
 
 •' bread at .05 per lb. 
 '• .08 " " 
 
 1 '• 
 1 " 
 1 " 
 1 " 
 
 
 ' 
 
 
 
 .76 
 
 1.83 
 .54 
 
 .87 
 
 " potatoes at .60 per bu. or .01 per lb. 
 '• $1.20 " " " .02 ■• " 
 
 1 " 
 1 " 
 
 
 c 
 
 
 
 .56 
 1.11 
 
 In addition to the proteid, the money invested would 
 have purchased, in the case of milk more than a pound 
 of fat and of sugar ; in that of meat an equal amount 
 of fat ; in the case of bread more than five pounds of 
 starch; in that of potatoes nearly seven pounds of 
 
MILK 
 
 S? 
 
 starch ; while three-fourths of a pound of fat would be 
 furnished by the eggs. 
 
 Even at city prices milk might well be substituted to 
 a certain extent for other proteid foods. The habit 
 of many people of using milk simply as a beverage in 
 addition to the food required, is perhaps responsible 
 for the fact that many people find milk indigestible ; 
 the difficulty lies not with the milk but with the over- 
 abundance of food. An experiment was tried at the 
 Maine Agricultural College on the effect of a limited 
 and an unlimited amount of milk at the I^niversity 
 boarding house. These experiments are reported in 
 the Government Bulletin called Milk as Food, and the 
 following conclusions are drawn : 
 
 "First, the dietaries in which milk was more abun- 
 dantly supplied was somewhat less costly than the 
 others, and at the same time was fully as acceptable. 
 Second, the increased consumption of milk had the 
 effect of materially increasing the proportion of pro- 
 tein in the diet. Third, the milk actually supplied the 
 place of other food materials, and did not, as many 
 suppose, simply furnish an additional amount of food 
 without diminishing the quantity of other materials. 
 Fourth, the results indicate that milk should not be re- 
 garded as a luxury, but as an economical article of 
 diet which families of moderate income may freely 
 purchase as a probable means of improving the char- 
 acter of the diet and of cheapening the cost of the 
 .supply of animal food/' 
 
 A Food 
 Not a 
 Beverage 
 
 An 
 
 Economical 
 
 Food 
 
84 
 
 FOOD AND DIETETICS 
 
 Chart of the Pecuniary Economy of Milk and Other Foods at 
 Given Prices 
 
 I'rotoia- 
 
 Csrbobyorans Pool valu 
 
 ^■ii'. 
 
 TVIioIe milk, tO 
 CIS. perqt 
 
 Whole milk. 8 
 ct6. perqt 
 
 Whole roilk, 7 
 era. perqt 
 
 Wliolo milk, 6 
 eta. perqt 
 
 Whole milk, 5 
 eta. perqt 
 
 Wholo railk, 4 
 cla. perqt 
 
 Skim milk, ncl.i. 
 perqt 
 
 Skim milk, e eta. 
 perqt 
 
 Imtter, 24eta. per 
 Jl) 
 
 Cheese, 16eta. per 
 lb 
 
 Beef, round, 12 
 eta. per lb 
 
 Beef, sirloin, 18 
 eta. per ll> 
 
 Uatton, Inin, 18 
 eta. per lb 
 
 Pork, salt, 12ct8. 
 per lb 
 
 Cod, ealt, 6 cts. 
 per lb 
 
 Eg^", 22 eta. per 
 (lu2 ..*... 
 
 O^atera, 30 ct». 
 p<rqt .... 
 
 PotaToea 6d eta. 
 per bii ....... . 
 
 teeaoa. dried. 8 
 eta. per qu 
 
 Wbeftt floai. 8 
 ft».peri!i...». 
 
 buy- 
 Lba.Oz 
 
 2 . 
 
 2 B 
 2 .11 
 
 Ma: 
 
 mm. 
 
 3 5 
 
 M»r 
 
 W^M:Z^MW 
 
 Pound* of aatrlents and calories in ten cant*' worth. 
 
 ^01 Soz. IZoz. ISo2 ZOoz. 24oz. ZSoi. 3Zot. 
 
 lOCOcal. ZOOOcal. 3000cal. 40(Kcal. 
 
 I I ■ I I - I I I ■ ■ I - 
 
 a^ 1 
 
 Z^^^ 
 
 iipgr 
 
MILK 
 
 8S 
 
 We may conclude that while it would not be econom- 
 ical to obtain our total food supply from milk, it is 
 i^ood economy to use it freely in connection with other 
 foods to furnish part of the proteid of the diet. 
 
 The digestibility of milk varies very much with the 
 method in wdiich it is taken. If a small amount of 
 liquid rennet or of the junket tablets so commonly 
 found in the market, be added to a portion of warm 
 milk, a thick clot forms. This is similar to the process 
 that takes place in the stomach after milk has been 
 swallowed. Milk properly, then, so far as its diges- 
 tion is concerned, is a solid rather than a liquid food. 
 Its digestibility depends largely upon the way in which 
 this clot is formed. If the milk be swallowed rapidly, 
 so that the rennin acts upon a large mass at once, one 
 large clot is formed. If, on the other hand, the milk 
 be sipped slowly, or eaten from a spoon, the action is 
 slower and the curd is broken. 
 
 The same result in a more marked degree is obtained 
 by the addition of certain substances, such as lime- 
 water, to the milk ; or by the mixing of the milk with 
 bread, as is done in eating bread and milk. Some peo- 
 ple who cannot use milk in its ordinary form have 
 found that they could digest it without difficulty if a 
 cracker were rolled into fine crumbs and stirred into 
 the milk. The digestive juices that would act slowly 
 upon a large mass of curd, act readily upon the same 
 amount when it is broken into small clots. 
 
 r>oik'd milk has generally been considered less digeS' 
 
 Digestibility 
 
 Addition 
 to Milk 
 
86 
 
 FOOD AND DIETETICS 
 
 Boiled 
 Milk 
 
 Buttermilk 
 Koumiss 
 Skim-milk 
 
 tible than uncooked milk, but some experiments seem 
 to contradict this. The experiment station bulletin 
 states that when cow's milk has been boiled before it 
 is taken into the stomach it is likely to be precipitated 
 in a more floculent form. Hutchison says that it has 
 been found in the case of infants and calves that ster- 
 ilized milk which has been kept at or above the boil- 
 ing point for more than an hour is absorbed quite as 
 well as milk which has merely been boiled in the usual 
 way, and he concludes that boiling- does not appreciably 
 diminish the digestibility of milk. 
 
 On the other hand, the government bulletin states; 
 after acknowledging that the results of experiments 
 upon the subject are conflicting, that "the more com- 
 mon experience seems to indicate that cooking or heat- 
 ing the milk makes the proteids somewhat more 
 difficult for most persons to digest, but there are ex- 
 ceptions to this rule, if it be a rule, for there are per- 
 sons who cannot take fresh milk with comfort but with 
 whom boiled milk agrees very well." 
 
 In this case as in many others we must wait for a 
 larger number of experiments to be made before we 
 can make very dogmatic statements. 
 
 Buttermilk is considered an especially digestible 
 form of milk, while koumiss or fermented milk is of 
 still greater value in this respect. Skim-milk deserves 
 more general use than it has, since the proteid of the 
 milk nearly all remains in this, and it is for the proteids 
 
MILK 87 
 
 that we especially value the milk. Where skim milk 
 is sold at a low price, it is economy to use it freely in 
 cooking, supplying- the needed fat in a less expensive 
 form than cream. 
 
 The Compositioa of Milk 
 
 The composition of milk has already been stated in Casein 
 a general way. If we examine it more in detail, we 
 find that the proteids of milk consist chiefly of two: 
 casein or, as it is sometimes called, caseinogen. This 
 forms about three per cent of the total of the 
 milk. It is held in solution more or less completely by 
 the salts of lime present in the milk. \Mien acid is 
 added to the milk, or it becomes sour, this casein is 
 precipitated. When rennet is added the casein is 
 coagulated and is changed in chemical composition. 
 The scum that forms upon heated milk is chiefly 
 casein. 
 
 The other proteid present in milk is lact-albumen. Lact- 
 This coagulates when the milk is heated for a long 
 time. It is present in much smaller amount than the 
 casein, forming only about one-seventh of the total 
 proteid of the milk. 
 
 The sugar of the milk, forming between four and five wiik 
 per cent, is called lactose or milk sugar. It has two 
 important characteristics. It lacks the sweetness usu- 
 ally associated with the name of sugar, having only a 
 very slight sweet flavor, and it is considered the most 
 digestible form of sugar, apparently fermenting in the 
 
 Sugar 
 
88 
 
 FOOD AND DIETETICS 
 
 Fats 
 
 Mineral 
 Matter 
 
 stomach or intestines with much less case than do 
 other sugars. For both of these reasons it is particu- 
 larly suitable for the use of infants or invalids. The 
 commercial article is obtained from milk, and is sold 
 in the form of a fine white powder looking not unlike 
 
 pulverized sugar. Aside 
 from its use as a food 
 it is extensively used in 
 the preparation of pills. 
 The fat of milk is 
 present in the form of 
 an emulsion. If one 
 looks at a drop of milk 
 through the microscope 
 one sees a large num- 
 ber of tiny fat globules. 
 That the fat is so fine- 
 ly divided is a factor in 
 its digestibility, though 
 fat derived from milk, 
 either in the form of 
 cream or butter, is also 
 considered particularly 
 digestible. 
 
 The mineral matter of milk consists largely of 
 potash and lime salts, and of these salts the phos- 
 phates are the most abundant. These are important, 
 not only in the building of bone tissue, but also, 
 as lias been suggested before, in hokhng the casein 
 
 in ^^olution, 
 
 Fat Globules of Milk Magnified 
 200 Times. 
 
 a Skim Milk. 6 Whole Milk. 
 c Cream. 
 
MILK 89 
 
 Water forms about 87 per cent of milk, and its chief water 
 use in this form is in holding other materials in solu- 
 tion. To compare milk with other foods, we should 
 properly think of the solid ingredients alone, since 
 the water has no more food value than water in any 
 other form. 
 
 Milk readily undergoes many changes, some of them Souring 
 harmless and some more or less harmful. The most 
 common change is that of souring. Bacteria present 
 in the milk act upon the sugar and change it into lactic 
 acid. After a certain amount of this acid has been 
 produced, the growth of the bacteria is stopped, and 
 no further change in the sugar takes place, though 
 undoubtedly certain other changes take place both in 
 the fat and in the proteid. 
 
 There is no evidence that sour milk is unwholesome, use of 
 The objection to it seems to be chiefly one of taste. Its ^^ 
 use in cooking produces good results, and many pre- 
 fer it for some purposes to sweet milk since it seems 
 to produce a more tender product than does the sweet 
 milk. On the other hand, milk may under the action 
 of certain bacteria produce most harmful products, 
 and poisoning from these ptomaines is not uncommon 
 where milk has been handled in an uncleanly manner 
 and has been poorly cared for. A more serious dan- 
 ger from milk is that owing to the excellent food it 
 furnishes for almost all bacteria, it is frequently a 
 carrier of disease. Disease germs that in water would 
 not multiply and would probably live only for a short 
 
90 
 
 FOOD .IND DimETICS 
 
 Pure 
 Milk 
 
 Care of 
 Milk 
 
 Condensed 
 
 mm 
 
 time, multiply abundantly in milk. It is because of 
 the possibility of the presence of these harmful bac- 
 teria, rather than from any danger from sour milk, 
 that we guard our milk supply carefully. Each hour 
 that elapses between the milking of the cow and the 
 use of the milk by the consumer, increases the num- 
 ber of bacteria present. One cul)ic centimeter of milk 
 frequently contains from 400,000 to several million 
 bacteria. 
 
 Efforts to guard the milk supply have been directed 
 in two wa}'s. The sterilization or pasteurization of all 
 milk is often recommended ; but a more satisfactory 
 method would seem to be the insuring of cleanly con- 
 ditions upon the dairy farm where the milk is pro- 
 duced. The next essential after cleanliness is that the 
 milk should be cooled rapidly wdien first milked, since 
 the lower temperature makes the fluid less favorable 
 for the growth of germs. 
 
 In the household milk should be kept in perfectly 
 clean vessels, and should be loosely, not tightly, cov- 
 ered, in order that there may be access of air to it, 
 since the absence of fresh air favors the growth of 
 certain putrefactive organisms. The entirely open 
 vessel is only allowable in perfectly clean surround- 
 ings, not only free from dust, but with no strong 
 flavoring substance near from which odors could be 
 absorbed. 
 
 One form in which we often get milk is that of 
 evaporated or condensed milk, This is simply milk 
 
MILK 
 
 or 
 
 from which most of the water has been removed, and 
 wdiich has been made sterile by heating to a high tem- 
 perature. It has usually been sweetened, and the sugar 
 acts as a preservative. While it is a convenient form 
 for use when fresh milk is not obtainable, its large 
 amount of sugar renders it somewhat undesirable as 
 a common article of diet, and also makes it unfit for 
 many cooking purposes. 
 
 There is being put upon the market now milk 
 powder that seems to consist chiefly of the curd of the 
 milk dried and ground. With the addition of water 
 it forms a very fair substitute for milk. 
 
 Milk is perhaps more often adulterated than any 
 other common article of diet. The most common form 
 of adulteration is that of skimming or removing part 
 of the cream. This can easily be detected, because it 
 increases the specific gravity of the milk. To coun- 
 terbalance this, water, which is slightly lighter than 
 milk, is added in such proportion that the twice adul- 
 terated milk gives the same test as if it had not been 
 tampered with at all. 
 
 Another adulteration that is sometimes practiced is 
 that of adding coloring matter to the milk. This is 
 usually done in order to conceal the blueness of the 
 milk, when it has been watered. 
 
 Preservatives are frequently used. Of these boric 
 acid is probably the least harmful, though some au- 
 thorities contend that formaldehyde in the minute 
 quantities in which it is used has no physiological 
 
 Milk 
 Powder 
 
 Adulteration 
 
 Preservatives 
 
92 ^OOD AND DIILTETICS 
 
 effect. A milk that will stand in a warm place for 
 some hours and show no tendency to sour is open to 
 the suspicion of having- hecn treated in some such 
 way. Ordinary cooking soda is sometimes added to 
 neutralize the acidity that may be present because of 
 the age of the milk. Salicylic and benzoic acids are 
 sometimes found, while formaldehyde is used most of 
 all. 
 
 MILK PROBUCTS 
 
 Butter The importance of milk is hardly greater than that 
 
 of its two chief products, butter and cheese. Butter 
 consists chiefly of the fat of the milk with a small 
 amount of water, of casein and of salt, with sometimes 
 a little milk sugar. The average amount of fat con- 
 tained is 82 per cent. The fats which are present may 
 be put into two classes: Those derived from the so- 
 called "fixed" fatty acids, and those from the volatile 
 fatty acids. The fixed fatty acids are present in the 
 form of stearin, the chief ingredient in beef fat, and 
 of palmitin and olein. The amount of the volatile 
 acids present differentiate butter from most of the 
 other fats that we commonly use as food. The flavor 
 of butter is produced apparently by the action of 
 bacteria upon the cream, the different flavor of butter 
 at different times of the year coming largely from 
 differences in the kind and amount of bacteria that 
 find their way into the milk. The- "ripening" of the 
 cream is often induced by artificial cultures of the 
 proper bacteria. Many buttermakers abroad and in 
 
BUTTER 
 
 93 
 
 some sections of our own country, depend entirely 
 upon these bacterial cultures for the production of 
 their butter flavor. 
 
 The rancidity of butter may be produced by changes 
 taking place in the casein that is present, or from a 
 decomposition of the fats themselves. Cooking les- 
 sens the digestibility of butter as it does that of other 
 !ats, probably because of the decomposition that takes 
 place when fats are subjected to a high temperature, 
 and the consequent freeing of irritating fatty acids. 
 
 The adulteration of butter consists chiefly in a sub- 
 stitution of other substances, either in whole or in 
 part, for the butter fat, or of an inferior and "doc- 
 tored" article. The coloring of butter is almost univer- 
 sal, but it is so generally accepted that it can hardly 
 be classed as an adulteration, although it surely shows 
 a false standard in foods when we insist upon buying 
 a deep yellow compound colored with annatto or some 
 other foreign material instead of the delicate straw- 
 colored substance that most natural uncolored butter is. 
 
 The substitutions spoken of are chiefly either what 
 is called renovated butter, or oleomargarine. Reno- 
 vated butter is made by taking different lots of stale 
 or rancid butter, melting it, allowing the curd to settle, 
 and re-churning the fat with a small amount of milk. 
 The product is certainly better than the rancid butter, 
 but it cannot compare in flavor and in wholesomeness 
 with fresh butter, and certainly should not be sold as 
 such. 
 
 Changes 
 
 Adulteration 
 
 Renovated 
 
 Butter 
 
94 rOOD AND DIETETICS 
 
 JButterine Oleomargarine, or ])utterine, is made by clarifying 
 
 the fat of beef and churning it in milk. It differs 
 from butter in its composition in that it contains 
 practicall}' no curd, and is lacking in the volatile fatty 
 acids that are present in the butter and character- 
 istic of it. It is a cheaper product than butter, and 
 the temptation to put it upon the market under the 
 name of butter has consequently been great. There 
 is absolutely no reason, however, why, sold under its 
 own name, it should not be a very general article of 
 use. There seems nothing to show that it is materially 
 less digestible than butter itself ; it does not grow 
 rancid with the ease that butter does, and it is made in 
 a perfectly cleanly and wholesome way, certainly so far 
 as the best quality of it is concerned. Even if it is 
 artificially colored, this is no worse than is true of 
 butter. The difference in taste between it and butter 
 is rather in an absence of the aroma that we find in the 
 best butter, than in any disagreeable flavor present. 
 Indeed, although each person thinks to the contrary 
 in regard to himself, few people are able to distin- 
 guish it from butter by taste. It may be used in almost 
 every way as a butter substitute. It is perfectly satis- 
 factory to use in the making of sauces or upon vege- 
 tables or meat. It does not make so light a cake as 
 butter, and is not satisfactory for this purpose, except 
 that in a plain cake it may be substituted for part 
 of the butter ; and it cannot be used in candy making 
 as, for some reason, it fails to combine with the other 
 
CHEESE OS 
 
 materials and always separates out upon cooling-. 
 Since it is so much cheaper than butter it would be 
 well to use it as a substitute for part of the more ex- 
 pensive material. 
 
 The present law in regard to it has lessened its 
 sale to a great extent since it can no longer be artifi- 
 cially colored, but it is certainly only prejudice that 
 prevents our accepting a pure white fat instead of a 
 bright yellow one. 
 
 Cheese, so far as nutritive value is concerned, stands cheese 
 almost at the head of our list of foods. Since it is 
 made from the curd of the milk, and the water has 
 largely been disposed of in the whey, while the fat is 
 carried down with the curd, we have the most im- 
 portant part of the milk solids in a condensed form. 
 The composition of the different varieties of cheese 
 varies to quite an extent, but in a rough way we may 
 say that cheese is one-third proteid, one-third fat and 
 one-third water. Mineral salts are abundant as well, 
 while a small amount of milk sugar Ls sometimes 
 present. 
 
 Cheese is prepared by the addition of rennet to cheese 
 milk. Coloring matter is generally added, and salt. Makmg 
 After the curd has set, it is cut in small pieces and the 
 whey allowed to drain off. The curd is then put into a 
 press and allowed to remain for a few hours. After 
 this the real curing or ripening of the cheese begins, 
 and this process is allowed to go on for months in 
 order to develop the flavor. This flavor is produced 
 
rOOD AND DIETETICS 
 
 Pigestibility 
 
 Effects of 
 Cooking 
 
 by the action of bacteria, different varieties of bac- 
 teria giving us the different flavors of the various 
 kinds of cheese. 
 
 While there is no question as to the nutritive value 
 of cheese, there is more doubt as to its digestibility. 
 In many countries cheese is used largely as a substi- 
 tute for meat, and wherever it can be digested this is 
 certainly a rational thing. Some people who have 
 delicate digestions have no difficulty in digesting 
 cheese, while others find it an extremely indigestible 
 food. One difficulty seems to be that the cheese is 
 frequently not chewed enough, and the digestive 
 organs have to cope with lumps of the material. 
 Cheese generally proves more digestible if it is finely 
 divided and mixed with some starchy material like 
 bread crumbs or macaroni. Another factor in its 
 digestibility is the temperature at which it is cooked. 
 Like all proteid foods, it is toughened and hardened by 
 a high temperature. This is very evident in the case 
 of such a dish as a Welsh rarebit, where over-cooking 
 produces a tough, stringy, most indigestible mass. In 
 combining cheese with such a dish as macaroni it is 
 well not to allow the cheese to be at the bottom or the 
 top of the dish, but to protect it from the high tem- 
 perature by putting it between the layers of starchy 
 material. 
 
 Matthieu Williams, in his chemistry of cookery, 
 suggests the use of a little l;icarbonate of potash, the 
 old-fashioned salaratus, to make the cheese more 
 
CHEESE 97 
 
 soluble and therefore more dig^estible. Sometimes 
 after the cheese has become tough from the action of 
 too high a temperature, it may be again made soft by 
 the addition of this substance, or of baking soda. 
 Hutchison suggests that the disagreeable effect that 
 cheese has upon some people may be due to small 
 quantities of fatty acids produced in the process of 
 ripening. The philosophy of the use of cheese at the 
 end of a dinner seems to be that the cheese in small 
 quantities aids the digestion of other foods, even 
 though it is not always easily digested itself. Wher- 
 ever, then, cheese can be used and digested without 
 difificulty, it forms an excellent article of food, one that 
 should be used more freely than is done at present. 
 
98 
 
 FOOD AND DIETETICS 
 
 Importance 
 
 CEREALS AND THEIR PRODUCTS 
 
 The most important of all our vegetable foods are 
 without doubt cereals. Not only do they contain a 
 large amount of nutriment, chiefly, but by no means 
 wholly, in the form of carbohydrates, but their areas 
 of growth are widely distributed, and their power of 
 adaptation to different climates and conditions is usu- 
 ally great. This alone would render them exceedingly 
 
 Maize 
 
 PROBABLE NATIVE HOME OF THE GRAINS. 
 (From Corn Plants By Fredric LeRoy Sargent.) 
 
 important as food for the human race. Of them all 
 wheat is undoubtedly the most important from its wide 
 distribution and its power of adaptation to different 
 conditions. Rice follows closely in importance, while 
 corn, oats, rye, barley and millet each have an impor- 
 tant place in the food of the world. The home of the 
 
CEREALS 
 
 99 
 
 cereals seems for the most part to have been Central 
 Asia, nearly all, except rice and corn, originating 
 there. Corn is supposed to have originated in Mex- 
 ico. From these centers their production has spread 
 through all parts of the world. 
 
 A comparison of the composition of some of the 
 different cereals in forms commonly used is given in 
 the following table: 
 
 Composition of Cereals. 
 
 Wheat flour (entire) . . 
 
 Cornmeal 
 
 Oatmeal 
 
 Rye flour 
 
 Barley meal and flour 
 
 Barley (pearled) 
 
 Rice. 
 
 Per Cent 
 
 Per Cent 
 
 Per Cent 
 
 of 
 
 of 
 
 of Carbo- 
 
 Water. 
 
 Proteld. 
 
 hydrate. 
 
 11.4 
 
 13.8 
 
 71.9 
 
 12.5 
 
 9.2 
 
 75.4 
 
 7.3 
 
 16.1 
 
 67.5 
 
 12.9 
 
 6.8 
 
 78.7 
 
 11.9 
 
 10.5 
 
 72.8 
 
 11.5 
 
 8.5 
 
 77.8 
 
 12 3 
 
 8. 
 
 79. 
 
 Per Cent 
 of 
 
 Fat. 
 1.9 
 1.9 
 
 1.1 
 .3 
 
 Wheat derives its special importance from the fact 
 that it will grow in so many different climates and 
 under so many varying conditions. It may be sown 
 either in the fall or in the spring, and receives its name 
 of winter or^spring wheat, according to the time of the 
 planting. ]\Iany varieties are found, such as red 
 wheat and white wheat, hard and soft wheat. 
 
 The hard wheats contain a larger proportion of 
 gluten, and therefore a smaller proportion of starch 
 than do the soft wheats. Wheat from which macaroni 
 is manufactured, is an exceedingly hard variety. Suc- 
 cessful attempts have been made within a few years to 
 grow macaroni wheats in this country, and much of it 
 is now produced in Dakota. Though hard wheat is 
 
 Composition 
 
 Wheat 
 
 Varieties 
 
THE PRINCIPAL GRAINS. 
 
 CReUrawn fruui turn riaiits.) 
 
CEREALS 
 
 101 
 
 used chiefly for making pastes like macaroni, excellent 
 bread can be made from it also, as is shown by ex- 
 periments made at the So, Dakota Agricultural Col- 
 lege. 
 
 Winter wheats as a rule are 
 softer than spring wheats. So- 
 called pastry flour is made from 
 the softer wheats. Much of our 
 bread flour is now made from 
 mixtures of winter and spring 
 wheat, and great care is exercised 
 in the combining of these in order 
 to keep an even standard. 
 
 The process of manufacturing 
 flour is carried out differently by 
 different manufacturers, so far as 
 its details are concerned, but the 
 main features are the same. The 
 wheat as it comes to the mill is 
 first of all cleaned, by screening to get rid 
 of any large foreign substances that may be 
 present in it, and by "scouring" to get rid 
 of the fine dirt that may adhere. The next process 
 is that known as breaking. The wheat is cut by- 
 corrugated iron rollers provided for the purpose. 
 There are generally five breaks iil all. Each "break" 
 is put through a number of siftings. The meshes of 
 the bolting cloth thmugh which this sifting is done are 
 graduated in size, and the products accordingly vary in 
 
 Section of a Gniiu 
 
 of A\1ie:it. 
 
 From a ]\I:iine Kxp. 
 
 .'Station Bulletin. 
 
 Flour 
 
 Bolting 
 
102 
 
 FOOD AND DIETETICS 
 
 Scalping 
 
 Mixing 
 
 and 
 
 Testing 
 
 fineness. The finest particles are calbd the dustings, 
 the coarsest are the scalpings, while between these are 
 the middlings, — germ, medium and fine. The scalpings 
 from the first break undergo a second breaking and 
 are again separated by sifting as in the first break, 
 
 SECTIONS OF A WHEAT GRAIN SHOWING THE STRUCTURE: 
 AND DIFFERENT PARTS. 
 (From Original Drawings.) 
 
 and this process continues through all the breaks. 
 
 The flours on the market are made from mixtures of 
 the products of the dififerent breaks. When a flour is 
 mixed it is tested by making a portion of it into a 
 small loaf and baking it, and comparing this loaf with 
 that made from some standard flour. The scalpings 
 from the last break constitute the bran. This is al- 
 
CEREALS 
 
 103 
 
 most wholly cellulose and is therefore not digestible 
 by human beings, but much of the so-called Graham 
 flour on the market is simply a mixture of white flour 
 with some of this bran. True Graham flour is really 
 wheat meal made by grinding the entire kernel. 
 
 So-called whole wheat flour contains the inner 
 portion of the bran only. The cellulose is very finely 
 divided, so that it is less irritating to the digestive 
 organs than the bran in Graham flour. 
 
 There is little difficulty today in obtainijig good 
 flour, but the different brands vary in composition, 
 and so do different lots of the same brand, in spite 
 of the eiifort to keep them constant. This means 
 that a different treatment must be used. It is well, 
 then, in the household, to experiment a few times 
 wath a new lot of flour before condemning it as poor 
 and returning it. 
 
 Some false standards have been set up in regar,! 
 to flour. The best bread flour is not pure white, but 
 yellowish in tint. It readily retains the impression of 
 the fingers, if a little is pressed together in the hand. 
 It always has a slightly gritty feeling, while pastry 
 flour is much smoother and more velvety to the 
 touch. 
 
 Within a few years the use of cereals as breakfast 
 foods has become general. We have now not only the 
 standard meals, which have been used for a long time, 
 but a multitude of patent preparations as well. The 
 Maine agricultural experiment station found that of 
 fifty varieties of cereals purchased in the market, only 
 
 Whole 
 Wheat 
 Flour 
 
 Standards 
 
 Breakfast 
 Foods 
 
104 FOOD AND DIETETICS 
 
 about twenty had been on sale for more than three 
 years. Many of these are only new in name, or differ 
 very slightly from those before used. Within a short 
 time there has been added to our list of breakfast 
 cereals many that claim to be predigested foods, and 
 some that make absurd claims with regard to their 
 wonderful food value, while others stand for what they 
 are, without pretence. 
 
 Probably there is comparatively little to choose be- 
 tween different preparations of the same grain, so far 
 as their chemical composition goes. The analysis of 
 the uncooked food, however, by no means represents 
 the composition of the cereal as we eat it. An analysis 
 of boiled oatmeal, for instance, gave: Water, 84.5 per 
 cent ; protein, 2.8 per cent ; carbohydrate, 1 1.5 per cent ; 
 - fat, 5 per cent. Comparing this with the analysis of 
 oatmeal given on p. 99, we find only about one-sixth 
 the per cent of nutritive material, with a correspond- 
 ing increase of water. A cereal that would absorb a 
 greater weight of water would show still greater varia- 
 tion, 
 wpestibiiity The digestibility of the cereals is influenced by the 
 of Cereals coarseness of the particles. The coarser foods are 
 highly desirable in many cases, especially where a slug- 
 gishness of the intestines exists, and in other cases are 
 very irritating to the delicate lining of stomach and 
 intestine. Individual needs must determine the use of 
 each. 
 
 Most of the cereals, even those that are steam 
 
CEREALS los 
 
 cooked, need much more cooking than is ordinarily Jo^^ing' 
 given them in order to sufficiently hydrate the starch. 
 Of the foods supposed to be ready to eat, it is difficult 
 to speak definitely, for lack of careful experimentation. 
 In most of them a certain proportion of the starch 
 has been converted into dextrin and sugar. Two 
 questions arise in regard to this. Has the starch been 
 sufficiently changed so that it no longer is indigestible 
 as uncooked starch ; and is it desirable to have the 
 starch digested ? There seenis to be a tendency in our 
 modern life to depend too largely upon predigested 
 foods, particularly in the case of children. This means 
 a tendency toward the lessening of the power to digest. 
 It is certainly a question whether it is not best to take 
 our starch undigested but in such a form that it can 
 be easily acted upon by the digestive juices, rather 
 ban to have the work done outside the body. 
 
io6 
 
 rOOD AND DIETETICS 
 
 History 
 
 Kinds of 
 Bread 
 
 BREAD 
 
 Bread was one of the earliest foods of man. That it 
 was used long before history was written, the discover- 
 ies of modern times have shown us. In Switzerland, 
 in the lake dwellings of prehistoric times, there have 
 been found not only stones for grinding meal and bak- 
 ing bread, but even bread itself, in the form of round 
 cakes. The first mention of bread in literature is in 
 Genesis, in the words of Abraham to the angels, "I 
 will fetch a morsel of bread." The Egyptians knew 
 the art of breadmaking, and baked loaves and cakes in 
 great variety of form and flavor. One ancient Greek 
 writer names sixty-two kinds of bread in use ; and in 
 Rome there were many bakeries, where not only was 
 the baking of bread done, but the grain was pounded 
 and sifted, to prepare it for use. 
 
 In our own day bread is found in a great variety of 
 forms, many of them characteristic of certain nations; 
 familiar examples are the black bread of Germany, the 
 oat cakes of Scotland, the hard rye cakes of northern 
 Sweden, baked only twice in the year, and the passover 
 cakes or unleavened bread of the Jews. 
 
 Bread forms the staple food of a large section of the 
 human race, and is often the only means of subsistence 
 of the very poor. Mr. Goodfellow, in some investiga- 
 tions made in London, found that in the worst districts 
 fifteen per cent of the children ate only bread for the 
 
BREAD 107 
 
 twenty-one meals of the week, while forty per cent 
 more had other food only two or three times a week. 
 
 It is essential that so universal a food should be nu- ^°ll^ 
 tritious, palatable, and digestible. To fulfil these con- 
 ditions, the flour used must be rich in nutriment ; the 
 bread must be light and po/ous, that as large a surface 
 as possible may be exposed to the digestive juices ; 
 and the cooking must develop the flavor, and render 
 the food materials assimilable to the greatest possible 
 extent. The necessary ingredients of bread are flour 
 of some variety and liquid for moistening it. Salt 
 for flavoring is required by almost every one, and to 
 most of us the term bread implies some agent for light- 
 ening the dough. 
 
 Wheat is the flour most commonly employed not wheat 
 only because of its widespread growth but because of 
 the presence in it of the proteid called gluten, or more 
 strictly speaking, of the proteids that upon the addition 
 of water form gluten. Gluten is an important aid in 
 the making of bread light in that being an elastic tena- 
 cious substance it retains the gas as it is formed in the 
 dough. In the process of cooking, the gluten hardens 
 and thus enables the loaf to retain its shape. This 
 function of gluten may be compared to that of soap 
 in the water from which soap bubbles are blown. 
 
 If some gluten be prepared from flour, as in the ex- 
 periment on page ,41, and baked, the value of this sub- 
 stance in lightening the dough will be appreciated. 
 
io8 
 
 FOOD AND DIETETICS 
 
 Other 
 Breads 
 
 Of the other cereals, rye makes the lightest bread as 
 its proteids form with water a sticky substance not so 
 elastic or tenacious as the gluten of the wheat, but 
 sufficiently so as to retain much gas. Corn flour, 
 however, makes only a flat and crumbly loaf unless 
 egg be added to increase the elasticity of the dough. 
 
 The most desirable bread flour is one rich in gluten. 
 
 Leavening 
 Agents 
 
 DIAGRAM SHOWING COMPOSITION OF A 
 I^OAF OP BREAD. 
 
 (After Hutchison.) 
 
 Even very hard macaroni wheat may be made into 
 excellent bread as has been shown at the South Dakota 
 Agricultural Experiment Station. If a flour poor in 
 gluten and rich in starch is to be used a stiffer dough 
 must be made than with the opposite conditions. In 
 spite of the efforts of the manufacturers to maintain a 
 constant standard in flour each barrel varies somewhat, 
 and slightly different treatment may be needed. 
 
 Many different agents for lightening the dough have 
 been used at various times. The ancient leaven was 
 made by allowing flour and water to stand in a warm 
 
BREAD 109 
 
 place till it fermented. Part of this dough was used 
 to start the fermentation in a new mixture of flour and 
 water. In some sections of our own country "salt 
 rising-" bread is commonly used. In England aerated 
 bread, made by foxing carbon dioxide under pressure 
 into the dough, has been advocated and used to some 
 extent. 
 
 The most common method of lightening the loaf, in Yeast 
 
 , . ... /. ^ ^y Bread 
 
 this country at least, is by means 01 yeast. 1 east 
 comes into the household in three forms, that of liquid 
 yeast, compressed, and dried yeast. The last is most 
 often used by those too far from the source of supply 
 to obtain compressed yeast in good condition. It 
 makes satisfactory bread, but the process is a long one, 
 as time must be allowed for the dry yeast to take up 
 water and renew its life processes. Liquid, or home 
 brewed yeast, prepared usually from potato with the 
 water from a few hops, frequently with the addition of 
 sugar and flour, and the whole fermented by means of 
 the addition of a "pitching" yeast, is much less used 
 than formerly. Aside from the trouble of preparation, 
 it is open to the disadvantage of usually containing 
 many bacteria and wild yeasts. Many think, however, 
 that the fine texture and delicious flavor of old fash- 
 ioned home made bread was due in part to the use of 
 this yeast. 
 
 Compressed yeast is a by product of the distillery or 
 
 Compressed 
 
 the brewery. It is skimmed from the top of the for- Yeast 
 
FOOD AND DIETETICS 
 
 Chemical 
 Process 
 
 Methods 
 of Making 
 
 menting liquor, is washed, strained, mixed with a small 
 amount of starch and pressed into large cakes. At the 
 distributing centers it is cut and wrapped in foil and 
 sold for one or two cents, according to locality. It is, 
 on the whole, the most satisfactory yeast to use in bread 
 making, though it is rarely, if ever, free from the bac- 
 teria that cause the souring of bread when conditions 
 are right for their growth. 
 
 The changes that take place in the process of bread- 
 making are largely those of fermentation. Some of 
 the starch of the flour is changed to sugar, and the 
 sugar is broken up into alcohol and carbon dioxide. If 
 the fermentation goes too far the alcohol is changed 
 to acetic and other acids and the bread becomes sour. 
 Yeast is not the sole agent working; bacteria and not 
 veast are responsible for the souring, while the change 
 of starch into sugar is probably accomplished by bac- 
 teria or some enzyme (ferment) present in the flour. 
 
 Chemical changes, such as the change of some of the 
 starch into dextrin and some of the sugar into cara- 
 mel, which takes place especially in the crust of the 
 bread, are caused by the heat of the oven, while the 
 same agent is responsible for the driving ofT of the 
 alcohol and carbon dioxide present. 
 
 A few years ago bread was almost invariably made 
 by what is called the long process. A small amount of 
 /east was used and the bread was allowed to rise over 
 night. T\^ow more often the bread is set in the morning 
 and the whole process is carried through in six hours. 
 
BREAD 1 1 1 
 
 The advantage of the latter method is that it makes it 
 possible to watch the process and regulate the temper- 
 ature more carefully than can be done if the bread is 
 set at night. As temperature is an important factor in 
 the growth of the yeast, too low a temperature hinder- 
 ing its growth, and too high a temperature favoring the 
 growth of the acid producing bacteria, this is a distinct 
 advantage. The most favorable range of temperature 
 is from 75 degrees to 90 degrees F. 
 
 On the other hand, the long process produces a 
 loaf of a texture preferred by many, and some ex- 
 periments tend to show that it may be slightly more 
 digestible. 
 
 There has been discussion for many years over the Graham 
 comparative value of graham, whole w^heat and white wheat B^ead 
 bread. Several years ago graham bread was urged 
 upon every one as the only ^satisfactory bread. After 
 a time the conclusion was reached that the coarse par- 
 ticles of the graham fiour were too irritating to the in- 
 testinal wall, and its use was discouraged except where 
 this very irritation was desirable, as in case of consti- 
 pation. Then came the era of whole wheat bread, show- 
 ing like the graham a high percent of nutriment. At 
 one time it seemed to be considered almost a crime to 
 use any other bread than this. The presence of phos- 
 phates in larger amount than in white flour and the 
 higher proportion of proteid seemed a sufficient reason 
 for encouraging its use by ever}^ one. 
 
 The latest government investigation? have proved 
 
II? 
 
 FOOD AND DIETETICS 
 
 White Bread 
 
 More 
 
 Kutritious 
 
 Combinations 
 with Bread 
 
 that this was a false assumption. While from the chem- 
 ical standpoint it is true, from the physiological one it 
 is not. Less of the material of whole wheat hread 
 is available for use in the body, or in other words, a 
 larger proportion is excreted in the feces than in white 
 bread, so that whole wheat is not superior to white 
 bread in real luitrit'ivc value. It is hurried through the 
 intestines more quickly and thus given less chance for 
 absorption than is true of the white bread. The 
 phosphates are so closely attached to the outer cellulose 
 wall that they probably do not furnish any more ma- 
 terial to the body than is obtained from bread made of 
 white flour. 
 
 Although bread contains a fair proportion of proteid, 
 about 9.2 per cent, it has too little proteid, too little 
 fat, and too large an amount of starch to form in 
 itself a perfect food. Instinctively we supplement it. 
 with these lacking ingredients. We use butter on 
 our bread, we eat bread with meat, or we combine 
 it with milk. In either case we are supplementing it 
 admirably. Eggs, too, contain the lacking fat and 
 proteid. Nuts eaten with bread and cheese so much 
 used in many countries have scientific sanction. 
 
 Good bread is one of the cheapest, most nutritious, 
 most easily and completely digested of all foods and 
 well deserves its title the "Staff of Life." 
 
SUGAR 
 
 "3 
 
 SUGAR AS FOOD 
 
 ]\rrs. Abel, ill the govcniiiient i)an)phlct Sugar as 
 Food, calls attention to the fact that the consumption 
 of sugar is everywhere increasing. In England 
 eighty-six pounds per capita and in the United States 
 sixt\-four pounds per capita were consumed in the 
 year 1895. This means simply the sugar that is manu- 
 factured in this form, and does not include that taken 
 in the form of various fruits and vegetables. 
 
 The desire for sugar seems to be universal, and 
 the fact that children always crave it would seem to 
 be an indication that it is needed in their diet. On the 
 < ther hand, we must remember that the manufacture 
 of sugar is comparatively a late matter, and that 
 earlier, a hundred years or so ago. people got along 
 without it except as naturally present in their foods. 
 
 in using sugar it must be remembered that it is a 
 highly concentrated food, and that it is therefore not 
 lo be used in such large quantities as would be right 
 m the case of foods containing' a large amount of 
 water. It seems best fitted for assimilation by the 
 body when it is diluted or used with other foods that 
 give it the necessary Inilk. It is also an error to use 
 sugar, as is so often done, with other foods in such 
 a way or in so large an amount as to disguise the 
 natural flavor of these foods. 
 
 One of the advantages of sugar is that it passes 
 quickly into the circulation, so that the energy obtainc(l 
 
 Consumption 
 
 Concentrated 
 Food 
 
"4 
 
 FOOD AND DIETETICS 
 
 Sources 
 ::f Sugar 
 
 Glucose 
 
 from it is available in a ven- short period. It is par- 
 ticularly fitted for food in cases of exhaustion. 
 
 The bad effects of sugar are ascribed by Mrs. Abel 
 to its use in too great quantity. Three or four ounces 
 a day can be disposed of l\v the healthy adult with 
 impunity. It has generally been thought that sugar 
 is injurious to the teeth, but this also is denied. Any 
 bad effects of this kind are due not to sugar in the 
 diet, but to the allowing particles of sweet food to re- 
 foi' acid fermentation and possible injury to the 
 teeth. 
 
 The source of most of the sugar used until a 
 few years ago was the sugar cane. Now over half 
 of the sugar used in the world is obtained from the 
 sugar beet. In 1904, only about 10 per cent of the 
 sugar used in the United States came from the sugar 
 beet. There has been an impression that beet root 
 sugar is less satisfactory for many purposes than the 
 cane sugar, but it is identical chemically. It may be 
 true in some cases that the beet root sugar has not been 
 completely purified, and that these impurities give an 
 odor to the sugar upon boiling, and possibly affect some 
 of its uses ; but the properly prepared sugar may be 
 used in every way that sugar from the sugar cane may ; 
 indeed, it is impossible to distinguish between them. 
 
 Another sugar of which we hear a good deal is 
 glucose. This has been made much of as an adul- 
 terant, ])articularly of candy. There is. however, no 
 rvason to think that glucose is less digestible or le§§ 
 
SUGAR 
 
 easil}- assimilated than cane sugar. Indeed, it is more 
 nearly ready for assimilation. When we boil sugar 
 for any length of time in the presence of an acid, we 
 change a certain amount of the sugar into glucose. 
 Candy that will stretch we may be sure contains at 
 least some of its sugar in this form. If glucose is pure 
 and properly prepared there is no rtason to fear it as 
 an adulterant of candv. The cheap coloring matter 
 and flavors that are used in some of the cheap candies 
 are more to be feared, since some of them are harmful. 
 
 It is possible that since glucose goes so rapidly into 
 circulation it may overload the system more readily 
 than would plain sugar, and it is more easily fer- 
 mented. 
 
 Maple sugar, regarded as a delicacy, is simplv cane 
 sugar plus the flavoring matters found in the maple 
 tree. Milk sugar is generally considered the most 
 easily digested form of sugar and it less easily under- 
 goes fermentation. 
 
 Cane sugar is on the market in various forms. 
 Ordinary powdered sugar is, of course, the same sub- 
 stance as granulated sugar, but more finely ground. 
 This is oftf^n considered adulterated because it is less 
 sweet than the granulated form, but the lack of sweet- 
 ness is due to the finely divided condition. A very 
 simple test will serve to show the presence of adulter- 
 ants since these would probably be either some form 
 of porcelain clay, or starch. If the sugar dissolves in 
 water neither of these can be present, 
 
 Maple 
 Sugar 
 
 Powdered 
 Sugar 
 
ii6 
 
 FOOD AND DIETETICS 
 
 Slolasses 
 
 Effect 
 
 on Diet 
 
 of Use 
 
 of Sugar 
 
 The brown sugars that we use are simply cane sugar 
 that has not been decolorized, or has been only par- 
 tially so treated. 
 
 Molasses formerly was obtained as a bi-product in 
 the manufacture of sugar, and was the part of the 
 sugar-cane juice that would not crystallize, containing 
 a large per cent of glucose. With modern methods 
 of work and with the coming in of beet sugar, 
 whose molasses has such a strong flavor that it cannot 
 be put ui)on the market, a manufactured molasses came 
 into use. The commercial molasses of the present day 
 is frequently glucose, prepared from starch, colored 
 and flavored with a small amount of molasses from 
 the sugar factories. Sometimes the light molasses 
 has been bleached, and the bleaching agents, unless 
 completely removed, may be injurious. Sorghum 
 molasses is also used in some sections. 
 
 One comparison in regard to the addition of sugar 
 to the diet may be interesting. In the case of milk, it 
 has been found that an addition of this in any large 
 amount to the diet means a corresponding decrease 
 in the amount of other foods used. This seems not 
 to be true of sugar. When sugar is furnished freely 
 in abundance, it does not decrease the use of other 
 foods, but sometimes by adding to the flavor of these 
 actually increases thier consumption. On the other 
 hand, the desire for sugar often marks an inadequate 
 diet, 
 
FOOD AND DIETETICS 
 
 PART II 
 
 Read Carefully. The following- U. S. Government Bul- 
 letins should be read in connection with this lesson: No. 
 34, Meat Composition and Cooking-; No. 85, Fish as Food; 
 No. 128, Eg-g-s and their Use as Food; No. 1-i, Milk as Food; 
 No. 112, Bread and the Principles of Bread Making; No. 93, 
 Sugar as Food. These may be obtained free by addressing- 
 the Department of Agriculture, Washington, D. C. Place 
 your name and address on the first sheet of the test. 
 Leave space between answers. Make your answers full 
 and complete. 
 
 1. What is the relative vaUic of animal and vege- 
 
 table foods? 
 
 2. What are the chief nutrient ingredients of meat? 
 
 How may the presence of some of these be 
 shown? What reasons are there for cooking 
 meat ? 
 
 3. Compare clear soup, beef broth, and beef jiiice 
 
 as to their nutritive value. 
 
 4. What meat substitutes may be used in the daily 
 
 diet, and how does their value compare with 
 that of meat? 
 
 5. In what ways does milk satisfy the require- 
 
 ments of a perfect food? How does it fail? 
 
 6. What is the approximate composition of milk? 
 
 Under what conditions is its free use econom- 
 ical? 
 
 7. Give the composition of butter. How does 
 
 cooking affect its digestibility? 
 
 8. What is renovated butter? How may oleomar- 
 
 garine be used and how does it compare with 
 butter in wholesomeness? 
 
 9. Describe the process of chec?^ making. 
 
FOOD AND DIETETICS 
 
 10. What is the food vahie of cheese? With what 
 
 foods should it be combined? 
 
 11. What can \'ou say of the vakie of the cereals as 
 
 food? 
 
 12. If scales are available weigh out a portion of 
 
 rice (about V4 cup), boil, and weigh again. If 
 the scales are not at hand, measure the rice 
 carefully, before and after cooking. How does 
 the composition of the cooked rice differ from 
 that of the uncooked? Repeat the experiment 
 with a potato and compare results. 
 
 13. Why is wheat so extensively used? \Miat is 
 
 its especial value in bread making? 
 
 14. What are the chief steps in the manufacture of 
 
 flour? 
 
 15. What are the tests for a good flour? Why is 
 
 a flour high in gluten desirable for bread? 
 
 16. W'hat are the characteristics of good bread? 
 
 17. Compare the nutritive value of whole wheat and 
 
 white bread. When is graham bread valu- 
 able?' 
 
 18. What kinds of yeast are in common use? What 
 
 are the advantages and disadvantages of each? 
 
 19. State the chief changes that take place in the 
 
 process of bread making and baking. 
 
 20. What is the value of sugar as food? How does 
 
 beet sugar differ from that obtained from the 
 cane? ^^'hat can you say of the adulteration 
 of sugar? 
 
 21. Ask one or more questions on this lesson. 
 Net^.'^After eompl^ting the test, sign your fuU namo. 
 
FOOD AND DIETETICS 
 
 PART III 
 
FOOD AND DjeTETICS 
 
 PART 111 
 
 VEGETABLES 
 
 An increasing importance is coming to be attached 
 to the nse of vegetables and fruits in the diet. Not 
 onl\- vegetarians but many others have found from 
 experience that it is possible to live largely upon vege- 
 table food, while those who use meat freely lay great 
 stress upon the vegetable accompaniments whether in 
 the form of salads or of cooked vegetables. 
 
 A study of vegetables from the standpoint of bot- 
 any would implv their classification according to the 
 parts of the plant used ; whether leaf, as in the case of 
 lettuce, cabbage, spinach ; stem, as in celery, aspara- 
 gus, potato (a tuber, or underground stem) ; root, as 
 in beet, carrot and sweet potato; flower, as cauli- 
 flower ; or fruit, as squash, cucumber, tomato. 
 
 From the standpoint of cookery the most important 
 classification is that of strong fMvorcd and szvcct 
 flavored vegetables, since this modifies our method of 
 cooking ; right methods leading us to retain all the 
 juices of the latter as far as possible, while we legiti- 
 mately discard part of the extract of the former. For 
 example, green peas and string beans, young carrots, 
 and squash, should be cooked in a small amount of 
 water, or have the water in which they are cooked 
 concentrated at the end so that it mav all be served 
 
 119 
 
 Botannical 
 Classification 
 
 Flavor 
 Classification 
 
120 
 
 FOOD AND DIETETICS 
 
 Nutritive 
 Classification 
 
 Cellulose of 
 Vegetables 
 
 with the vegetable ; while in the case of onions we 
 may well use a large portion of water, and throw it 
 away. It is true that in this latter case we may lose 
 valuable salts and some nutriment, but these we sac- 
 rifice for the sake of improved flavor. 
 
 From the standpoint of diet a better classification 
 would be into nutritive vegetables and flavor vegeta- 
 bles. With the latter we should include those that 
 contain mineral salts, but have little food value. Of 
 this class, lettuce, spinach, cabbage, tomato and cucum- 
 ber are types ; while rice, potatoes, peas, beans and 
 lentils furnish examples of the former. Many vege- 
 tables will be on the border line between the two. 
 
 The composition of vegetables varies in general from 
 that of animal foods in that here we have the carbo- 
 hydrates largely represented. The chief carbohy- 
 drates of vegetables are starch, sugar, and cellulose of 
 various types. 
 
 The fact that cellulose forms the framework of the 
 plant and that it is within cellulose walls that the 
 starch as well as the proteid of the plant are con- 
 tained, is important in two ways. While cellulose is 
 only slightly digested by human beings (only so 
 little of it in young and tender plants really serving 
 as a food that the amount may be neglected), it does 
 have a more or less important function in furnishing 
 the required bulk of food. If one undertakes to live 
 wholly upon a vegetable diet, this bulk generally be- 
 comes too great; on the other hand, one of the objec- 
 
VEGETABLES 
 
 121 
 
 tions to an exclusively animal diet is in the absence 
 of bulk. Since the digestive juices do not act upon 
 cellulose to any extent, and the nutritive portions of 
 the vegetables are enclosed within walls of this sub- 
 
 STARCH OF A POTATO ENCLOSED IN CELUX.OSE CELLS. 
 
 stance, the province of cooking is to so change the 
 cell wall that the nutritive materials may be set free, 
 or the digestive juices penetrate to them. 
 
 We usually speak of softening the cellulose by means zflFect of 
 of cooking. Apparently what we really do is to dis- ceiiu\ose°'* 
 solve the intercellular substances that bind the walls 
 together, and thus make it possible for the cell walls 
 
122 FOOD AND DIETETICS 
 
 to be mechanically ruptured, either in the process of 
 cookery or by the pressure exerted in the mouth. Part 
 at least of this intercellular substance belongs to the 
 pectin g-roup that causes the jelling- of fruit juices. 
 
 SWELLING OF THE STARCH. 
 
 Hydration 
 of the Starch 
 
 The first process in rendering the starch of the vege- 
 table digestible is one of hydration. It is important, 
 therefore, that an abundance of water be present when 
 starch is cooked. Some vegetables like the potato 
 contain so much water that the necessary amount for 
 the starch is supplied within the vegetable itself. The 
 
VEGETABLES 
 
 123 
 
 grains and other dry vegetables need to have a large 
 amount supplied. The swelling of the starch grains 
 upon hydration is probably an important agent in the 
 rupturing of the cellulose cell wall already referred to. 
 
 THE CELL WALLS RUPTURED. 
 
 Sugar IS the soluble carbohydrate of the vegetable, 
 as starch is the insoluble form in which this nutri- 
 ment is stored. Some vegetables, such as carrots, 
 show large amounts of sugar, while starch is absent 
 from this part of the plant. Other typical vegetables 
 containing a large amount of sugar are beets, pars- 
 
 Sugar in 
 Vegetables 
 
124 
 
 FOOD AND DIETETICS 
 
 Starchy 
 Vegetables 
 
 nips, artichokes, sweet potato. Onions, cabbage, and 
 some varieties of peas, string beans, squash and sweet 
 corn all contain a fair amount. 
 
 Vegetables containing a large amount of starch are 
 
 \~WATBI^8£554 
 
 s= — 
 
 1 
 
 \^- = 
 
 
 IPrcteidQSM 
 
 \ r.bY-el6y. / 
 
 \Ca»rbo- 
 \ V\ydr&t.« 
 
 \ lOir. 
 
 
 XFaXOS'^ 
 
 
 1 Mm M.t 
 
 
 COMPOSITION OF THE CARROT AND TURNIP. 
 
 ( After Hutchison ) 
 
 Proteid of 
 Vegetables 
 
 represented by potato, sweet potato, rice, peas, beans 
 and lentils. Some vegetables , containing a large 
 amount of cellulose are squash, potato, beet, celery, 
 cabbage. 
 
 As a rule, we do not look to the vegetable world 
 for our main supply of proteid, yet some of our vege- 
 tables, notably the legumes, do contain an abundant 
 
VEGETABLES 12$ 
 
 supply of this food principle. Whether this is as avail- 
 able for use in the body as the proteid in meat is 
 often questioned. With ordinary cooking processes 
 it evidently is not, but with long continued heat the 
 matter is different. That there is no inherent dififer- 
 ence between vegetable and animal proteid, so far as 
 
 e»-rbo>\ydrcx.te 
 Ce\lulo&e 
 Mii> Mat 
 
 Ext-ract. 
 
 COMPOSITION OF THE CABBAGE. 
 Blackened portions represent amount dissolved in cooking. 
 
 its digestibility is concerned, would seem to be indi- Digestibility 
 
 o J ' . . of Vegetable 
 
 cated by the fact that when the vegetable is finely di- Proteid 
 vided, as in the case of some of the vegetable meals, 
 it is absorbed to a greater extent than in its ordinary 
 form. It is said, for instance, that when lentils are 
 soaked and boiled until soft, 60 per cent of their pro- 
 teid is absorbed, while in the lentil meal 90 per cent 
 is utilized by the body. No careful experiments have 
 been made to see what proportion of the boiled lentils 
 would have been absorbed if the cooking had been 
 continued for several hours. There is every reason, 
 
126 
 
 FOOD AND DIETETICS 
 
 however, to think that the percentage would be in- 
 creased. Anyone who has compared dry peas or beans 
 cooked two hours, or until they have just become 
 soft, with those cooked from eight to twelve hours 
 will realize the difference in the result. 
 
 TAT 
 CRUDE FIBER -^a% 
 PROTE\0->-bI% 
 ASH-Vv% 
 
 COMPOSITION OF THE POTATO. 
 
 The 
 Potato 
 
 Salts of 
 Vegetables 
 
 Among the vegetables, the potato, in this country 
 at least, is the most generally used. It has of late 
 l)cen decried as having no food value. This is far 
 from true. It has, of course, a small amount of pro- 
 teid, some of which is lost in the process of cooking. 
 Its mineral salts are less in amount than in many vege- 
 tables, and are partially lost in the cooking. Its chief 
 value as food lies in the starch it contains, and in the 
 fact that its very absence of strong flavor makes it 
 acceptable day after day. 
 
 ^'egetables should be in our diet not only for their 
 food value but for their mineral salts as well. The 
 bad effect of the failure to use a certain proportion 
 of vegetables and fruits, has long been known. Scurvy 
 has usually been attributed to this error in diet, while 
 it is quite possible that some minor disorders of the 
 
VEGETABLES 
 
 127 
 
 digestion are attributable to the same cause. Cabbage, 
 lettuce, celery, onion, spinach and the different leaves 
 used as greens find their value almost wholly in the 
 presence of mineral salts. 
 
 IMushrooms have often been considered of great 
 value, from the proteid they contain, but it seems cer- 
 tain now that this value has been much exaggerated, 
 
 Mushrooms 
 
 SECTION OF A P0T.\TO. 
 
 -Outer Skill. /> — Inner Skin or Fibro-vascular Layer, 
 d — luuer i'lcbh. 
 
 -Flesh. 
 
 and that the reason for using them as articles of food 
 lies in their pleasant flavor and the variety they give, 
 rather than in the amount of nutriment they furnish 
 the system. 
 
 The digestibility of different \egetablcs must ahva}-s 
 be difficult to ascertain, so far as any one individual 
 is concerned. Not only the presence of cellulose, but 
 
 Digestibility 
 of Vegetables 
 
128 FOOD AND DIETETICS 
 
 of acids, as in the tomato, of nitrogeneous substances, 
 such as asparagin found in asparagus, and of vola- 
 tile flavors, as in the onion, all affect this question. 
 There has been within a few years a great gain in 
 the abundance and variety of vegetables available. 
 Formerly in winter choice was confined to cabbage. 
 
 COMPOSITION OF THE CUCUMBER. 
 
 turnip, squash, onions and a few others. Now a visit 
 to the market of a large city, even at the least promis- 
 ing time of year, shows an overwhelming variety of 
 fresh vegetables. If we add to these the numerous 
 canned vegetables of excellent quality available (and 
 these are increasing in variety constantly) and the 
 dried vegetables, like the peas, beans and mushrooms 
 even, that are obtainable, we have no excuse for limit- 
 ing our diet so far as vegetables are concerned. 
 
 True economy will consist not in cutting down the 
 supply but in choosing fresh vegetables at the time 
 when each is most abundant and therefore cheapest, 
 and presumably at its best, and in supplementing these 
 by the judicious use of the canned or dried product, 
 not forgetting the ordinary winter vegetables. 
 
VEGETABLES 
 
 Average Composition of Vegetables 
 
 129 
 
 Name 
 
 Percentage Composition of 
 Edible Portion 
 
 Beans, dried 
 
 Beans, string.. .. 
 
 Peas, dried 
 
 Peas, green 
 
 Potatoes 
 
 Sweet Potatoes. 
 
 Sweet Corn 
 
 Parsnips 
 
 Carrots 
 
 Beets 
 
 Turnips 
 
 Onions 
 
 Cabbage 
 
 Spinach 
 
 Siiuash 
 
 Tomatoes 
 
 Lettuce 
 
 Celery 
 
 Cucumbers 
 
 7.0 
 
 45.0 
 20.0 
 20.0 
 61.0 
 20.0 
 20.0 
 20.0 
 30.0 
 10.0 
 15.0 
 
 50.0 
 
 15.0 
 20.0 
 15.0 
 
 12.6 
 89.2 
 9.5 
 74.6 
 78.3 
 69.0 
 75.4 
 83.0 
 88.2 
 87.5 
 89.6 
 87.6 
 91.5 
 92.3 
 88.3 
 94.3 
 94.7 
 94.5 
 95.4 
 
 55.2 
 5.5 
 57.5 
 15.2 
 18.0 
 26.1 
 19.2 
 11.0 
 8.2 
 8.8 
 6.8 
 9.1 
 4.5 
 2.3 
 8.2 
 3.3 
 2.2 
 2.3 
 2.4 
 
 4.4 
 
 1.9 
 
 4.5 
 
 1.7 
 
 .4 
 
 1.3 
 
 .5 
 
 2.5 
 
 1.1 
 
 .9 
 
 1.3 
 
 .8 
 
 1.1 
 
 .9 
 
 .8 
 
 .8 
 
 .9 
 
 1.0 
 
 .5 
 
 22.5 
 2.3 
 
 24.6 
 7.0 
 2.2 
 1.8 
 3.1 
 1.6 
 1.1 
 1.6 
 1.3 
 1.6 
 1.6 
 2.1 
 1.4 
 .9 
 1.2 
 1.1 
 .8 
 
 1.8 
 .3 
 
 1.0 
 .5 
 .1 
 .7 
 
 1.1 
 .5 
 .4 
 .1 
 2 
 '.Z 
 .3 
 .3 
 .5 
 .4 
 .3 
 .1 
 
 3.5 
 
 .8 
 
 2.9 
 
 1.0 
 
 1.0 
 
 1.1 
 
 .7 
 
 1.4 
 
 1.0 
 
 1.1 
 
 .8 
 
 .6 
 
 1.0 
 
 2.1 
 
 .8 
 
 .5 
 
 .7 
 
 1.0 
 
 1,605 
 
 195 
 
 1,655 
 
 465 
 
 385 
 
 570 
 
 470 
 
 300 
 
 210 
 
 215 
 
 185 
 
 225 
 
 145 
 
 110 
 
 215 
 
 105 
 
 90 
 
 85 
 
 80 
 
 *Not including fiber. 
 
 tincluding liber and thus higher than fuel value available in the body. 
 
 The substances grouped under carbohydrates in the above 
 table are chiefly starch, sugar and pectose bodies. Church 
 states that turnips contain no starch or sugar, only pectose, 
 but one of the analyses of the Department of Agriculture 
 showed one sample to contain over 4% of sugar. The carrot 
 contains sugar and pectose, but no starch ; parsnips, sugar, 
 starch and pectose. The nitrogenous matter is only in part 
 proteid ; in potatoes about 57% ; in carrots, onions, cabbage, 
 cucumbers, lettuce, about one-half. 
 
FRUITS 
 
 Classification 
 of Fruits 
 
 Dietetic 
 Value 
 
 Nutritive 
 Value 
 
 Fruits may, like vegetables, be classified as flavor 
 fruits and food fruits, and again these two classes will 
 run together so that we shall have difficulty in decid- 
 ing where certain ones belong. The apple, the orange, 
 the strawberry, although all having a certain food 
 value, are used so largely for their flavor and to give 
 variety, that these may well be put under the head 
 of the flavor fruits. Bananas form, perhaps, the best 
 common example of the food fruits. Bread fruit, so 
 largely used in the tropics, is another representative 
 of this class. 
 
 From a dietetic standpoint the most important func- 
 tion of fruits is that of furnishing mineral salts and or- 
 ganic acids to the body. The potash salts are consid- 
 ered especially important. Some fruits, like the pine- 
 apple, contain ferments that are said to be aids , to 
 digestion. , Fruits are generally laxative in efifect, — 
 apples, figs, prunes, peaches and berries are particu- 
 larly efifective in this respect, especially if taken be- 
 tween meals or at the beginning of a meal. 
 
 Their chief nutritive value is given to fruits hy the 
 carbohvdrate group. This is largely in the form of 
 sugar, while the remainder consists chiefly of vege- 
 table gums, among which may be included the "pectin 
 bodies" that give to fruits their power to form jelly. 
 Starch may be present in unripe fruits, but disappears 
 as the fruit ripens. Bananas, as we use them, contain 
 a small amount of starch. Of fresh fruits very few 
 contain more than one per cent of nitrogenous mat- 
 ter, not all of which is proteid. 
 
 130 
 
FRUITS 
 
 131 
 
 Dried fruits may be without question put under the 
 food fruits, dates containing sixty-six per cent of 
 carbohydrate, prunes approximately the same amount, 
 figs about sixty-three per cent, while raisins furnish 
 seventy-five per cent. Raisins in this respect stand 
 almost at the head of the list of concentrated foods 
 since they furnish so much nutriment in so small a 
 
 Dried 
 Fruits 
 
 RB0HVDRAT8 
 
 MAT. 
 
 COMPOSITION OF AN AFFL,E. 
 
 ^ After ilutchiaon. ^ 
 
 bulk. When fresh fruits are not obtainable dried 
 fruits may well take their place. These are usually 
 less expensive than fresh fruits, and properly cooked 
 go far to make up for the absence of the fresh varie- 
 ties. 
 
 Canned fruits are increasingly used, and many who 
 formerly thought it necessary to put up large amounts 
 of fruit at home, are now purchasing those canned on 
 a commercial scale. Whether this is a wise thine: or 
 
 Canned 
 Fruits 
 
Varieties 
 
 132 FOOD AND DIETETICS 
 
 not depends on the amount of fruit available for the 
 housekeeper at a low cost, the price of sugar, and the 
 time and strength at her disposal. Often the fruit 
 commercially canned is really superior to that pre- 
 pared at home for the reason that the canning is done 
 where the fruit is easily obtainable in its freshest and 
 most perfect condition. When canned fruit is as rea- 
 sonable in cost as it is at present, the housekeeper 
 should certainly be very sure that her time cannot be 
 used to better advantage before she undertakes to 
 prepare quantities of fruit at home. 
 
 Perhaps no article of diet has increased in use dur- 
 ing the last few years so rapidly as fruits. Not only 
 the most hardy, but the more perishable varieties, in- 
 cluding berries, are by improved methods of transpor- 
 tation, by the use of refrigerator cars and by increased 
 areas of cultivation made available through a longer 
 season, and at greater distances from the source of 
 supply than ever before. The fruit industries, includ- 
 ing the cultivation of the fruit, the great canning and 
 drying establishments, and the transportation of the 
 product, have become of immense importance in the 
 commercial world, 
 jje^ New varieties of fruit produced by careful selection 
 
 and cross fertilization are constantly appearing. Some 
 of the most important changes that have been induced 
 by cultivation have been the lessening of the proportion 
 of cellulose, the production of seedless varietjes, the 
 increase in size and the development of fine flavors. 
 
FRUITS 133 
 
 As in the case of vegetables, the (lic::estibility of 
 '^ruits is lartiely an inilividual matter. l'>ananas may 
 )e eaten freely by many, even by children, while oth- 
 ers fail to digest even a small portion. Strawlierries, 
 g-cnerally considered easily dig'ested, are actual poison 
 to some people. The chief benefit of a table of digesti- 
 bility is as a guide for experimentation. In feeding- a 
 child, for instance, one would try first the fruits con- 
 sidered most digestible. 
 
 Aside from the personal equation, ease in mastica- Digestibility 
 
 r ,1 ■ , . 1 , • ,1 1- , • of Fruits 
 
 tion IS one of the nuportant elements m the digestion 
 of fruits, as in the ease of other foods. The banana, 
 for instance, easily slips down the throat in large 
 pieces ; the blueberry can be swallowed whole, while 
 such a fruit as the apple is naturally more thoroughly 
 masticated, for ease in swallowing, and the orange 
 almost falls apart of itself. 
 
 The difference in the digestibility of ripe and unripe 
 fruits is generally attributed to the larger proportion 
 of cellulose in the latter ; this and the excess of acids 
 in unripe varieties is held responsible for their ill 
 efTects. 
 
 Gilman Thomson gives among the commoner fruits 
 easy of digestion : grapes, oranges, lemons, cooked 
 apples, figs, peaches, strawberries and raspberries ; 
 while he classifies as somewhat less digestible : melons, 
 prunes, raw apples, pears, apricots, bananas and fresh 
 currants. Dried currants and citron he considers 
 ■'wholly indigestible," while he gives as the most use- 
 
134 
 
 FOOD AND DIETETICS 
 
 fill fruits for invalids : lemons, oranges, baked apples, 
 stewed prunes, grapes, banana meal. 
 
 Young cbildren and tbose of delicate digestion 
 should avoid all skin and seeds of fruit. 
 
 Averag-e Composition of Fruits 
 
 
 
 
 Perc'ENtag 
 
 i Composition of 
 
 
 
 <s 
 
 
 
 Edible Portion 
 
 
 
 
 
 « 
 
 
 3 
 
 
 
 ^ 
 
 
 2, 
 
 u 
 
 u 
 
 1 
 
 
 
 o 
 
 
 Nitrogeno 
 Fats 
 
 
 < 
 
 P. 
 .2 
 
 o 
 
 Bananas 
 
 £5. 
 
 75.3 
 
 21.0 
 
 1.0 
 
 1.3 
 
 6 
 
 .8 
 
 460 
 
 Grapes 
 
 1ft. 
 
 77.4 
 
 14.9 
 
 4,3 
 
 1.3 1 
 
 6 
 
 .5 
 
 45'^ 
 
 Plums 
 
 5. 
 
 78.4 
 
 20.1 
 
 'i 
 
 1.0 ... 
 
 
 .5 
 
 395 
 
 Cherries 
 
 5. 
 
 80.9 
 
 16.5 
 
 9 
 
 1.0 
 
 8 
 
 .6 
 
 365 
 
 Huckle berries 
 
 
 81.9 
 
 16.6 
 
 V 
 
 .6 
 
 6 
 
 .3 
 
 345 
 
 Apples 
 
 £5. 
 
 84.6 
 
 13.0 
 
 1.2 
 
 .4 
 
 5 
 
 .3 
 
 290 
 
 Pears 
 
 10. 
 
 84.4 
 
 11.4 
 
 2.7 
 
 .6 
 
 5 
 
 .4 
 
 295 
 
 Black berries 
 
 
 86.3 
 
 8.4 
 
 2.5 
 
 1.3 1 
 
 
 
 .5 
 
 270 
 
 Apricots 
 
 6. 
 
 85.0 
 
 13.4 
 
 9 
 
 1.1 ... 
 
 
 .5 
 
 270 
 
 Peaches 
 
 6. 
 
 85.0 
 
 10.5 
 
 -i 
 
 .5 ... 
 
 
 .6 
 
 
 Oranges 
 
 27. 
 
 86.9 
 
 11.6 
 
 1 
 
 .8 
 
 2 
 
 .5 
 
 240 
 
 Raspberries (red) 
 
 V 
 
 85.8 
 
 9.7 
 
 2.9 
 
 1.0 ... 
 
 
 .6 
 
 255 
 
 Cranberries 
 
 
 88.9 
 
 8.4 
 
 1.5 
 
 .4 
 
 6 
 
 9 
 
 215 
 
 Lemons 
 
 30. 
 
 89.3 
 
 7.4 
 
 1.1 
 
 1.0 
 
 7 
 
 .5 
 
 205 
 
 
 
 89.3 
 
 89.5 
 
 9.3 
 7.2 
 
 .4 
 2.1 
 
 .4 
 
 .6 ... 
 
 3 
 
 3 
 .6 
 
 200 
 
 Muskmellon 
 
 50. 
 
 185 
 
 
 .5. 
 60. 
 
 90.4 
 92.4 
 
 6.0 
 6.7 
 
 1.4 
 
 1 
 
 1.0 
 .4 
 
 6 
 
 .6 
 .3 
 
 180 
 
 
 140 
 
 
 
 * Not includjnf; fiber, 
 t Including liber. 
 
 The carbohydrates of fruits are chiefly in the form of sugar. 
 Nearly all contain pectin bodies and these are most abundant 
 in unripe fruit. The acids of the fruits are here included un- 
 der the carbohydrates. Apples, pears and peaches contain 
 malic acid; lemons and oranges, citric acid; grapes, tartaric 
 acid ; rhubarb, oxalic acid, etc. 
 
FRUITS 
 
 135 
 
 Average Composition of Dried Fruits 
 
 
 
 Pehcent.age Composition 
 
 of 
 
 • 
 
 
 
 Edible Portion 
 
 
 
 
 o 
 
 
 
 
 J2 
 
 
 o 
 
 
 CS 
 
 3 
 
 
 
 t- 
 
 
 a 
 
 u 
 
 73 
 
 ^ 
 
 
 
 K 
 
 
 5 
 
 
 O 
 
 ca 
 O 
 
 
 
 
 m 
 
 .2 
 
 
 
 Dates 
 
 10.0 
 
 15.4 
 
 78.4 
 
 2.1 
 
 2.8 
 
 1.3 
 
 1,615 
 
 Raisins 
 
 10.0 
 
 14.6 
 
 76.1 
 
 2.6 
 
 3.3 
 
 3.4 
 
 1,605 
 
 Currants 
 
 
 17.2 
 
 74.2 
 
 2.4 
 
 1.7 
 
 4.5 
 
 1,495 
 
 Fies 
 
 
 18.8 
 22.3 
 28.1 
 29.4 
 
 74.2 
 73.3 
 66.1 
 62.5 
 
 4.3 
 2.1 
 
 1.6 
 4.7 
 
 .3 
 "22 
 
 ilo 
 
 2.4 
 2.3 
 2.1 
 2.4 
 
 1,475 
 
 
 15.0 
 
 1,400 
 
 
 1,350 
 
 
 
 1,290 
 
 
 
 
 * Including flbor. 
 
NUTS 
 
 Nutritive 
 Value 
 
 The form of fruits that we know as nuts has a very 
 different place in diet from that of the ordinary fruit. 
 We find here foods having a nutritive value that com- 
 pares favorably with that of the most nutritious sub- 
 stances. Almond kernels for instance contain twenty- 
 one per cent of proteid, fifty-four of fat, and seventeen 
 
 PFtOTElD 
 
 f='AT 
 
 ARROHyDF^ATe, 
 MIN.MAT. 
 
 y.&^c &i.L>uuodE. 
 
 COMPOSITION OF AN ENGLISH WALNUT. 
 
 of carbohydrates, while peanuts are richer still in pro- 
 teid and also contain a large amount of fat. Indeed, 
 nuts often may well be substituted for meat, and have 
 the advantage that they supply at the same time a 
 certain amount of carbohydrates. Some nuts, as chest- 
 nuts, are very rich in the latter. The table given is 
 taken from the experiment' station bulletin, Nuts as 
 Food, and shows the comnosition of sonie of the iT}0§t 
 common nuts, jstj 
 
NUTS 
 
 137 
 
 Average Composition of Nuts 
 
 Almonds 
 
 Brazil Nuts 
 
 Filberts 
 
 Hickory Nuts 
 
 Pecans 
 
 Walnuts 
 
 Chestnuts (fresh) — 
 
 Butternuts 
 
 Cocoanuts 
 
 Cocoanut, shredded. 
 
 Pistachio 
 
 Peanuts 
 
 Roasted Peanuts 
 
 Peanut Butter 
 
 47.0 
 49.4 
 52.1 
 62.2 
 50.1 
 58.8 
 15.7 
 86.4 
 34.7 
 
 27.0 
 32.6 
 
 Percentage Composition of 
 Edible I'ohtion 
 
 4.9 
 4.7 
 5.4 
 3.7 
 3.4 
 3.4 
 
 43.4 
 4.5 
 
 13.0 
 3.5 
 4.2 
 7.4 
 l.« 
 2.1 
 
 21.4 
 
 17.4 
 16.5 
 15.4 
 12.1 
 IS. 2 
 6.4 
 27.9 
 6.6 
 6.3 
 22.6 
 29.8 
 30.5 
 29.3 
 
 54.4 
 65.0 
 64.0 
 67.4 
 70.3 
 60.7 
 6.0 
 61.2 
 56.2 
 57.4 
 54.5 
 43.5 
 49.2 
 46.5 
 
 V ho 
 -■ 5 
 
 o -3 
 ^ 3 
 
 O C 
 
 16.8 
 9.6 
 11.7 
 11.4 
 12.2 
 16.0 
 42.8 
 3.4 
 22.6 
 31.5 
 15.6 
 17.1 
 16.2 
 17.1 
 
 2.5 
 3.3 
 2.4 
 2.1 
 1.6 
 1.7 
 1.4 
 3.0 
 1.6 
 1.3 
 3.1 
 2.2 
 2.5 
 5.0 
 
 o 
 
 2,895 
 3,120 
 3,100 
 3,345 
 3,300 
 3,075 
 1,140 
 3,370 
 2,805 
 3,125 
 3,250 
 2,610 
 2,955 
 2,825 
 
 Much has been said about the indigestibility of 
 nuts, but this probably comes largely from the fact 
 that nuts are most usually eaten at the end of a 
 hearty meal after the appetite has been completely 
 satisfied. If nuts were more often taken as a sub- 
 stitute for a part of the meat of the meal, there 
 would probably be less difficulty with regard to 
 their digestion. Another important factor in their 
 digestibility as in the case of other foods, is that 
 of their finely divided condition ; often they are in- 
 sufficiently masticated. Some of the nut meals and 
 pastes on the market are valuable because of their 
 fine division, and their use as a meat substitute 
 certainly has a rational basis. Peanut butter is 
 the most common of these preparations. 
 
 Digestibility 
 of Nuts 
 
of Tea 
 
 TEA, COFFEE AND COCOA 
 
 The common beverages, tea, coffee and cocoa, are in 
 such general use today that it is difficult to realize 
 that two of them were not introduced into Europe 
 until the seventeenth century, and the other only a 
 hundred years earlier, though other nations had known 
 them long before. Tea drinking began in Japan in 
 692 A. D., while coffee, though not known to the 
 Greeks and Romans, had been used in Abyssinia and 
 Ethiopia from time immemorial. 
 Varieties The tea plant seems to be a native of Assam, a prov- 
 ince of Burmah, but it has been grown in China and 
 Japan for fifteen hundred years. Two different types 
 of the plant are illustrated by the Assamese and Chi- 
 nese varieties. The tea of Assam grows luxuriantly, 
 but is sensitive to drought, cold or winds. Its leaves 
 are of bright green, sometimes reaching a size of nine 
 inches in length and three in width, while the young 
 leaf is of soft texture and golden color. It may pro- 
 duce as many as twenty "flushes," or successive crops 
 of young leaf during each picking season. The Chi- 
 nese plant is tough and hardy, able to endure severi- 
 ties of climate, and to grow in poor soil with deficient 
 moisture. The leaf is smaller, tougher and darker 
 than that of the Assam tea plant. Between these two 
 extremes exist all varieties of tea. Most varieties 
 produce three or four crops a year. 
 
 The tea plant produces small white flowers which 
 eventually yield the seed from which cultivated tea is 
 
 138 
 
TEA 
 
 139 
 
 raised. In cultivating the plant an effort is made to 
 produce abundant young leaf, since good tea is made 
 from this alone. Pekoe tea is the choicest variety. 
 The undeveloped bud at the end of a young shoot is 
 
 Pekoe 
 
 Tea 
 
 TEA LEAVES. 
 
 a— Flowery Pekoe, fi — Orange Pekoe, f— Pekoe, d — Sour hoijp: (first). 
 e — Souchong (second), y"— Congon. //— Bohea. 
 
 called the pekoe tip, or flowery pekoe. It is said that 
 this tea rarely comes to this country. From it is made 
 Mandarin tea, that commands a very high price in its 
 native country. The next leaves produce orange pekoe 
 and pekoe. Souchong is the next larger leaf and Con- 
 gou the next. A still larger leaf formerly on the mar- 
 ket more generally than now yields Bobea, 
 
 Souchong 
 Tea 
 
140 
 
 FOOD AND DIETETICS 
 
 Black 
 and 
 
 Green 
 Tea 
 
 Fermentation 
 Process 
 
 Ifames 
 
 All of these different varieties may be made either 
 into black or green tea, though some plants yield 
 leaves better adapted for the manufacture of black 
 tea, and some that serve better for green. Japan tea, 
 for example, is usually made into green, while the 
 Indian are generally black. Chinese tea provides both 
 varieties. The difference between black and green 
 tea is, however, in the method of preparation. Green 
 tea is prepared by withering the leaves in iron vessels 
 over a quick fire, or by steaming them on mats. The 
 leaf is then rolled in order to break up the tissue con- 
 taining the essential oil. It is then re-heated and sub- 
 jected to long continued drying over a low fire. In 
 black tea the fresh leaf is spread out to wilt in the 
 sun, then rolled, spread out thinly, moistened and 
 allowed to ferment. The leaves are then dried and 
 fired in a furnace or over a charcoal fire. 
 
 The chief difference between the black and green tea 
 lies in this fermentation process. By this means, some 
 of the tannic acid in the leaves is changed so that it 
 becomes less soluble. The blaGk tea is thus less as- 
 tringent than the green. Common varieties of green 
 tea are hyson, corresponding to the pekoe or sou- 
 chong, and gunpowder, corresponding to congou. 
 
 Aside from the varieties given by the stage of 
 growth at which the leaf is plucked and by the method 
 of preparation, teas are named from the different 
 countries or the special district that produces them, 
 or ^vcn from the g-ftr(:lens where \htY ar*? grQwn, 
 
TEA 
 
 141 
 
 Japan, Chinese, Indian and Ceylon teas each have their 
 own marked characteristics, while the different dis- 
 tricts of China give various kinds, as the oolongs 
 from Formosa or the monings from north China. 
 
 The quality is dependent on the cultivation of the 
 plant, the age of the leaf, and the care in manufacture. 
 Some of the finest tea of China is so high priced that 
 it can be purchased there only by the very rich, while 
 the lowest grades are often made into bricks (brick 
 tea) and sent into the interior. The choicest Japan tea 
 is raised under protection from direct sunlight and is 
 prepared without rolling. It is said to be untouched 
 with the hand after it is put upon the steaming appara- 
 tus. Most of the teas sent to the United States might 
 be classed as low middling, with some superior grades. 
 The choice varieties are rarely received. 
 
 The most important constituents of tea are theine, 
 or cafifeine, tannic acid and the volatile oil that gives 
 the flavor. Black and green tea contain practically 
 the same amount of oil and caffeine, but black tea has 
 onlv about half as much tannic acid as green. 
 
 The method of making tea has an important influ- 
 ence on the constituents of the beverage. Methods 
 vary all the way from one Japanese fashion of stir- 
 ring the finely ground tea into warm water and drink- 
 ing'' the whole infusion, to the Russian method of 
 brtnging the water just to a boil and making a deli- 
 cate infusion. 
 
 Jhe l?oiling of tea and the practice of keeping the 
 
 Quality 
 
142 FOOD AND DIETETICS 
 
 teapot on the stove all day that the brew may be ready 
 at any moment, each results in extracting the largest 
 possible amount of tannic acid from the tea. If tea 
 must stand after making, it should be poured off the 
 leaves immediately. The difference in extract can be 
 easily seen if equal amounts of tea be in one case 
 boiled four or five minutes, in another allowed to 
 stand in cold water, and in a third infused in hot water 
 for the same length of time. If these three results be 
 put into glasses, the depth of color will indicate the 
 difference in material extracted. If a solution -of ordi- 
 nary copperas be made, and a few drops of this added 
 to each, a black, inky substance, a tannate of iron, 
 will form, the amount varying with the tannic acid ex- 
 tracted. 
 Adulteration Adulterations of tea are much less common than 
 of Tea formerly. The chief fraud practiced is that of sub- 
 stituting an inferior grade for a better. One method 
 of doing this is by facing the tea. This is practiced 
 especially on green teas, giving them a brighter color. 
 
 Occasionally spent or exhausted leaves are mixed 
 with fresh ones, thus constituting an adulteration. 
 
 Tea tablets are sometimes prepared for the use of 
 travelers by pressing finely ground tea of varying 
 quality into tablets to be dissolved in hot water. 
 
COFFEE 
 
 The coffee tree (caffaea arabica) belongs to the 
 same botanical family as the tiny partridge berry 
 found in our northern woods, the familiar button 
 bush of the country roadside, and the gardenia. 
 
 COFFEE BEANS AND BLOSSOMS. 
 
 It is native to Abyssinia, western Africa, and per- 
 haps western Arabia, though it has now been nat- 
 uralized in a large number of tropical countries. It 
 blooms eight months in the year and with its small 
 fragrant, white blossoms in the axils of the glossy 
 
 143 
 
 Native 
 Home 
 
144 FOOD .IXD DIETETICS 
 
 evergreen leaves, it presents an attractive appearance. 
 The ripe coffee berry is dark in color and is a pnlp\- 
 fruit, somewhat resembling a cherry. The berries 
 have two cells, each containing a single seed, the 
 coffee bean. Three gatherings of coffee are generally 
 made annually. The ripe fruit is dried and then freed 
 from skin and pulp, usually by machinery. 
 
 In the east a decoction is frequently made of the 
 unroasted seeds, while in some places the leaf of the 
 tree is used for preparing a drink ; and it is said that 
 in the Sultan's coft'ce the dried pulp of the berry is 
 employed. 
 Roasting The roastiug of coffee so generally practiced, is 
 
 chiefly for the purpose of developing its flavor and 
 rendering the beans brittle so that they can be more 
 easily ground, though it has other effects also. Coffee 
 is imported from Mocha, Java, Ceylon, Maracaibo, 
 Porto Rico, and other countries. But 75 per cent of 
 ^ that used in this country comes from Brazil. Our 
 Mocha and Java mixtures are simply different kinds 
 of berries from the same plant. 
 
 Coffee, unlike tea. may properly be prepared cither 
 as an infusion or a decoction ; that is, it may be ex- 
 tracted without boiling, or it may be boiled. 
 
 The important constituents of coffee are caffeine 
 and caft'etannic acid, and caft'eol, the oil that gives the 
 fragrant aroma and Ravor. Caffeol is developed by 
 the process of roasting while the amount of caffein': 
 i^ lessened. Sugar is present in considerable amounts, 
 
PICKING COFFEE BEKKIES. 
 
146 FOOD AND DIETETICS 
 
 and most of this is caramelized in the roasting. Fat 
 also is found, sometimes to as much as 15 per cent, 
 and proteid to about 10 per cent. A comparison ol 
 the composition of tea and coffee is given below : 
 
 Percentage Composition of Coffee 
 
 Raw. Roasted. 
 
 Moisture 8.y8 0.63 
 
 Caffeine 1.08 0.82 
 
 Saccharine matter 9.55 0.43 
 
 Caffeic acid 8.46 4.74 
 
 Alcoholic extract 6.90 14- H 
 
 Fat and oil 12.60 13.59 
 
 Lugumin and albumen 9.87 II.23 
 
 Dextrin 0.87 1.24 
 
 Cellulose and insoluble coloring 
 
 matter 37-95 4862 
 
 Ash 374 4-56 
 
 Percent^ce Compositicn of Tea 
 
 Unprepared Green Black 
 
 Leaves. Tea. Tea. 
 
 Caffeine or theine '3.3^ 3-20 3.30 
 
 Ether extract 6.49 5.52 5.82 
 
 Hot-water extract 50-97 53-74 47.23 
 
 Tannin (as gallotannic acid).. 12.91 10.64 4-^9 
 
 Other nitrogen-free extract. .. .27.86 31.43 35.39 
 
 Crude protein 37 -2,^ 37-43 38-90 
 
 Crude fibre 10.44 10 06 10.07 
 
 Ash 4-97 4-92 4-93 
 
 Nitrogen 5-97 5-99 6.22 
 
 Composition This does not give a fair estimate of the compost- 
 of Decoctions ^j^^^ ^^ ^j^^ druiks siucc wc usc more coffee to the cup 
 
COFFEE BERRY AND LEAF, NATURAL SIZE 
 Fiom Bulletin No. 25, Division of Botany, U. S. Department of Agriculture 
 
COFFEE 147 
 
 than tea. Hutchison finds that a cup of black coffee 
 contains nearly the same amount of caffeine and tan- 
 nin as a cup of tea. This depends, of course, very 
 largfely upon the methods of preparation. It is gen- 
 erally considered that with our ordinary methods that 
 less tannin is present in coffee than in tea. 
 
 The adulterants of coffee are many. One of the Adulterants 
 commonest is chicory. In France this is often used in 
 order to add a desired flavor. Other adulterants that 
 have been found are roasted peas, beans, wheat, brown 
 bread, charcoal, red slate, and dried pellets consisting 
 of ground peas, pea hulls and cereals held togethei 
 with molasses. These are met with only in ground 
 coffee. Although at one time artificial coffee beans 
 were manufactured to some extent, they are said to 
 be seldom found today. The adulteration of un- 
 ground coffee consists rather of the substitution or 
 admixture of cheap or inferior varieties. A simple 
 rough test for the detection of adulteration in cofi'ce 
 consists in shaking some of the sample in cold water. 
 The pure coffee usually floats on the surface while 
 most of the adulterants sink, the grains of chicory 
 coloring the water a brownish red as they fall. Some- 
 times adulteration can be detected if ground coffee is 
 spread out upon a paper and examined with a mag- 
 nifying glass. A better protection is aft'orded, how- 
 ever, by purchasing the coft'ee unground. 
 
COCOA 
 
 It is said that "the earhest intimation of the intro- 
 duction of cocoa into England is found in the an- 
 nouncement ni the Pubhc Advertiser of Tuesday, 
 i6div June, 1657 (more than a hundred and thirty 
 years after its introduction into Spain), stating that 
 "in Eishopgate street, in Queen's Head alley, at a 
 Frenchman's house, is an excellent West India drink, 
 called chocolate, to be sold, where you may have it 
 ready at any time ; and also unmade, at reasonable 
 rates." 
 u^"of ^'^ spite of this alluring advertisement, it was the 
 
 Cocoa beginning of the eighteenth century before chocolate 
 became a fashionable beverage. And even as late as 
 1832 the consumption of cocoa was very limited, ow- 
 ing to a large duty that existed up to that time. Long- 
 before this it had become a great favorite in Spain as 
 it was in Spanish Ameria. In New England a mill 
 for the preparation of chocolate was established in 
 1765. The chocolate of the early Spanish days must 
 have been somewhat different from the modern arti- 
 cle. This is one receipt that is given : "Take a hun- 
 dred cocoa kernels, two heads of Chili or long peppers, 
 a handful of anise or orjevala, and two of mesachusii 
 or vanille — or, instead, six Alexandria roses, pow- 
 dered — two drachms of cinnamon, a dozen almonds 
 and as many hazelnuts, a half pound of white sugar, 
 and annotto enough to color it, and you have the king 
 
 of chocolates." 
 
 148 
 
COCOA 149 
 
 The cacao tree (theobroma cacao) from which cocoa 
 chocolate and cocoa are obtained, is a native of tropi- 
 cal America. It grows to an average height of from 
 thirteen to twenty, or even thirty feet, with a diam- 
 eter of from five to ten inches. A quaint description 
 of the appearance of the tree is given in the following 
 
 FLOWER AND FRUIT OF COCOA TREE. 
 
 words : "The cacao-tree almost all the year bears 
 fruit of all ages, which ripens successively, but never 
 grows on the end of little branches, as our fruits in 
 Europe do, but along the trunk and chief boughs, 
 which is not rare in these countries, where several 
 trees do the like. Such an unusual appearance would 
 seem strange in the eyes of Europeans, who have 
 never seen anything of that kind ; but, if one examines 
 the matter a little, the philosophical reason of the dis- 
 
Bean 
 
 150 FOOD AND DIETETICS 
 
 position is very obvious. One may easily apprehend 
 that if nature had placed such bulky fruit at the ends 
 of the branches their great Vv'eight must necessarily" 
 break them, and the fruit would fall before it came to 
 maturity." 
 
 Cocoa is raised from seed, and the tree does not bear 
 fruit till it has reached the fifth or sixth year. It re- 
 quires an abundance of air and light, but must be 
 shaded from too much direct sun. This is accom- 
 plishd by growing large shade trees at frec[uent in- 
 tervals in the cocoa plantation. 
 Cocoa The cocoa beans are the seed of the plant and lie in 
 
 even rows in a pod not very unlike a large cucumber 
 in shape and size. The first step in the preparation 
 of cocoa is the removal of the bean from this pod and 
 its subjection to a "sweating" or fermentation pro 
 cess. After this the beans are drietl in the sun and 
 in this form are shipped to our market. 
 
 Beans from different places, Caracas, Trinidad, 
 Maracaibo, Java, and others are imported by the 
 manufacturer who mixes them in different proportions 
 in order to get the result desired. The second step 
 in the process of manufacture is the careful roasting 
 of the beans to develop the flavor, and the crushing 
 or cracking of the nuts and the removal of the thin 
 husk or shell with which the seed is covered, by win- 
 nowing. The shells are used in many places for the 
 preparation of a drink. If they are boiled for a long- 
 time, a smooth, oily beverage with a pleasant nutty 
 
COCOA BE my. 
 
 Showiug Fruit, Flowcr.~ and Leaf. 
 
152 
 
 FOOD AND DIETETICS 
 
 flavor is obtained. The cracked cocoa, or cocoa 
 nibs, as it is called, is also used for preparing a bev- 
 
 METHOD OF GROWTH OF COCOA. 
 
 erage. A mixture of the shells and nibs gives a very 
 satisfactory result. 
 
 The next step in the preparation of chocolate is the 
 
COCOA 153 
 
 grinding of the nibs and running the semi-Hquid prod- 
 uct into molds. If sugar or any flavoring is to be 
 added, it is done at this time. 
 
 Cocoa in its purest form is chocolate with part of 
 the fat removed. In order that it may stay in a pow 
 dered condition, it is necessary either to remove this 
 oil or add some form of starchy material. Sometimes 
 flavoring materials such as cinnamon or vanilla are 
 also added. 
 
 Cocoa, like tea and coffee, contains an alkaloid 
 called theobromine. Tannin is also present in the raw 
 bean, but is changed during the roasting to cocoa- 
 red which gives the color to the cocoa. A substance 
 somewhat like the caffeol of coffee is also developed 
 during the roasting process. Cocoa beans also con- 
 tain a large amount of fat — about 50 per cent — with 
 proteids, starch, and other substances in small amounts. 
 Percentage Composition of Cocoa 
 
 Roasted Cocoa Nibs. 
 
 Water 2.72 
 
 Ash 3.32 
 
 Theobromine 1.44 
 
 Other nitrogenous substances 12.12 
 
 Crude fibre 2.64 
 
 Starch 8.07 
 
 Other nitrogen-free substances 19-57 
 
 Pat 50.12 
 
 100.00 
 The food value of clear chocolate has never been 
 questioned. Perhaps the writer of the eighteenth cen- 
 
 Chocolate 
 
 Theobromine 
 
154 FOOD AND DIETETICS 
 
 tury who is responsible for the following statements 
 may have exaggerated somewhat. He says : 
 
 "In reality, if one examines the nature of chocolate 
 a little, with respect to the constitution of aged per- 
 sons, it seems as though the one was made on pur- 
 pose to remedy the defects of the other, and that it 
 is truly the panacea of old age." 
 
 "There lately died at Martinico a counsellor, about 
 a hundred years old, who, for thirty years past, lived 
 on nothing but chocolate and biscuit. He sometimes, 
 indeed, had a little soup at dinner, but never any fish, 
 Hesh, or other victuals. He was, nevertheless, so vig- 
 orous and nimble that at fourscore and five he could 
 get on horseback without stirrups." 
 Food So good a scientist as Liebig says, however: "It is 
 a perfect food, as wholesome as delicious. It is 
 highly nourishing and easily digested, and is fitted lo 
 repair wasted strength, preserve health, and prolong 
 life." A simple statement of the case is that we have 
 in chocolate a highly concentrated food, particularly 
 rich in fat, but containing a fair amount of the otiicr 
 food principles. Since it is so concentrated it de- 
 mands water in abundance. So far as its digestibility 
 is concerned, there is more question. The very pres- 
 ence of so much fat means that it is too rich for 
 some people, while others can digest it with no dif- 
 ficulty. Hutchison tells us that so far as cocoa as a 
 drink is concerned the food value is over-estimated, 
 since the amount we actually use is small. This de- 
 
COCOA 
 
 155 
 
 pends to a large extent upon the manner in which the 
 beverage is prepared. The milk and sugar used add 
 appreciably to the nutriment, and if we follow Thudi- 
 chum's suggestion, we shall have a beverage of high 
 food value even if one questions its perfection in other 
 respects. He says : "Chocolate should be served in 
 cups and be of sufficient consistency to be eaten with a 
 small spoon, rather than drunk. In this way it was 
 used by the Mexicans ; they also ate it with golden 
 spoons. We have tasted the combination, and find 
 chocolate in a red cup and saucer, to be eaten with a 
 golden spoon, aesthctical perfection ; both taste and 
 sight are much-pleased with the combination." 
 
 The possible effect upon digestion of the theobro- 
 mine present has nt)t been fully determined. It is a 
 substance similar in character to caft"eine in coffee 
 and tea. These beverages, however, unlike cocoa, 
 have no food value. 
 
 The physiological eft'ect upon the system of tea, 
 coffee, and cocoa has been much discussed. Of the 
 three, cocoa seems to have much less inlluence eithci 
 in retardmg digestion or as a stimulant, though there 
 is reason to think that it is not without stimulating 
 efft;cts. 
 
 Tea has a marked influence in lessening the action 
 of the saliva, while both tea and coffee retard diges- 
 tion, the latter to a less extent than the former. This 
 effect seems due to the tannic acid and the volatde 
 oil. The caffeine ilsell' favors digestion. Both tea 
 
 Physiological 
 Effect of 
 Tea, Coffee 
 and Cocoa 
 
156 
 
 FOOD AND DIETETICS 
 
 Personal 
 Equation 
 
 Cereal 
 Coffee 
 
 and coffee act as stimulants because of the caffeine 
 present. It is this that causes them to be so effective 
 in lessening the feeling of fatigue. Strong coffee is 
 a powerful antidote to narcotics, and is often used 
 where a heart stimulant is needed. Coffee and tea 
 may, because of the tannic acid and other astringent 
 substances present, prove irritants to the mucous 
 membrane of the stomach. This action is greater if 
 the stomach is empty. The stimulating effect also is 
 greater if taken upon an empty stomach. 
 
 The effects of coffee and tea seem to be influenced 
 largely by the personal equation, and quite opposite 
 results are produced in different persons by them ; 
 while in most people they tend to produce wakeful- 
 ness, in others they are conducive to sleep. Some 
 people can use one freely and must refrain completely 
 from the other. 
 
 The general conclusion from experiment and ob- 
 servation seems to be that, taken in moderate quanti- 
 ties and at suitable times, they are not injurious to 
 the healthy adult, but that those of a feeble digestion, 
 or who are nervous, should use them in exceedingly 
 small quantities, if at all. Of the two, coffee seems 
 to have the least harmful effect in the majority of 
 cases. 
 
 On the market at present there are a large number 
 of coffee substitutes. Some of them undoubtedly are 
 true cereal drinks, and may be used as such, though 
 when a large amount of food value is attributed to 
 
COCOA 157 
 
 them on this account, one cannot help wondering how 
 the insohible substances of the wheat grain can so 
 largely be present in the drink made from the treat- 
 ment of wheat kernels in water. Some of the so- 
 called cereal coffees are said to derive their flavor 
 from the volatile oils produced in the roasting of cof- 
 fee, while others actually contain coffee. 
 
Pure Food 
 Campaign 
 
 ADULTERATION OF FOOD 
 
 Probably no food question has been so much dis- 
 cussed of late, or has appealed so generally to the 
 public at large as that of food adulteration. Nearly 
 all the states have passed laws providing for more or 
 less stringent regulations, and the United States 
 Congress has passed a national law and is considering 
 further legislation on the same subject. Alagazines 
 and newspapers have taken up the matter ; the wom- 
 en's clubs have enthusiastically pressed it and a vigor- 
 ous "pure food" cami)aign has been made. This is 
 right and proper ; but, either through ignorance, or 
 the belief that it is justifiable to do evil that good 
 may come, many statements are made that are not 
 only sensational in the extreme, but absolutely untrue. 
 ( )thers, while not absolutely wrong, convey a distinctly 
 false impression. 
 
 Mrs. Abel, in a recent article, calls attention t<i 
 some ty])es of sucli statements b\- the following illus- 
 tration : 
 
 "A baby has dined on a candy Easter egg and saus- 
 age, and the heading reads 
 
 DEATH EROAl COAL TAR COLOR IN 
 EASTER CANDY. 
 
 "Now sausage is not exactly an infant food anel 
 nn'ght perhaps have been held responsible for the 
 sad result, but sausage is a trite and common thing, 
 while chemical colors, bearing such a disagreeable 
 name will surelv catch the public eve! 
 
 158 
 
ADULTERATION OF FOOD 159 
 
 "And did we not read one other day that a promi- 
 nent hygienist had announced that 450,000 babies die 
 yearly in this country of poisoned milk? Few of us 
 had access to census reports from which to learn that 
 this is a much larger number than die yearly from all 
 causes under the ages of five, and perhaps fewer stiii 
 saw the indignant denial of this official, and learned 
 how a truthful and moderate statement can be dis- 
 torted." 
 
 One of our most reputable city dailies is responsibic 
 for the following absurd statement in the report of a 
 speech : 
 
 "Dr. Wilev, chief of the national bureau of chemis- ,. 
 
 Newspaper 
 
 try, says that nine-tenths of the deaths each year in statements 
 .this country are due to dyspepsia, generally caused b}- 
 impure food. He declares that the tendency also is to 
 shorten the duration of life, and cites figures to show 
 that 2,000,000 deaths in the ITnited States in the last 
 ten years have been traceable largely to the use of 
 bad iood. Tt is the workingman, the poor man, who 
 cannot afford to buy the higher priced articles of food, 
 who suffers more from tliese conditions. 
 
 ''\'iewed from an economic standpoint also, the 
 lal)oring man should be interested. In the report of 
 the Kentucky state board of health for last year the 
 statement is made that for every dollar spent in the 
 purchase of food, 45 cents on the average is paid for 
 adulterations." 
 
 "The implication here is even worse than the actual 
 
i5o FOOD AND DIETETICS 
 
 statement, for while "Impure food" and "bad food" 
 might inchide water and milk contaminated with ty- 
 phoid germs, or food that has been allowed to deteri- 
 orate by bacterial action till it is in a dangerous con- 
 dition, it is evident that the meaning intended to be 
 conveyed is that these phrases mean adulterated food. 
 
 The same paper in a recent editorial makes the ab- 
 solutely ungrounded charge that numerous deaths 
 have been caused by the presence of coal tar dyes in 
 candy. It implies that all manufacturers are actuated 
 by greed, and that they care nothing as to the poison- 
 ous character of their materials if only they make 
 money. 
 Glucose A circular advertising a certain breakfast food, 
 
 after dividing glucose into good and bad kinds, in- 
 troduces the following paragraph, saying that the 
 definition is from the dictionary, "Glucose, the 
 trade name of a syrup obtained as an uncrystallizable 
 residue in the manufacture of glucose proper, and 
 containing in addition to some dextrose or glucose, 
 also maltose, dextrine, etc. It is used as a cheap 
 adulterant of syrups, beers, etc. Thus we learn even 
 in this public way that there are harmless and harm- 
 ful kinds of glucose." 
 
 The implication is, of course, that glucose is untit 
 for food, and no account is taken of the facts that 
 maltose is a sugar perfectly wholesome and digestible, 
 and that dextrine is always an intermediate product in 
 the change of starch into sugar, whether this change 
 
of Adulterants 
 
 ADULTERATION OP FOOD. i6i 
 
 is induced by the action of acid as in the manufacture 
 of commercial glucose, or by a ferment as in the 
 change of starch into sugar by the saliva. 
 
 No good can come from exaggerated and false 
 statements, and it is the business of every woman who 
 has to do with the purchasing of foods to so inform 
 herself that she shall not be misled. 
 
 We may classify the adulterants of foods, using ciassiflcation 
 the term in a broad sense, under three headings . 
 First, additions or substitutions used for the sake of 
 cheapening the product ; second, material such as col- 
 oring matter, used either to imitate the natural prod- 
 uct or to beautify and make more attractive some 
 foods ; third, preservatives. Of the first class, by far 
 the greater number are such as afifect the pocketbook 
 and not the health. One of the common adulterants 
 of spices, for instance, is starch, and this only means 
 that when such a spice is used a larger amount is 
 needed than would be the case if it were pure. Cofifec 
 to which has been added chicory or ground peas oi 
 beans, or for which has been substituted an artificial 
 bean, cannot be said to be less wholesome because of 
 this treatment. Cream of tartar, because of its ex- 
 pense, is often adulterated, but again the adulterant is 
 usually harmless. Butterine substituted for butter 
 means the payment on the part of the consumer of a 
 large price for an inexpensive article ; but the article 
 consumed is in every way as digestible and whole- 
 some as if no substitution had been made. This and 
 
Labelling- 
 
 162 rOOD AND DIETETICS 
 
 many other articles used to adulterate more expensive 
 ones, have their own value, ard if placed upon the 
 market under their own names, mij^ht be profitably 
 used. There is no reason to think that corn syrup, or 
 glucose, with a flavoring- of caramel is less wholesome 
 than maple syrup, but we all justly object to having 
 the former product labelled with the name of the latter 
 and sold at its price. 
 Correct The crusadc against adulterations should then, so 
 
 far as this class is concerned, be directed toward full 
 and correct labelling, and against the possibility of 
 cheap articles being branded as superior ones or sold 
 at the price of the better article. The consumer should 
 demand the right to receive the full equivalent for 
 money paid, and every effort should be made, not onlj' 
 to have right laws passed but to see that frequent 
 tests are made of food materials bought in the open 
 market, and to compel manufacturers to make a cor- 
 rect statement of the ingredients in their wares. 
 
 On the part of the housekeeper there should be a 
 knowledge of materials, and ability to make simple 
 tests, while for such tests as imply technical chemical 
 knowledge material should be sent to the board of 
 health or other experts. Most of all, skill in interpref- 
 ing labels should be cultivated. A bottle purporting to 
 be vanilla and labelled 
 
 PURE VANILLA, 
 
ADULTERATION OF FOOD 163 
 
 on the face of it is not vanilla, though it may not 
 necessarily be a less wholesome article. 
 
 The second kind of materials that we have classed coloring 
 as adulterants — the colorino- matters, are used gener- 
 ally to satisfy a popular demand. Everyone knows 
 that fresh butter is seldom of the bright yellow color 
 of that on the market, yet few people would purchase 
 an uncolored butter. Because in June, under the best 
 conditions, butter is yellow, we have come to regard 
 that as the only desirable thing. The manufacturer of 
 a certain brand of cheese a few years ago made an 
 attempt to put an uncolored product on the market, 
 though he had formerly used coloring. To his sur- 
 prise, he could not sell his cheese. The public, ac- 
 customed to a deep orange color in that brand, said 
 the white cheese was not "so rich," that it was made 
 of skim milk instead of cream, and refused to accept it. 
 
 As soon as the purchasing public has a different 
 standard of values the manufacturer will cease to color 
 his products. He will be content to offer properly 
 canned tomatoes, even though the color is not as bril- 
 liant as that of the fresh fruit, and will put upon the 
 market a catsup more attractive though less bright 
 than the modern product. He will devise methods of 
 canning peas and beans that will change their color 
 as little as possible, but will not "green" them to de- 
 ceive a credulous public. At the same time, the dis- 
 honest manufacturer will have less opportunity to 
 conceal the inferiority of poor goods by the addition 
 of color. 
 
i64 . FOOD AND DIETETICS 
 
 Coal Tar Color is also used frankly to beautify articles, as in 
 
 the case of candy, and this seems legitimate when the 
 colors are harmless, and the coloring is delicate. In 
 this case, as in that of other uses of it, the question 
 arises as to the possible harmful effects of the colors 
 used. Of late the so-called coal tar dyes have been 
 frequently employed, and perhaps because of their 
 name much anethema has been directed against them. 
 As a matter of fact, most of the coal tar dyes used are 
 perfectly harmless, with absolutely no physiological 
 effect. They are so strong in coloring power that a 
 very minute amount is all that is necessary to give 
 the desired result. Some of the coal tar dyes are 
 poisonous, and should not be used, though again the 
 fact that so small an amount is required to produce 
 the effect is a protection. Some vegetable dyes aie 
 also poison, as well as some of the mineral dyes used 
 before the coal tar products were availal)le, and both 
 of these classes have less coloring power, and so must 
 be used in larger quantities. 
 
 That the confectioners are not all "monsters of 
 greed" "reeking" with the desire to make money at 
 the cost of the health and lives of an unsuspecting 
 public, is shown by the fact that long lists of harm- 
 less and harmful colors have been made by the Na- 
 tional Confectioners' Association, and that the same 
 association has offered resolutions for dealers in con- 
 fectioners' colors as well for manufacturers of candies, 
 urging only the legitimate use of non-poisonous col- 
 
ADULTERATION OF FOOD 
 
 165 
 
 ors. Legislation and public opinion should unite in 
 forbidding the use of any harmful coloring even in 
 minute quantities, and careful investigation should be 
 made and lists of safe colors presented. An educated 
 public will see no beauty in crude and vivid colors 
 and will demand only the most delicate shades in 
 candies and similar products, and this will mean less 
 coloring of any kind. 
 
 As to the use of preservatives in food, there is an 
 honest difference of opinion among experts. It is 
 contended by many that in proper amounts and under 
 proper regulation they are a desirable safe-guard, 
 since they keep in a fresh and wholesome condition 
 foods that would otherwise deteriorate. The amounts 
 necessary are so small that they would seem presum- 
 ably to have no effect on the users. On the other 
 hand, the user may not be a healthy adult, but an in- 
 fant or an invalid, presenting quite a different prob- 
 lem. In most cases a little more care would keep the 
 food in proper condition without the resort to doubt- 
 ful means. 
 
 The two sides of the case are stated as follows in 
 the" government pamphlet giving the result of the 
 famous borax experiment. 
 
 'Tt is admitted by all who have examined the sub- 
 ject in a critical way, even by the users of preserva- 
 tives, that in certain maximum quantities the limit of 
 toleration is reached in each individual and positive 
 injury i§ (JQne, gut it i§ abp well recognized that 
 
 Preservative* 
 
 Government 
 Statement 
 
i66 FOOD AND DIETETICS 
 
 many, if not all, of the usual foods when used in large 
 excess produce injurious results. The many cases of 
 disease produced by overeating, or by eating im- 
 properly prepared or poorly cooked foods, or by eat- 
 ing at unusual times, are illustrations of this fact. 
 Upon this basis and upon the further statement that 
 when used in extremely small quantities the preserva- 
 tives in question cannot be regarded as harmful, is 
 founded the principal argument in favor of the use 
 of the preservatives, aside from the fact that the 
 foods themselves are kept in a better and more whole- 
 some state.'' 
 Small "It would be useless to contend that the occasional 
 uan I les consumption of small quantities of boric acid in a 
 sausage, in butter, or in preserved meat would pro- 
 duce, even upon delicate stomachs, any continuing 
 deleterious effect which could be detected by any of 
 the means at our disposal, but naturally it seems that 
 this admission does not in any way justify the indis- 
 criminate use of this preservative in food products, 
 Implying, as it would, the equal right of all other 
 preservatives of a like character to exist in food 
 products without restriction. 
 
 "It appears, therefore, that there is no convincing 
 force in the argument for the use of small quantities 
 unless it can be established that there is only a single 
 preservative used in foods, that this preservative is 
 used in only a few foods, that it will be consumed in 
 extremely minute quantities, and that the foods in 
 
ADULTERATION OF FOOD 
 
 1^7 
 
 which it is found are consumed at irregular intervals 
 and in small quantities. On the other hand, the logi- 
 cal conclusion which seems to follow from the data 
 at our disposal is that boric acid and equivalent 
 amounts of borax in certain quantities should be re- 
 stricted to those cases where the necessity therefor 
 is clearly manifest, and where it is demonstrable that 
 other methods of food preservation are not applicable 
 and that without the use of such a preservative the 
 deleterious effects produced by the foods themselves, 
 by reason of decomposition, would be far greater than 
 could possibly come from the use of the preservative 
 in minimum quantities. In these cases it would also 
 follow, apparently, as a matter of public information 
 and especially for the protection of the young, the 
 sick, and the debilitated, that each article of food 
 should be plainly labeled and branded in regard to the 
 character and quantity of the preservative employed." 
 
 JNIany more experiments need to be conducted be- 
 fore we know the truth in the matter of preservatives. 
 jNIeanwhile most careful supervision of their use 
 should be exercised when they are allowed at all, and 
 every effort should be directed toward securing clean- 
 ly processes of food preparation, and such good condi- 
 tions that no preservatives should be needed other 
 than the ordinary ones of salt, sugar, spices, with the 
 l)rocesscs of smoking and sterilization. 
 
 Jhe jiiost common preservatives in general use arc 
 
 Conclusion 
 
 More 
 
 Experiments 
 
 Needed 
 
Tests 
 
 168 FOOD AND DIETETICS 
 
 formaldehyde, salicylic acid, benzoic acid, baking soda, 
 borax and boric acid. 
 Home Some of the simpler tests for food adulterants can 
 
 be successfully used by the housekeeper even without 
 technical training. 
 
 The following methods of distinguishing between 
 butter, oleomargarine and renovated butter are taken 
 from the farmers' bulletin on the subject : 
 
 The Spoon Test for Butter 
 
 In the kitchen the test may be conducted as fol- 
 lows : Using as the source of heat an ordinary kero- 
 sene lamp, turned low and with chimney off, melt the 
 sample to be tested (a piece the size of a small chest- 
 nut) in an ordinary tablespoon, hastening the process 
 with a splinter of wood (for example, a match). Then, 
 increasing the heat, bring to as brisk a boil as possible, 
 and after the boiling has begun, stir the contents of 
 the spoon thoroughly, not neglecting the outer edges, 
 two or three times at intervals during the boiling — 
 always shortly before the boiling ceases. In the labor- 
 atory a test tube, a spoon, or sometimes a small tin 
 dish, is used in making this test. From the last- 
 named utensils the test is often called the "spoon 
 test," and sometimes the "pan test." 
 
 A gas flame, if available, can be used perhaps more 
 conveniently than a kerosene lamp. 
 
 Oleomargarine and renovated butter boil noisily, 
 sputtering (more or less) like a mixture of grease 
 (ind >Y^t?r yvh?n boiled, and produce no foanij or ^ut 
 
ADULTERATION OF FOOD 169 
 
 very little. Renovated butter produces usually a very 
 small amount. 
 
 Genuine butter boils usually with less noise, and 
 produces an abundance of foam. 
 
 To Distinguish Oleomargarine from Genuine and Renovated Butter 
 
 Utensils Required. — The utensils required in the 
 test to distinguish oleomargarine from renovated and 
 genuine butters are as follows : 
 
 (i) A one-half pint tin "measuring cup," common 
 in kitchen use, marked at the half and quarters ; or a 
 plain one-half pint tin measure, ordinary narrow form , 
 or an ordinary small tin cup, 2^ inches in diameter 
 and 2 inches in height, holding about one gill and a 
 half. 
 
 (2). A common kitchen pan, about 9J^ inches m 
 diameter at the base. 
 
 (3). A small rod of wood, of the thickness of a 
 match and of convenient length for stirring. 
 
 (4). A clock or watch. 
 
 The Process. — The process for distinguishing oleo- 
 margarine from renovated and genuine butters is as 
 follows : 
 
 Use sweet skimmed milk, obtained by setting fresh 
 milk in a cool place for twelve to twenty-four hours 
 and removing cream as fully as possible. Half fill 
 with this milk the halT-pint cup or measure, or two- 
 ^hircls fill the srrialler cup mentioned, measuring acai- 
 
170 FOOD AND DIETETICS 
 
 rately the gill of milk when possible ; heat nearly to boil- 
 ing, add a slightly rounded teaspoonful of the butter or 
 butter substitute, stir with the wooden rod, and con- 
 tinue heating until the milk "boils up," remove at once 
 from the heat and place in the pan (arranged while 
 milk and fat are heating), containing pieces of ice 
 with a very little ice water, the ice to be mostly in 
 pieces of the size of one to two hens' eggs (not 
 smaller, as small fragments melt too rapidly) and 
 sufficient in quantity to cover two-thirds of the bottom 
 of the pan ; the water to be in quantity sufficient, 
 when the cup is first placed in the pan, to reach on 
 the outside of the cup to only one-fourth the height of 
 the milk within ; any water in excess of that amount 
 must be removed. (This refers to the condition at 
 the beginning of the cooling; later, as the ice mells, 
 the water will rise to a higher level.) Stir t'ne con- 
 tents of the cup rather rapidly, with a rotary and a 
 cross-wise motion in turn, continuously throughout 
 the test, except during the moment of time required 
 for each stirring of the ice and watCi- in the pan, 
 which must be done thoroughly once every minute by 
 the clock. This is done by moving the cup about, in 
 a circle, following the edge of the pan. Proceed in 
 this manner for ten minutes, unle»s before that tmie 
 the fat has gathered or has allowed itself to be easily 
 gathered in a lump or a soft ma^s, soon hardening. If 
 it so gathers, the sample is oleomargarine ; if not, it i-s 
 either genuine or renovated butter," 
 
ADULTERATION OF FOOD 171 
 
 It will be seen that by trying both of these tests 
 one may determine which of the three a suspected 
 sample of butter really is. 
 
 A method of determining the presence of coal tar 
 dyes in foods has been given in the following words 
 by a recent writer : 
 
 "Suppose that some cheap currant icily is to be ex- Test for 
 
 , ^ . , \. , , . . Aniline 
 
 ammed. Stir up about one-fourth of the contents ot colors 
 the tumbler of jelly with about a pint of water in an 
 agate stewpan. Take a piece of white woolen clolli 
 al^out five or six inches square and wet it thoroughly 
 with boiling water. Care should be taken that it is 
 "all wool," and white is. better than cream color, 
 Xun's veiling is an excellent thing to use. Immerse 
 the cloth in the diluted jelly and boil it on the stove 
 for five or ten minutes, stirring it frequently with a 
 small wooden stick. Then remove it and wash well in 
 boiling water. If a dye has been used in the jelly 
 the cloth will be brightly colored. 
 
 "Natural colors impart to the wool, when treated in 
 this way, only a dull pinkish-brown color, quite dif- 
 ferent from the brilliant color of the artificial dye. 
 In order to be absolutely certain, however, it is best 
 to take the dyed w'ool and boil it with about a table - 
 spoonful of ordinary household ammonia in half a 
 pint of water. After boiling for five minutes, remove 
 the wool, and if the ammonia is colored add to it a 
 third of a cupful of vinegar, immerse it in a second 
 piece of the white woolen cloth and boil it as before. 
 Any color that is imparted to tl^e second piece of 
 
Test 
 
 172 FOOD AND DIETETICS 
 
 cloth IS the anaHne dye, which was dissolved off by 
 the ammonia. The natural color would not be re- 
 moved from the first cloth by the ammonia, hence 
 would not dye on the second piece. The coloring can 
 be boiled out of sausages and dyed on wool in the 
 same way." 
 
 "Another interesting way of showing the presence 
 Gei3+iT"> of these dyes, especially in beverages, is to dye them 
 on gelatine. Dissolve one part of gelatine in ten 
 parts of boiling water and pour it into a deep pan to 
 harden. When it is cold, by means of a sharp knife 
 cut it into inch cubes. Place one of these cubes into 
 the suspected liquid and allow it to remain for twenty- 
 four hours, then wash it slightly with cold water and 
 cut through it with a knife. If the color is a natural 
 one it will lightly tinge the outer surface of the cube, 
 but will not penetrate far below the surface, so that 
 the inner portions will be largely free from color. 
 Nearly all of the coal-tar dyes, cochineal and similar 
 colors, will be found to permeate the jelly cube, often 
 to the center. 
 
 "One advantage of the dyeing on cloth, however, 
 is that the sample can be preserved as evidence. 
 Nothing is better than ocular proof to convince the 
 average person." 
 
 Several other tests for food adulteration have been 
 given under the special foods or in other papers of 
 this series. (See also Bulletin No. 100. Some Forms 
 of Food Adulteration and Simple Methods for Their 
 Detection. Price 10 cents, of the Supt. of Documents, 
 Washington, P, C.) 
 
SPECIAL CIET 
 
 The housekeeper of today must know not only how 
 to select food for the normal member of her house- 
 hold, and how to provide for the varying needs of 
 different ages and activity, but she is many times 
 called upon to direct the diet of an invalid or a delicate 
 child or to provide special foods for those who are 
 
 sick. 
 
 It is not her province to diagnose a case, or to Housekeeper's 
 prescribe special diet, but it is her part to be able in- 
 telligently to carry out the directions of a physician. 
 If the invalid is to have starchy foods eliminated from 
 his menu, the housekeeper must know where to turn 
 to obtain foods that will furnish the requisite number 
 of calories without recourse to carbohydrates, and 
 she must be able to prepare such food in a palatable 
 manner; if the diet is to contain a large amount of 
 fat, as in the case of a tubercular patient, she must 
 know where to obtain this food in a digestible form, 
 and, if there is need for economy, how to substitute 
 cheap forms of fat for the more expensive ones. She 
 must know, when the direction is given for a nourish- 
 ing diet, how to add the egg or milk that is required, 
 or to substitute some other form of food if these are 
 not acceptable. 
 
 The housekeeper then, so far as invalid diet is con- 
 cerned, should be familiar first, with the composition 
 of the ordinary food materials, and second, with the 
 relative digestibility of the different foods so far as 
 
 173 
 
Children 
 
 174 rOOD AND DIETETICS 
 
 that knowledge is available and with their physio- 
 logical effect. Then, and then only, can she intelli- 
 gently carry out the directions given. 
 Food for One of the troublesome proljlems for the mother is 
 
 the deciding upon the right food for children, espe- 
 cially for those of school age. While the physician 
 will direct her in the care of her invalids, and in the 
 food necessary for the young baby, she is usually left 
 to work out her own problems so far as the older child 
 is concerned. One reason for this is that compara- 
 tively little attention has been given to this matter, 
 while the diet for the baby has been studied for years. 
 
 Fortunately the healthy child settles the matter for 
 himself to quite an extent and his own normal appe- 
 tite guides him up to a certain point. But a normal 
 appetite may easilv become perverted, and lead him 
 :!ar astray. 
 
 As we have seen, the child needs a larger percent- 
 Proteid ^gg q£ proteid in the diet than the adult. At about 
 ten or twelve years the needs of the body rapidly .in- 
 crease, and a far larger amount of food in proportion 
 to body weight is used than in the case of the adult. 
 The mother who has a growing boy of this age is 
 often astonished at the amount of food he eats and 
 seems to need. The chart given on page 51 shows 
 the proportional amounts of th.e different foods needed 
 at different ages. 
 
 Little anxiety need be felt lest the child overeat if 
 the food be properly masticated and so taken slowly, 
 
 High 
 
Children' 
 
 SrnCl.lL DIET 175 
 
 if it be of the right kind, and if it be taken at proper 
 times. The latter point is particnkarly important m 
 its relation to sweets. Candy at the end of a meal 
 for dessert is legitimate and even desirable, Init the 
 same article bought at the candy store and eaten on 
 the way home from school before dinner is seriously 
 objectionable, since it satisfies the appetite and lessens 
 the desire for the regular meal without giving ade- 
 quate nourishment. An over amount of sugar may 
 easily be taken in this way while rarely, if ever, docs 
 this happen if the appetite is first largely satisfied with 
 bread and milk, vegetables and meat. 
 
 The often objectionable children's party would be 
 robbed of its evil efifects if simple, attractive sand- Parties 
 wiches were always provided in aluindance before the 
 ice cream and cake were ofifered, since few children 
 would over-eat of the latter under these circumstances. 
 
 If children are to be allowed to eat freeh^ the food 
 must be simple in character and easy of digestion. 
 The ordinary meats, with the exclusion of pork, 
 cooked simply, few "made" dishes, an abundance of 
 vegetables and fruits, only the simplest puddings, no 
 pastry, occasional plain cake (not betw^een meals), 
 plent}- of the best of bread and butter, of well cookcl 
 cereals and of milk and eggs will furnish variety 
 sufficient for anyone. Tea and cofifee are to be re- 
 served for the adult, while cocoa may be used in mod- 
 eration, chiefly for the milk with which it is made. 
 Highly seasoned foods are to be avoided, as they tend 
 
176 
 
 FOOD AND DIETETICS 
 
 Fat in 
 
 the Child's 
 
 Diet 
 
 Omniverous 
 Tastes 
 
 to excite unduly the flow of the digestive juices and 
 gradually make such flow dependent on their stimu- 
 lation. Their continued use also seems to induce a 
 craving for strong stimulants. 
 
 It is necessary to encourage many children to eat 
 more fat than they are inclined to do. This may as 
 legitimately be taken in the form of butter and cream 
 as in that of fat meat, so generally repungant to chil- 
 dren. Hutchison suggests that toffee taken at the end 
 of the meal is a good medium for fat when there is 
 difficulty in giving sufficient in other ways. 
 
 With young children special attention must be paid 
 to the digestibility of the food. This is frequently a 
 matter of personal idiosyncracy, and when this is the 
 case the matter can only be determined by experiment. 
 The safe way is to begin the diet with foods which 
 are generally easily digested, and to allow those more 
 difficult of digestion only at a later period. If any 
 one article proves unwholesome in the particular case, 
 it should of course be discarded. 
 
 On the other hand, it is most undesirable that chil- 
 dren should grow up without learning to like all 
 ordinary foods, and without being able to eat every 
 kind of wholesome food. Such habit cannot be ac- 
 quired unless a certain variety is provided and unless 
 the child who is old enough be encouraged to try dif- 
 ferent articles. Even those less easily digestible may 
 at a proper age be taken occasionally with impunity, 
 for the sake of accomplishing this end. Vegetables, 
 
SPECIAL DIET 177 
 
 while so desirable in the diet, often SQftm to be an ac- 
 quired taste. 
 
 Above all things there should be no yielding to a 
 child's whims in allowing him to refuse the food of- 
 fered and to require special provision for himself. 
 
 The question of eating between meals is one that Eating 
 frequently arises. During the school period there is MeaU*° 
 difficulty in providing fqod at sufficiently short inter- 
 vals. The child who has breakfasted early, often be- 
 comes exhausted before the time of the noon meal. 
 This exhaustion sometimes is shown by the apparent 
 stupidity or the inattention and restlessness of the 
 child, and sometimes by extreme irritability. Wher- 
 ever this interval is a long one, there should be pro- 
 vision for some luncheon during the morning. 
 School lunches have been established in many places . 
 and when well conducted serve an excellent purpose. 
 Where the establishment of such a luncheon is not 
 possible, a light lunch carried from home, such as a 
 sandwich, a sHce of bread and butter sprinkled with 
 sugar, or even some fruit or sweet chocolate, eaten 
 in the middle of the morning, will do much to preserve 
 the good temper of the child and to make it possible 
 for him to do his work adequately. The child who 
 at home grows hungry between meals should be al- 
 lowed to have something to eat, provided it be bread 
 and butter, a sandwich, or crackers and milk, or fruit. 
 With the younger children the heartiest meal should 
 be in the middle of the day, and the evening meai 
 
178 rOOD AND DIETETICS 
 
 should 1ic chosen with especial reference to ease in 
 digestion. 
 
 In general, then, the food for children should differ 
 from that of adults, first, in heing of the most simple 
 character; second, in the absence of stimulating sub- 
 stances, such as large amounts of spice ; third, in the 
 proportions of the different food principles. In addi- 
 tion to this the child should think as little as possible 
 about the food he eats. The constant discussion of 
 the wholesomeness of different articles of diet and the 
 consequent directing of the attention of the child to 
 his own bodily processes seems distinctly harmful. 
 Such discussion should only be used when necessary 
 in order to show the unsuitableness of some especially 
 desired food that must be denied. Good habits in 
 regard to food should be established at this age. rather 
 than theories about it. 
 students' Much has been said in regard to food for older 
 
 students, and a number of studies of student diet have 
 been made. A few points only can be considered. 
 In the first place, the student is leading a sedentary 
 life, and does not need the hearty food required by 
 the laborer or the one who is doing much outdoor or 
 manual work. The proportion of proteid should be 
 somewhat high in comparison with that of the carbo- 
 hydrates, and the food should be simple and digestible, 
 in order that but little energy be used in carrying on 
 the processes of digestion. 
 
 Diet 
 
SPECIAL DIET 179 
 
 A good variety is needed, however, and especial 
 care must be exercised to make the food attractive 
 that the appetite may be stimulated. The compara- 
 tively small amount of exercise taken generally by 
 the student makes this especially necessary, though no 
 amount of attention paid to the food can or should be 
 a substitute for the healthy appetite. 
 
 As in the case of the child, it is frequently wise for 
 the student to eat oftener than at the regular meal 
 time. A glass of milk, a cup of cocoa, or of broth 
 with a cracker in the middle of the morning will often 
 prevent a headache from exhaustion. 
 
 Old age needs especial consideration in regard to old Age 
 diet as well as youth. xA.fter middle life the total °'® 
 amount of food needed lessens somewhat, and the 
 proportion of building Material, both of proteids and 
 of mineral salts is less. Again, as in childhood, care 
 must be exercised in regard to digestibility and sim- 
 plicity of food. Often special conditions of the cys- 
 tem must be considered and certain kinds of food 
 avoided, but this is a matter for intelligent following 
 of a physician's directions. 
 
 One of the question that frequently arises in regard 
 to diet is that of reducing or increasing flesh by this 
 means. Increase in weight implies that more food is 
 taken into the body than is utilized in the repair of 
 waste and in work. To prevent the storage of fat more 
 work must be performed or less food taken. The well 
 known systems for curing obesity depend chiefly on 
 the reduction of the total amount of food, — some- 
 
i8o FOOD AND DIETETICS 
 
 times to two-fifths of the standard dietary, and on the 
 lessening of the proportion of fats and carbonydrates, 
 especially of the latter. So radical a treatment as this 
 should only be undertaken under the direction of a 
 physician as there is a possibility of serious injury to 
 health, A diminution of the sugar and starch in the 
 diet and a slight lessening of the total amount eaten 
 with increased light exercise may be undertaken by 
 almost anyone with the result of decreasing the fat of 
 the body. 
 
 The converse of course holds true. Rest, a full diet, 
 and one rich in carbohydrate and fat tend to increase 
 the storing of fat in the body, although there is occa- 
 sionally a person who fails to respond to such treat- 
 ment. In increasing the diet due regard must be paid 
 to the digestive powers of the individual that they may 
 not be over-taxed. 
 
 It is said that some orieotel countries, wiser than 
 we, have a custom of paying the physician for keep- 
 ing the family well, not for restoring the sick mem- 
 ber to health. In the absence of such a custom and 
 with physicians not trained for this purpose, the 
 housemother herself must perform this office. 
 
 Special diet in disease must be directed by the physi- 
 cian, for the housekeeper, even though she informs 
 herself upon the general principles of such diet, can- 
 not recognize special symptoms that often require in- 
 dividual modification of general rules. She must con- 
 tent herself, then, with the role of preserver of health, 
 and though she can by no means ward off all sick- 
 ness by the best planned dietary, she can do much 
 toward strengthening the constitution of the members 
 of her family, and making their bodies more resistant 
 to disease. 
 
BIBLIOGRAPHY 
 
 A. B. — Z of Our Own Nutrition ($i.oo, postage .10). 
 Horace Fletcher. 
 
 Air, Water, and Food ($2.00, postage .18). Richards and 
 Woodman. 
 
 Corn Plants ($1.00, postage .08). F. L. Sargent. 
 
 Cost of Food ($1.00, postage .10). Ellen H. Richards. 
 
 Cost of Living ($1.00, postage .10). Ellen H. Richards. 
 
 Dietary, The ($0.15, postage .02). Ellen A. Huntington. 
 
 Dietary Computer ($1.50, postage .12). Ellen H. Richards. 
 
 Dietetic Value of Bread ($1.50, postage .14). Goodfellow. 
 
 Diet in' Relation to Age and Activity ($1.00, postage .08). 
 Sir Henry Thompson. 
 
 Elements of the Theory and Practice of Cookery ($1.00, 
 postage .08). Williams and Fisher. 
 
 Essentials of School Diet ($2.00). Clement Dukes. 
 
 Essentials of Chemical Physiology ($1.50, postage .14). 
 Halliburton. 
 
 Food ($1.20, postage .08). A. H. Church. 
 
 Food as a Factor in Student Life ($0.25, postage .02). Rich- 
 ards and Talbot. 
 
 Food and Its Functions ($1.00. postage .08). James Knight. 
 
 Food Inspection and Analysis ($7.50). Albert E. Leach. 
 
 Food Products of the world (.$1.50, postage .14). Mary E. 
 Green, M. D. 
 
 Food and the Principles of Dietetics ($3.00, postage .26). 
 Robert Hutchison, M. D. 
 
 Food and Feeding ($1.75, postage .14). Sir Henry Thomp- 
 son. 
 
 Food in Health and Disease ($5.00). I. B. Yeo. 
 
 Food Materials and their Adulterations ($1.00, postage .08). 
 Ellen H. Richards. 
 
 Handbook of Domestic Science and Household Arts (^1,00; 
 postage .10). L, L. W. Wilson, 
 
 * - ■ m 
 
i82 FOOD AND DIETETICS 
 
 How to Feed Children ($i.oo, postage .10). Louise E. Ho- 
 gan. 
 
 Milk and Its Products ($1.00, postage .08). Wing, 
 
 Physiological Economy in Nutrition ($3.00, postage .20). 
 R. H. Chittenden. 
 
 Plain Words About Food (Rumford Leaflets) ($1.00, post- 
 age .06). E. H. Richards. 
 
 Practical Dietetics ($5.00). Oilman Thompson, M. D. 
 
 Practical Sanitary and Economic Cooking ($0.40, postage 
 .06). Mary Hinman Abel. 
 
 Story of a Grain of Wheat ($1.00, postage .10). W. C. 
 Edgar., 
 
 Story of the Living Machine ($0.35, postage .04). H. W.' 
 Conn. 
 Note. — Books may be ordered through the School at the 
 
 prices given. Any book for which the postage is given may 
 
 be borrowed by members of the School for one week. Send 
 
 the postage in stamps with the request. 
 
 V. S. BEPARTMENT OF AGRICULTURAL PUBLICATIONS 
 Fanuert^' Bulletin!). 
 
 Free, of the Department of Agriculture, Washington, D. C. 
 
 No. 34 — Meats, Composition and Cooking. 
 
 No. 42 — Facts About Milk. 
 
 No. 63 — Care of Milk on the Farm. 
 
 No. 74 — Milk as Food. 
 
 No. 85 — Fish as Food. 
 
 No. 93 — Sugar as Food. 
 
 No. 112 — Bread and the Principles of Bread Making. 
 
 No. 121 — Beans. Peas and other Legumes as Food. 
 
 No. 128 — Eggs and their Uses as Food. 
 
 No. 129 — Sweet Potatoes. 
 
 No. 142 — Principles of Nutrition and the Nutrjtiv? Valu^ 
 
 9i Fopa, 
 
BIBLIOGRAPHY 183 
 
 No. 175 — Home Manufacture and Use of Unfermented 
 Grape Juice. 
 
 No. 182 — Poultry as Food. 
 
 No. 183— Meat on the Farm: Butchering, Curing, and 
 Keeping. 
 
 No. 203 — Canned Fruit, Preserves and JeUies. 
 
 Reprint from Year Book of 1900 — The \'ahie of Potatoes 
 as Food. 
 
 Reprint from Year Book of 1902 — The Cost of Food as Re- 
 lated to Its Nutritive Value. 
 
 Circular No. 43 — Foods, Nutrients, Food Economy. 
 
 Circular No. 46 — The Functions and Uses of Food. 
 
 Also, see the List of Bulletins and Circulars of U. S. De- 
 partment of Agriculture for Free Distribution, for contents of 
 the Farmers' Bulletins called "Experimental Work,"' which 
 have many brief articles of interest, compiled chiefly from 
 State Agricultural Station reports. 
 STATE AGRICULTURAL EXPERIMENT STATION BULLETINS. 
 
 Free, within their own states, usually sent to others free or 
 for a two cent stamp. Apply to the various stations. 
 Maine Agricultural Experiment Station, Orono, Maine. 
 
 Bulletin No. 54 — Nuts as Food. 
 
 Bulletin No. 65 — Coffee Substitutes. 
 
 Bulletin No. 84 — Cereal Breakfast Foods. 
 
 Bulletin No. 118 — Cereal Foods. 
 Illinois Agricultural Experiment Station, Urbana, 111. 
 
 Circular No. 71 — Roasting of Beef. 
 Cornell Agricultural Experiment Station, Ithaca, N. Y. 
 
 Bulletin No. 230 — The Cooking Quality of Potatoes. 
 Minnesota Agricultural Experiment Station, St. Paul, Minn. 
 
 Bulletin No. 74 — Digestibility of Beans. 
 
 Bulletin No. 92 — Digestibility of Cabbage, Cheese, Rice, 
 Peas and Beans. 
 
 Note. — There are many other State bulletins but their re- 
 sults are usually republished in the bullctin^b of the Office of 
 
 E?cperiment StatipnSi 
 
i84 FOOD AND DIETETICS 
 
 FOR SALE BULLETINS OF THE OFFICE OF EXPERIMENT 
 STATIONS. 
 
 Send coin or money order (stamps not accepted) to the 
 Superintendent of Documents, Washington, D. C. 
 
 No. 28 — The Chemical Composition of American Food Ma- 
 terials. By W. O. Atwater. Price 5 cents. 
 
 No. 29 — Dietary Studies at the University of Tennessee in 
 1895. By Chas. E. Wait, Ph. D. Price 5 cents. 
 
 No. 35 — Food and Nutrition Investigations in New Jersey. 
 By Edward B. Voorhees. Price 5 cents. 
 
 No. 40 — Dietary Studies in New Mexico. By Arthur Goss, 
 M. S. Price 5 cents. 
 
 No. 43 — Losses in Boiling Vegetables and the Composition 
 and Digestibility of Potatoes and Eggs. By H. Snyder, B. S. 
 Price 5 cents. 
 
 No. 52 — Nutrition Investigations in Pittsburg, Pa. By Isabel 
 Bevier, Ph. M. Price 5 cents. 
 
 No. 53 — Nutrition Investigations at the University of Ten- 
 nessee. By Chas. E. Wait, Ph. D. Price 5 cents. 
 
 No. 55 — Dietary Studies in Chicago. Jane Addams and 
 Caroljjie L. Hunt. Reported by W. O. Atwater. Price 5 
 cents. 
 
 No. 63 — Description of a New Respiration Calorimeter and 
 Experiments on the Conversion of Energy in the Human 
 Body. By W. O. Atwater, Ph. D. Price 10 cents. 
 
 No. 84 — Nutrition Investigations at the California Agri- 
 cultural Experiment Station. By M. E. Jaffa, M. S. Price 5 
 cents. 
 
 No. 85 — A Report of Investigations on the Digestibility and 
 Nutritive Value of Bread. By Chas. D. Woods. Price 5 
 cents. 
 
 No. pi^Nutrition Investigations at the University 01 Illi- 
 nois, North Dakota Agricultural College, and Lake Erie Col- 
 lege, Ohio. By H. S. Grindlcy, J. L. Sammis, E. F. Ladd, 
 Isabel Bevier, and Elizabeth C. Sprague, Price 5 cents. 
 
BIBLIOGRAPHY 185 
 
 No. lOi — Studies on Bread and Bread Making at the Uni- 
 versity of Minnesota. By Henry Snyder, B. S. Price 5 cents. 
 
 No. 102 — Experiments on Losses in Cooking Meat. By H. 
 S. Grindley, D. Sc. Price 5 cents. 
 
 No. 107 — Nutrition Investigations Among Fruitarians and 
 Chinese at the California Agricultural Experiment Station. 
 By M. E. Jaffa, M. S. Price 5 cents. 
 
 No. 126 — Studies on the Digestibility and Nutritive Value 
 of Bread at the University of Minnesota in 1900-.1902. By 
 Harry Snyder, B. S. Price 5 cents. 
 
 No. 129 — Dietary Studies in Boston and Springfield, Mass., 
 Philadelphia, Pa., and Chicago, Hi. By Lydia Southard, El- 
 len H. Richards, Susannah Usher, Bertha M. Terrill, and 
 Amelia Shapleigh. Price 10 cents. 
 
 No. 132 — Further Investigations Among Fruitarians at the 
 California Agricultural Experiment' Station. By M. E. Jaffa, 
 M. S. Price 5 cents. 
 
 No. 141 — Experiments on Losses in Cooking Meat, 1900- 
 1903. By H. S. Grindley, D. Sc. Price 5 cents. 
 
 No. 143 — Studies on the Digestibility and Nutritive Value 
 of Bread at the Maine Agricultural Experiment Station, 1899- 
 1903. By C. D. Woods. Price 5 cents. 
 
 No. 149 — Studies of the Food of Maine Lumbermen. By 
 C. D. Woods. Price 10 cents. 
 
 No. 152 — Dietary Studies with Harvard University Stu- 
 dents. By Edward Mallinckrodt, Jr. Price 5 cents. 
 
 No. 156 — Studies of the Digestibility and Nutritive Value of 
 Bread and of Macaroni at the University of Minnesota. By 
 Harry Snyder, B. S. Price 10 cents. 
 
 No. 162 — Studies on the Influence of Cooking upon the Nu- 
 tritive Value of Meats at the LTniversity of Illinois, 1903- 1904, 
 By H, S. Grindley, Sg, D, Price 15 cents, 
 
i86 FOOD AND DIETETICS 
 
 PURE FOOD 
 
 Circular No. i6 — Officials cliarged with the Enforcement of 
 Food Laws in the United States and Canada. 
 
 Circular No. 17 — Standards of Purity for Food Products. 
 
 Circular No. 59 — Influence of Formaldehyde on the Diges- 
 tive Enzymes. 
 
 Extract No. 44 — Butter Substitutes. 
 . Extract No. 221 — The Use and Abuse of Food Preserva- 
 tives. 
 
 Extract No. 328 — Determination of the Effect of Preserva- 
 tives on Food and Health. 
 
 Extract No. 331 — The Adulteration of Drugs. 
 
 Farmers' Bulletin, No. 131 — Household Tests for the Detec- 
 tion of Oleomargarine and Renovated Butter. 
 
 Bulletin No. 13 — (Bureau of Chemistry). Part 9, Cereals 
 and Cereal Products. Price 5 cents. 
 
 Bulletin No. 13 — (Bureau of Chemistry). Part 10, Pre- 
 served Meats. Price 10 cents. 
 
 Bulletin No. 84 — (Bureau of Chemistry). Influence of Food 
 Preservatives on Health, Part I Boric Acid and Borax. Price 
 30 cents. 
 
 Bulletin No. 69 — (Bureau of Chemistry). Food and Food 
 Control. (Revised). Parts I, II, III, IV, V, VI, VII, VIII. 
 Price 5 cents each. 
 
 National laws to 1905 in Part I and laws of all the States 
 in alphabetical order. Request State laws wanted. 
 
 Bulletin No. 100 — (Bureau of Chemistry). Some Forms 
 of Food Adulteration and Simple Methods for their Detec- 
 tion. Price ID cents. 
 
 Bulletin No. 46 — (Bureau of Animal Industry). The Milk 
 Supply of 200 Cities and Towns. Price 15 cents. 
 
 Bulletin No. 70 — (Bureau of Animal Industry). Milk Sup' 
 ply of 29 Southern Cit'eg, Frice 5 C?nt5. 
 
BIBLIOGRAPHY 187 
 
 Bulletin No. 8l — (Bureau of Animal Industry).' The Milk 
 Supply of Boston, New York, and Philadelphia. Price 5 cents. 
 
 Also, see State publications on pure food, especially bulle- 
 tins and reports of North Dakota Experiment Station, Fargo. 
 N. D. ; Wyoming Agricultural Experiment Station, Laramie, 
 Wyo. ; Wisconsin Dairy and Food Commission, Madison, 
 Wis.; Pennsylvania Dairy and Food Commission, Harrisburg. 
 Pa.; Massachusetts State Board of Health, Boston, Mass.; 
 Maine Agricultural Experiment Station, Orono, Me. ; Nebras- 
 ka Food Commission, Lincoln, Neb. ; Minnesota Dairy and 
 Food Commission, St. Paul, Minn., etc. 
 
 rERIODlC.\LS AND LISTS. 
 
 Experiment Station Record, published by U. S. Department 
 of Agriculture, Office of Experiment Stations. Price $1.00. 
 Published monthly and contains extracts and summaries of 
 national and state publications, foreign and domestic maga- 
 zines, and current books relating to food and the work of the 
 various departments. 
 
 The Monthly List of New Publications of the Department 
 of Agriculture will be sent regularly to all who apply for 
 it. (Free.) 
 
 Complete list of bulletins for free distribution and for sale 
 will be sent on application to the Department of Agriculture, 
 also the list food of the Office of Experiment Stations, Bureau 
 of Chemistry, etc. 
 
TEST QUESTIONS 
 
 The following questions constitute the "written reci- 
 tation" which the regular members of the A. S. H. E. 
 answer in writing and send in for the correction and 
 comment of the instructor. They are intended to 
 emphasize and fix in the memory the most important 
 points in the lesson. 
 
FOOD AND DIETETICS 
 
 PART 111 
 
 Read Carefully. It will be advisable to read the fol- 
 lowing United States Department of Agriculture Bulletins in 
 connection with this lesson: No. 121 — Beans, Peas, and 
 Other Legumes as Food. No. 129 — Sweet Potatoes. Re- 
 print — The Value of Potatoes as Food. Circular No 17 — 
 Standards of Purity for Food Products. Circular No. 16 — 
 Officials Charged with the Enforcement of Food Laws. Ex- 
 tract No. 221 — Use and Abuse of Food Preservatives. Make 
 your ansifers full and complete. 
 
 1. In what different ways may vegetables be classi- 
 » fied r Classify the following according to each 
 
 method : Tomatoes, potatoes, sweet potatoes, 
 squash, turnips, beets, green corn, lettuce, spin- 
 ach, cabbage, green peas, dried peas, string 
 beans, dried lima beans, celery, rice. 
 
 2. How does the percentage of water in milk com- 
 
 pare with that in vegetables and fruits? 
 
 3. How does the presence of cellulose in vegetables 
 
 affect our use of them? 
 
 4. \\'hy do vegetables have an important place in 
 
 the diet? 
 
 5. Compare fruits and nuts as to food value. 
 
 6. Name three fruits that have a high food value. 
 
 7. Compare tea, coffee and cocoa as beverages. 
 
 8. Describe the process of the preparation of tea for 
 
 the market, and account for the names of dif- 
 * ferent kinds. 
 
 9. What are the reasons for prohibiting the adultera- 
 
 tion of foods? 
 10. fa) How ought this to be accomplished? (b) 
 What do you know of the food laws in your 
 own state? 
 
FOOD AND DIETETICS 
 
 11. Give examples, from your own experience if pos- 
 
 sible, of misleading statements in regard to 
 food, and show the truth in the matter. 
 
 12. Can you suggest any way in which standards may 
 
 be changed so that the public will not demand 
 such articles as colored butter? 
 
 13. Give the arguments for and against the use of 
 
 preservatives. Which side seems to you to have 
 the better case? 
 
 14. Try the two tests for distinguishing butter, but- 
 
 terine, and renovated butter, and report your 
 results. 
 
 15. How should the diet of a child, say from five' to 
 
 ten years of age, differ from that of the adult? 
 
 16. What is the objection to the use by the child of 
 
 tea, coffee and highly seasoned food? 
 
 17. What control should be exercised over eating be- 
 
 tween meals on the part of the child? 
 
 18. What is the need for fat in the child's diet? In 
 
 what ways may it be supplied? 
 
 19. Make out a menu for three days for a child of 
 
 about eight. 
 
 20. What is the province of the housekeeper in re- 
 
 gard to food for the sick? 
 
 21. Summarize the chief new points that you have 
 
 learned from Food and Dietetics. 
 
 22. To what extent and how has the study of these 
 
 lessons resulted in the modification of your own 
 diet or that of your family? 
 
 23. What questions have you ? 
 
 Note. — After completing the test, sign your full name. 
 
FOOD AND DIETETICS 
 
 NOTES ON THE QUESTIONS 
 
 The chief difficulty that our students seem to have 
 in answering the questions seems to be in the calcu- 
 hitions necessary in question 6 and 21 of Part I. 
 These seem to arise chiefly from lack of practice in 
 using percentages. 
 
 Question 6 reads: " Which would be the cheaper 
 source of proteid, beefsteak at 22 cents per pound, 
 milk at 7 cents per quart, bread at 5 cents per pound, 
 corn meal at 3 cents per pound?" 
 
 As percentage simply denotes the number of parts 
 in 100, it seems simplest in this problem to calculate 
 the cost of I pound of proteid in 100 pounds of each 
 of the materials, viz., if beef contains 19^, of 1 ro- 
 teid (table page 57), 100 pounds of beef will contain 
 19 pounds of proteid, and 
 
 100 lbs. beef steak @ 22c. a lb. costs $22.00. Then 
 I lb. proteid in beef steak will cost $22.00 -r- 19 
 = $1.15 per lb. 
 In the same way, — 
 
 100 lbs. of milk with ^.^% proteid contains ^.:^ lbs. 
 
 100 lbs. milk = 50 qts. @ 7c. a qt. costs $3.50. i lb. 
 
 proteid in milk costs $3.50 -^ 3.3 = $1.06 per lb. 
 
 In like manner, the cost of one pound of proteid 
 in bread and in com meal is obtained with little cal- 
 
 191 
 
1.92 
 
 FOOD AND DIETETICS 
 
 culation and the cheapest source of proteid is obvious. 
 In the use of percentage and decimals, to avoid errors 
 in pointing off, note whether the answer is reason- 
 able. 
 
 Although Question 21 is optional, — "Calculate 
 the amount of proteid, carbohydrates, and fat in 
 own diet for one day as nearly as 3'ou can," a num- 
 ber of interesting solutions have been sent in. The 
 following is a good example; 
 
 MENU 
 
 Breakfast 
 
 Orange 
 
 3 oz. 
 
 Oatmeal 
 
 K " 
 
 Cream 
 
 1% " 
 
 Sugar 
 
 1/ '• 
 
 /2 
 
 Toast 
 
 2 " 
 
 Butter 
 
 Va, " 
 
 Lunch 
 
 Potato Soup 
 Potato 
 Milk 
 Butter 
 Flour 
 
 Cold Beef 
 
 Bread 
 
 Butter 
 
 Chocolate 
 Milk 
 Sugar 
 Chocolate 
 
 K 
 
 Dinner 
 
 Tomato Soup 
 Butter Yi oz 
 
 Flour Ys 
 
 Tomatoes 4 
 
 /8 
 
 Crackers 
 
 Beefsteak 6 
 
 Potatoes 4 
 
 Letture with Oil 
 Dressing 
 Lettuce i 1 
 Oil K 
 
 Bread i 
 
 Butter Ji 
 
 Strawberries 4 
 Cream i 
 
 Sugar 1% 
 
NOTES ON THE OLEST/ONS ig^ 
 
 Percentage Composition and Weight of Nutrients of Food Consumed 
 
 ^ o 
 
 3 -Q 
 
 c *j 
 
 v as 
 " tic 
 
 3 
 
 o 
 
 Oatmeal 
 
 Cream 
 
 Orange 
 
 Bread 
 
 Butter..... .. 
 
 Potato 
 
 Milk 
 
 Flour 
 
 Cold Beef.. . 
 Chocolate.. . . 
 
 Sugar 
 
 Tomato 
 
 Crackers 
 
 Beefsteak . . . 
 
 Lettuce 
 
 Oil 
 
 Strawberries, 
 
 i6 7 
 
 2 S 
 
 .fa 
 
 II. 9 
 i.o 
 .V6 
 3-3 
 7 9 
 
 22.3 
 
 12 9 
 
 Q 
 
 9.8 
 
 23 9 
 
 0835 
 
 075 
 
 018 
 
 595 
 
 013 
 
 216 
 
 231 
 
 020 
 446 
 
 043 
 
 036 
 012 
 434 
 001 
 
 036 
 
 3 268 
 
 331 
 135 
 255 
 575 
 
 344 
 
 286 
 
 101 
 
 000 
 156 
 091 
 
 025 
 
 ^3 
 
 18.5 
 
 4 5 
 
 48,7 
 
 91 
 
 .0^,65 
 •S55 
 • 003 
 .015 
 i.ifaS 
 .270 
 .280 
 .005 
 •572 
 .162 
 
 .016 
 .011 
 .612 
 .002 
 .250 
 .024 
 
 8.929 
 
 3.981 
 
 Total Amount of Food Consumed During the Day 
 
 Protfid C.\rbohydrate F.at 
 
 3 268 ounces 8.929 ounces 3 981 ounces 
 
 or or or 
 
 92.6i5grams 253.019 grams 112. 821 grams 
 
 There are 28.34 grams (28,'/^) in an ounce. 
 
 Fuel and Energy Value of Food Consumed 
 
 Calories 
 
 92.615 grams proteid X 4.1= 379-7 
 
 253.019 grams carbohydrate X 4.1 = 1.037.3 
 
 114.821 grams fat X 9.3 = 1,049.0 
 
 Total 2,4fa&.o 
 
 Of course this involves a great deal of calculation, 
 and no one would think of undertaking so much extra 
 work often. As stated on page 60, the chief value 
 of calculating a few dietaries is in giving a definit-^ 
 
194 FOOD AND DIETETICS 
 
 idea of the composition of food. It is not expected 
 or necessary that each day's ration should conform 
 to any standard. It is only when the diet is calcu- 
 lated for a considerable period of time that it l)e- 
 comes of much use for comparison. 
 
 The method of studying the diet for a month is 
 described on page 59. When this is done, there is 
 in reality less calculation involved, for then the 
 figures are based on the amount of raw materials 
 used and the composition of each individual dish 
 need not be calculated. That is, the total weight 
 of flour, butter, milk, eggs, and sugar is known and 
 there only remains the allowance to be made for 
 waste. 
 
 The whole sul)ject of standard dietaries is in a 
 somewhat chaotic state at present. Professor Chit- 
 tenden's experiments have shown that it is possible 
 to maintain health and strength on about half the 
 amount of proteid recommended in the standard 
 dietaries. If Dr. Folin's theory is correct (see fol- 
 lowing article), any ordinary diet contains more than 
 sufificient proteid for the physiological needs of the 
 body. Nearly all dietetians agree that, from the phy- 
 siological standpoint, it is immaterial whether the 
 body obtains its supply of heat and energy from fats, 
 carbohydrates, or proteid s. 
 
 But all this does not mean that a proper balance 
 between the food materials is not necessary for health. 
 Digestibility, bulk, personal taste and habit must 
 
XOTES ON THE QUESTIONS 195 
 
 be considered. The problem, then, of the balanced 
 ration becomes an individual one, to be solved ac- 
 cording to the conditions and experience of each 
 individual person. To make the best selection of 
 foods it is necessary to know as much as possible 
 about the composition of all ordinary foods. Then 
 proper cooking and serving and especially the man- 
 ner of eating and the amount eaten are fully as 
 important as the composition. So there is no royal 
 road to the selection of a best diet, but experience 
 based on knowledge should give good judgment. — 
 M. Le Bosquet. 
 
NEW METHODS IN DIET CALCULATIONS 
 
 THE ordinary method of figuring dietaries, using the 
 tables of food by percentage composition, involves 
 much tedious figuring so that such dietaries are very 
 seldom calculated in practice. Although there is no settled 
 "best diet" for human beings applicable to all conditions 
 a scientific diet cannot be planned unless it is known 
 definitely what people eat. 
 
 In one of the Bulletins of the School, Professor Irving 
 Fisher's article "A Graphic. Method in Practical Dietetics" 
 was reviewed. The number of the Journal of the American 
 Medical Association April 20, 1907, and the reprint of the 
 article, both are exhausted. As his method of calculating 
 food values is very valuable we are republishing in this 
 Supplement the tables given in the original article. 
 
 Dr. Fisher's method of calculation is given in the article 
 as follows : " Two methods have hitherto been used for com- 
 puting proportions of proteids, fats, and carbohydrates. One 
 consists in using the tables of percentages by weight of proteids, 
 fats and carbohydrates; the other, Dr. J. H. Kellogg's, in 
 using a table which gives the number of calories in the form 
 of proteids, fats and carbohydrates per ounce of each kind of 
 food. These may be described, respectively, as the method, 
 of 'weight per cent' and the method of 'calories per ounce.' 
 The method here suggested is different from either, and may 
 be called the method of 'calories per cent.' 
 
 " It takes as its starting point not a unit of weight, but a 
 
 197 
 
igg FOOD AXD DIETETICS 
 
 unit of ]ood value, called a ' standard portion ' of each kind of 
 food. A ' standard portion ' is defined as that amount of food 
 which contains 100 calories, or food units. A table is con- 
 structed which gives the weight in a 'standard portion' of 
 each particular kind of food, and out of the 100 calories con- 
 tained therein the number of calories in the form of proteids, 
 fats and carbohydrates. 
 
 ' ' In order to carry out this method food should be served 
 at the table in ' standard portions, ' or simply multiples thereof. 
 The amount of milk served, instead of being a whole number 
 of ounces should be (for average milk) 4.9 ounces — the 
 amount that contains 100 calories. This 'standard portion' 
 constitutes about two-thirds of an ordinary glass of milk. 
 Of the 100 calories which it contains 19 will be in the form of 
 proteid, 52 in fat, and 29 in carbohydrates. In other words, 
 of the food value of milk, 19 per cent is proteid, 52 per cent 
 fat, and 29 per cent carbohydrates. 
 
 " One advantage of this method is apparent at once. It 
 enables us to make a true comparison between different foods 
 as to the relative amounts of proteids, fat and carbohydrate. 
 The other methods are misleading in this regard. For in- 
 stance, though it is well recognized that milk is a higher pro- 
 teid food than pecan nuts, yet, if we compare milk and the 
 pecans on the basis of the method of weight per cent, we shall 
 find that the pecans appear three times as z'ich in proteid, 
 milk containing 3.3 per cent and pecans 11 per cent. But 
 if we compare them on the basis of calories per cent w^e find 
 that, while milk contains 19 calories of proteid out of each 
 100 of total calories, pecans contain only 6, milk showing 
 three times as much proteid as pecans. * * * 
 
 Moreover by having the composition of foods in food 
 
DIET CALCULATIONS I99 
 
 units (calories) the fats are on the same basis as the proteids 
 and carbohydrates. This is not the case in composition by 
 weight, for one ounce of fat in the body produces 264 calories 
 of heat and energy, while one ounce of carbohydrate or pro-, 
 teid produces only 116 calories. Or in grams, one gram fat 
 gives 9.3 calories, one gram carbohydrate or proteid 4.1 
 calories. (A calorie is approximately the amount of heat 
 required to raise the temperature of 1 pound of water, 4° F.) 
 
 THE GRAPHIC METHOD 
 
 " Different foods contain the three food elements, proteids, 
 fats and carbohydrates, in different proportions. The tri- 
 partite constitution of any particular food is represented in 
 the present method by the position of a point in the triangle 
 CPF (Fig. 1). The method of locating the point on the tri- 
 angle is analogous to that of locating a city on a map by lati- 
 tude and longitude; the per cent of proteid in the food is 
 represented, like latitude, l)y the height of the point above 
 the base line CF (the total height, CP, being taken as 100 
 per cent). The percentage of fat is represented like longi- 
 tude, by the distance of the point horizontally from the verti- 
 cal line CP (the total horizontal breadth, CF, being taken as 
 100 per cent). Thus, the point 0, representing milk, is lo- 
 cated at a height above CF ('latitude') 19 per cent of the total 
 height of the triangle, which signifies that 19 per cent of the 
 food value of milk is proteid; and at a distance to the right 
 of CP C longitude ') 52 per cent of the total breadth of the 
 triangle, which signifies that 52 per cent of the food value of 
 milk is fat. Foods high in proteid will be represented by 
 points high up in the triangle. White of egg, of which the 
 food value is all proteid, v/ill be represented at the point P, 
 representing 100 per cent. P is, therefore, called the 'pro- 
 
200 
 
 FOOD AND DIETETICS 
 
 teid corner' of the triangle. Foods rich in fats, as nuts, 
 cream, and butter, are represented by points far to the right. 
 Pure fats, like olive oil, are located at F at the extreme right, 
 representing 100 per cent of fat. F is therefore called the 
 ' fat corner. ' 
 
 "The point representing a food is completely located by 
 means of the percentage of proteid and fat; no attention 
 
 10 20 30 40 50 60 70 80 90 100 
 
 Fig. 1 " Food Map." Composition of Milk Rep- 
 resented by Position of Point O. 
 
 need be paid to the carbohydrate. If one desires a graphic 
 representation of carbohydrates it is found in the distance 
 of the point O from the third side of the triangle, FP *,the 
 total distance of this side from the opposite corner being 
 taken as 100 per cent). Foods like bread, cereals and fruits, 
 which arc mostly carjjohydrate, will thus be represented l)y 
 points far away from the side FP. Foods such as sugar, of 
 ■which the food value is wholly carbohydrate, will Ije repre- 
 
\.<^*' ^'' flt^^ and Cereals 
 
 Ootrmal BnltJ fi " 
 
 flour (Graham Jfc — ^ ^ 
 iSraniard fradf 37 
 
 s,a^,ni S7 ~ 
 
 Vllil-e Brrmit /J - ■ 
 Ctrn Hants 97 , -^ 
 
 »\ ''^ x^ ■ ' 
 
 W*/v <f £ j,3 t.y 
 
 Dainj Products . f (j<j?, and 
 Heat Subatllutes. 
 
 .<t 
 
 Glutrn Gruti 7 J 
 
 5Kimmrd MilK 9 ^ 
 
 Bi/trfrmiiH 97- - - 
 
 
 /SJ' /A 
 
 
 Figs. 2 and 3, "FOOD MAPS" 
 
 201 
 
Ve<)ttal)lfes 
 
 
 CaMage //~. 
 
 Celerif /3 - _ ^ 
 string Beam ,^\. 
 Lima Beans j/sX 
 
 fgq Cianr u^^ 
 Rad,sl7e5/7S -^ I 
 
 Onions(fresi!j — 
 Corntgrvfn' \ — - 
 
 1^ v5- 
 
 ffat.hrs , , 
 
 
 
 Figs. 4 and 5, "FOOD MAPS" 
 
 202 
 
Conitifme Muf *»- 
 
 Clam C/tonder sif - ' 
 Hitrd PicKlei i^b' 
 
 Pudd in()s , Pus, Paslnes.Surttts 
 
 
 Honey I Of . 
 AJolassei Cane 1 2, 
 Tapioco dM- ' 
 Tapioco Applet JSV 
 B-une Marmalade 22 ,~ 
 Granulated iuqar I 
 Maple su^jr I.Z- 
 
 
 g 5 -^ 
 5 ;«: <a 
 
 ^ ^ 
 
 ?«: 
 
 2 2^ S^ 
 
 ji vj ^ c s 
 
 ^S o ^ c^ eg § <5 (^ t§ 
 Figs. 6 and 7. "FOOD MAPS 
 
 203 
 
204 FOOD AND DIETETICS 
 
 sented at the remotest point C, representing 100 per cent 
 carl)ohy(lrate, which is, therefore, called the ' carl^ohydrate 
 corner.' 
 
 " Any food is thus represented on the ' food map ' by a point, 
 the relative distances of which from the three sides of the 
 triangle represent the proteid, fat and carbohydrate. On 
 this food map, fatty foods are represented by points near 
 the fat corner, F; starchy and saccharine foods by points near 
 the carbohydrate corner, C, and proteid foods by points near 
 the proteid corner, P. A food devoid of proteid is evidently 
 located on the base line C; a food devoid of fat, on the side 
 CP, and a food devoid of carbohydrate on FP. The chief 
 classes are represented in the accompanying^ diagrams, flesh 
 foods and cereals being shown in Figure 2; dairy products, 
 eggs and meat substitutes in Figure 3; vegetables in Figure 
 4; nuts and fruits in Figure 5; soups, salads and relishes in Fig- 
 ure 6, and puddings, pies, pastries and sweets in Figure 7. 
 In each case the position of the point relatively to the sides 
 of the triangle represents the proportions of the proteids, fats, 
 and car])ohydrates, and the number opposite each name rep- 
 resents the weight (in ounces) of a 'standard portion.' * * * 
 
 COMBINATIONS 
 
 "The combination of two foods equal in calories is rep- 
 resented by a point midway between them. Thus, to com- 
 bine one ' portion ' of bread and one ' portion' of butter (Fig. 9) 
 draw a straight line between their points and at the middle 
 of it mark a cross and label it ' 2 ' ; this point will represent 
 two 'portions' of bread and butter. 
 
 " If the calories of the two foods are unequal, the point 
 representing the combination will be proportionately nearer 
 
DIET CALCULATIONS 
 
 20 5 
 
 the point with the larger number. Thus, if one portion of 
 bread is combined with one-half portion of butter, the bread 
 and butter point will be midway between the points for bread 
 and for butter, but will lie twice as near the bread point as the 
 butter point. 
 
 " When three foods are combined, the point representing 
 the coml>ination is, in like manner, the ' center of gravity ' of 
 
 ^B utter 
 
 10 20 30 40 50 60 70 80 90 100 p 
 
 Fig. 9. Food Map Showing Combination of one "Por- 
 tion" of Bread and one "Portion" of Butter. 
 
 the three, and may be found by first obtaining the center of 
 gravity of two, and then obtaining the center of gravity of 
 the point thus obtained, and the third. Thus if, as in Fig. 10, 
 we have three points representing respectively, 3, 4 and 5 
 calories of three separate foods, shown by the attached num- 
 bers 3, 4 and 5, the point representing the combination may 
 be found by joining the points labeled 3 and 4, and finding 
 their center of gravity 7, situated nearer the point 4 than point 
 
2o6 
 
 FOOD AND DIETETICS 
 
 3, and dividing the line between them in the ratio of 3 to 4. 
 The first two points, 3 and 4, may be considered as concen- 
 trated at 7 with their combined weight, 7. We then find the 
 center of gravity of this new point 7 and the remaining point, 5. 
 The center of gravity at this point 7 and point 5 will be a 
 point 12, on the straight line between them, situated nearer 
 the 7 than the 5, and dividing the distance between in the 
 
 10 20 30 40 50 60 70 80 90 100 
 
 Fig. 10. Showing Method of Combining Three 
 or More Foods. 
 
 ratio of 5 to 7. At point 12 the whole combination of 12 
 portions may be considered to be concentrated. It is evi- 
 dent that we could find the center of gravity of the same three 
 points by combining them in a different order, but the result 
 would be the same. 
 
 " It is evident that more than three points may be com- 
 bined on the same principles by combining them by twos and 
 threes and then combining the combinations. * * * * 
 
f 
 
 DIET CALCULATIONS 
 
 207 
 
 "If we accept Professor Chittenden's results as to proteid 
 requirements, a well balanced daily ration for the average 
 person will be represented by a point lying within the ' normal 
 rectangle/ as shown in Fig. 11. This shows that proteid 
 should be near 10 per cent. * * * * 
 
 "Since the resultant point, representing the ration, is the 
 center of gravity of the points representing its constituents. 
 
 10 20 30 40 50 60 .70 80 90 100 
 
 Fig. 11. Food Map with "Normal Rectangle," 
 Chittenden's Standard, of Well Balanced Ration. 
 
 it is evident it can be obtained by mechanical as well as by 
 geometrical methods. For this purpose a mechanical diet 
 indicator has been devised, as shown in Fig. 12. 
 
 " The essential feature of this apparatus is a card on which 
 is drawn the right-angled triangle with which we have already 
 become familiar. Points on this card may be located to 
 represent the various foods employed. These points may be 
 easily found from table given at the end of this article. . . . 
 
2o8 FOOD AND DIETETICS 
 
 At points representing foods eaten, pins with heav}' heads 
 are thrust through the cardboard, the weight of each repre- 
 senting one 'standard portion.' Similar pins but one-half 
 and one-quarter as heavy are also provided to represent half 
 
 Fig. 12. Mechanical Diet Indicator. 
 
 and quarter ' portions. ' When these pins are placed the 
 total ration which has been consumed is easily found, simply 
 by counting the ' portions' thus represented. In order to find 
 the pi'ecentages of proteid, fat and carbohydrate in this 
 rations it is only necessary to obtain the center of gravity 
 of all the pins. For this purpose the card is placed in a basket 
 
DIET CALCULATIONS 209 
 
 and suspendetl on a standard so that the center of gravity is 
 easily indicated on the card l)y means of a vertical pricker, 
 which may be pressed on the card. Thus, almost instan- 
 taneously, the center of gravity is found. The total time 
 consumed in placing the pins, adjusting the card and basket, 
 and finding the center of gravity, is found to be, for accurate 
 work, about five minutes." 
 
 Professor Fisher's mechanical diet indicator is now manu- 
 factured and may be obtained through the Purchasing De- 
 partment of this School for $25.00, express collect. 
 
 Further details are given in the original article, reprint of 
 which will be loaned to Mernbers of the School for Ic. postage. 
 
 Aside from the "food map" and the diet indicator, the 
 table will' repay careful study in making clear the real com- 
 position of foods as eaten. 
 
 The proportion of proteids given in the table for some of the 
 foods is not absolutely correct, as proteid-like substances like 
 gelatin and also the so-called ''extractives," the latter having 
 no food value, are calculated as proteids. The error is not seri- 
 ous, for the proportion of such substances is usually very small. 
 
 The table is particularly valua])le in showing equivalent 
 total food values. After weighing out a few "portions" of 
 various foods it is very easy to tell by the eye the amount of 
 food being served and so obtain a fairly accurate idea of the 
 total food value of one's diet. An ordinary postal scale will 
 serve for weighing. 
 
 An educated appetite is the best guide for diet in health. 
 In a diet for an invalid, foods may easily be served in " stand- 
 ard portions" or multiplies or fractions thereof, so that a 
 {physician's prescription as to food may be followed. It would, 
 of course, be necessary to deduct food served but not eaten. 
 
210 
 
 FOOD AND DIETETICS 
 
 If it is desired to add further items to the table, the weight 
 of a "standard portion" and the calories per cent is found 
 from the percentage composition given in the Department of 
 Agriculture Bulletin No. 28, Chemical Composition of Ameri- 
 
 C lasses of Foods 
 
 Jam ■\ 
 
 ./iarmaladesj — 
 
 can Food Materials,* as follows: The weight in ounces of a 
 " standard portion " is found by dividing 1,600 by the number 
 of calories per pound given in the table. 
 
 The '' calories per cent" of proteid is found by multiplying 
 the percentage of proteid in the Bulletin table by 1,860 and 
 dividing the result by the figure giving the numbers of 
 calories per pound. The same calculation and the same factor 
 1,860 applies to carbohydrates. For fat the same calculation 
 applies, but with the substitution of the factor 4,220 in place 
 of 1,860. The three results may be verified by adding the 
 resulting figures for proteid, fat and carbohydi-ate, the sum 
 of which should be 100 per cent. 
 
 * For this Bulletin send 5 cents (coin) to the Supt. of Dotuments, Washing- 
 ton, D. C. 
 
TABLE OF 100 FOOD UNITS 
 
 Name of Foocl 
 
 •' Portion " Con- 
 taining 100 Food 
 Units (approx.) 
 
 Per cent of 
 
 COOKED MEATS 
 
 tBeef.r-nd. boiled (fat) 1099t f ^^^^ fj;:!"„| . ; It 
 
 tBeef, r'd, boiled Oea..) 1 2061: Large ser g ^^ 
 
 tBeef, rVl. bo.le.l (med.) Il88t ^"^f/' J^[. , ^^ . . 18.5 
 
 tBeef, 5th nb, roasted, 5.58t "^'^ffgr^-i^g . . 32 
 
 JBeef, 5th rib, roas ed, 6 6t %^^f ^^^2^^%' g 25 
 
 tBeef, 5th rib, roasted, Ibloj. A^"^?^^, vins . . 30 
 
 iBeef, ribs boiled 69t ^^^^^ Z^n s'v'g 25 
 
 •/Beef, ribs boiled, U a)f '•^ y jj2 
 
 ♦Calves foot jelly j--^ ^hin slioe.. . 27 
 
 *Chicken, canned^ ._...■ Y,' „ ^op 27 
 
 *Lamb chops, boiled, av ^Jne s™ 50 
 
 *Lamb, leg, roasted . ■■■ Ylr'J%er\k>g . . 34 
 
 tMutton, leg, bmled 1184^ Large serv g ^o . 5 
 
 tPork, ham, bo. ed (fat) 11 - n bmall ser^ng ^^ . 5 
 
 tPork, ham, bo'lejl. 192t ^ Si serving . . 27 
 
 ?o^th\C,';st-d',(ffi;i5ul i-}}-->|:; 11 
 
 klt^^^^^:nS^t■■■■ Sefervinl.. 67.5 
 UNCOOKED MEATS, EDIBLE 
 
 *Beef, loin, av (lean) ^J^^airserving . ^ to 
 
 *Beef. loin, av. (fat). . ■ ... ■ Sma ser^mg 
 
 *Beef , loin, p'house steak, av.. fema steaK ... 
 
 *Beef loin, sirloin steak, av. Small steak^ ^^ 
 
 *Beef, ribs, lean, av grd. |ej% mg ^.^ 
 
 *Beef, round, lean, av Ord. ser^ ng ^^ 
 
 *Beef, tongue, average Urd. servmg ^^^ 
 
 *Beef, juice. ...■■■ iWrWe serving . . 90 
 
 *Chicken (broilers), av Twelve to 16 . . 210 
 
 *Clams, r'nd m shell, av ^ wel^l.t^^^gs . . . 138 
 
 *Cod, whole. . „ ,f serving ... 25 
 
 *Goose (young) av Ha f serv mg ^^ 
 
 :Halibut steaks av O i^ ^^^^,j f,^,,^ 79 
 
 *Liver (veal) av.. servings. . . 117 
 
 ♦Lobster, whole, av. . . . ... ■ i^,' „; ; ^ 57 
 
 ♦Mackerel (Span.), whole av. Ord. se^^ ng ^^ 
 
 ♦Muttonleg, hind, lean, av.... ^^-^^.'^^"^ . . . 193 
 
 ♦Oysters., in shell, av Verv small s' v'g 27 
 
 ♦Pork, loin chops, av Small serving . 36 
 
 ♦Pork, ham, lean. av. .•■■••■■ °"^^ ||j; "^ • . 15 
 
 ♦Pork, bacon, med. fat, av. . . . Sma serv ng ^^ 
 
 ♦Salmon (Cal.), average o?d serv , g . 60 
 
 Shad, whole, average Ord |er^,V f „ ^^^ 
 
 ♦Trout, brook «^.ole. av Twc smal, ^,^ g ^.^ 
 
 13 
 
 40 60 
 
 00 
 
 2 2 
 
 90 10 
 
 00 
 
 1 6 
 
 60 40 
 
 00 
 
 65 
 
 12 88 
 
 00 
 
 1 2 
 
 25 75 
 
 00 
 
 .88 
 
 18 82 
 
 00 
 
 1 1 
 
 27 73 
 
 00 
 
 .87 
 
 21 79 
 
 00 
 
 4 
 
 19 00 
 
 81 
 
 96 
 
 23 77 
 
 00 
 
 96 
 
 24 76 
 
 00 
 
 1 8 
 
 40 60 
 
 00 
 
 1 2 
 
 35 65 
 
 00 
 
 73 
 
 14 86 
 
 00 
 
 1 1 1 
 
 28 72 
 
 00 
 
 .96 
 
 19 81 
 
 00 
 
 1 2 
 
 33 67 
 
 00 
 
 99 
 
 23 77 
 
 00 
 
 ; 2.4 
 
 73 27 
 
 00 
 
 PORTION 
 
 
 1 8 
 
 40 60 
 
 00 
 
 1 1 
 
 22 78 
 
 00 
 
 1 3 
 
 32 68 
 
 00 
 
 1.4- 
 
 31 69 
 
 00 
 
 1 8 
 
 42 58 
 
 00 
 
 2 2 
 
 54 46 
 
 00 
 
 2 2 
 
 47 53 
 
 00 
 
 14. 
 
 78 22 
 
 00 
 
 3.2 
 
 79 21 
 
 00 
 
 7 4 
 
 56 8 
 
 36 
 
 4.9 
 
 95 5 
 
 00 
 
 88 
 
 16 84 
 
 00 
 
 2 8 
 
 61 39 
 
 00 
 
 2 8 
 
 61 39 
 
 00 
 
 4 1 
 
 78 20 
 
 2 
 
 2 
 
 50 50 
 
 00 
 
 1 8 
 
 41 59 
 
 00 
 
 6 8 
 
 49 22 
 
 29 
 
 97 
 
 18 82 
 
 00 
 
 1 3 
 
 29 71 
 
 00 
 
 53 
 
 6 94 
 
 00 
 
 1 5 
 
 30 70 
 
 00 
 
 2 1 
 
 46 54 
 
 00 
 
 % 6 
 
 SO 20 
 
 00 
 
 XM 
 
 i9 l>^ 
 
 )U 
 
" Portion" Con- 
 Name of Food taining 100 Food 
 
 Units (approx.) 
 
 Wt.oflOO „ ^ . 
 
 Calories Per cent of 
 
 C3 
 
 VEGETABLES 
 
 ♦Artichokes, av. canned 430 15 14 86 
 
 *Asparagus, av. canned 540 19 33 5 62 
 
 ♦Asparagus, av. cooked 206 7 10 18 63 19 
 
 *Beans, baked, canned Small side disli.. 75 2 66 21 18 61 
 
 *Beans, Lima, canned Large side dish. 126 4.44 21 4 75 
 
 *Beans, string, cooked Five servings. . . 480 16.66 15 48 37 
 
 *Beets e<lible portion, cooked. Three servings . 245 8.7 2 23 75 
 
 ♦Cabbage, edible portion 310 11 20 8 72 
 
 ♦Carrots, edible pt., fresh 215 7.6 10 8 82 
 
 Carrots, cooked Two servings. .164 5.81 10 34 56 
 
 ♦Cauliflower, as purchased 312 11 23 15 62 
 
 ♦Celery, edible portion 540 19 24 5 71 
 
 Corn, sweet, cooked One side dish . . 99 3.5 13 10 77 
 
 ♦Cucumbers, edible pt 565 20 18 10 72 
 
 ♦Egg plant, edible pt 350 12 17 "10 73 
 
 Lentils, cooked 89 3.15 27 1 72 
 
 ♦Lettuce, edible pt 505 18 25 14 61 
 
 ♦Mushrooms, as purchased 215 7.6 31 8 61 
 
 ♦Onions, fresh, edible pt 200 7.1 13 5 82 
 
 ♦Onions, cooked Two large s'v'gs 240 8.4 12 40 48 
 
 ♦Parsnips, edible pt 1 J4 serving. .. . 152 5.3 10 7 83 
 
 Parsnips, cooked 163 5.84 10 34 56 
 
 ♦Peas, green, canned Two servings. . . 178 6.3 25 3 72 
 
 ♦Peas, green, cooked One serving . 85 3 23 27 50 
 
 Potatoes, baked One good sized .86 3 Oo 11 1 88 
 
 ♦Potatoes, boiled One large sized. 102 3 62 11 1 88 
 
 ♦Potatoes, mashed (creamed). One serving. .. . 89 3.14 10 25 65 
 
 Potatoes, steamed One serving. .. . 101 3.57 11 1 88 
 
 ♦Potatoes, chips One-half s'v'g. . 17 .6 4 63 33 
 
 ♦Potatoes, sweet, cooked Half av. potato. 49 1.7 6 9 85 
 
 ♦Pumkpins, edible pt. .380 13 15 4 81 
 
 Radishes, as purchased 4S0 17 18 3 79 
 
 Rhubarb, edible, pt 430 15 10 27 63 
 
 ♦Spinach, cooked -. Two ord. s'v'g. 174 6 1 15 66 19 
 
 Squash, edible pt 210 7.4 12 10 78 
 
 ♦Succotash, eaimed Ord. serving . . 100 3.5 15 9 67 
 
 ♦Tomatoes, fresh as purchased Four av 430 15 15 16 69 
 
 Tomatoes, canned 431 15.2 21 7 72 
 
 ♦Turnips, edible pt Two large s'v'g 246 8.7 13 4 83 
 
 Vegetable oysters 273 9 . 62 10 51 39 
 
 FRUITS (DRIED) 
 
 ♦Apples, as purchased 34 1.2 3 7 90 
 
 Apricots, as purchased 35 1 .24 7 3 90 
 
 ♦Dates, edible portion Three large. . .. 28 .99 2 7 91 
 
 ♦Dates, as purchased 31 1.1 2 i 91 
 
 ♦Figs, edible portion One large 31 1.1 5 95 
 
 ♦Prunes, edible porlicn Three large.. . . 32 1.14 3 97 
 
 ♦Prunes, as purchasoil 38 l.,35 3 97 
 
 ♦Raisins, edible portion 28 1. 3 9 88 
 
 *Raiain3, JV? piircljased 31 1.1 3 9 §§ 
 
 •>19 
 
Name of Food 
 
 " Portion " Con- 
 taining 100 Food 
 Units (approx.) 
 
 Wt. of 100 
 Calories 
 
 Per cent of 
 
 FRUITS (FRESH OR COOKED) 
 
 ♦Apples, as purchased Two apples. . . . 206 
 
 Apples, baked 94 
 
 Apples, sauce Ord. serving. . . Ill 
 
 ♦Apricots, edible pt 168 
 
 Apricots, cooked Large serving. . 131 
 
 ♦Bananas, edible pt One large 100 
 
 ♦Blackberries 170 
 
 Blueberries 128 
 
 ♦Blueberries, canned 165 
 
 Cantaloupe. Half or. serv'g . 243 
 
 ♦Cherries, edible portion 124 
 
 ♦Cranberries, as piirch;ised ;....-. 210 
 
 ♦(irapes, a,s purchasetl av 136 
 
 (irape fruit 215 
 
 Grape juice Small glass 120 
 
 Gooseberrries 261 
 
 ^Lemons. 215 
 
 Lemon .juice 246 
 
 Nectarines 147 
 
 Olives, ripe .\bout seven ... 37 
 
 Oranges, as purchased, av.... One very large. 270 
 
 Oranges, juice Large glass. . . . 188 
 
 Peaches, as purchased av. . . . Three ordinary . 290 
 
 Peaches, sauce Ord. serving. . . 136 
 
 Peaches, juice Ordinary glass . 136 
 
 Pears One large pear. 173 
 
 ♦Pears, sauce 113 
 
 Pineapples, edible p't'n, av 226 
 
 *Raspberries, black 146 
 
 Raspberries, red 1 78 
 
 Strawberries, av Two servings. . . 260 
 
 ♦Watermelon, av 760 
 
 7.3 
 3.3 
 3.9 
 5.92 
 4.61 
 3 5 
 5.9 
 4.6 
 5.8 
 $.6 
 4.4 
 7.5 
 4.8 
 7.57 
 4.2 
 9.2 
 7.57 
 77 
 18 
 31 
 4 
 62 
 
 5.18 
 6.29 
 9.1 
 27. 
 
 
 5 
 9 
 
 4 
 2 
 
 6 
 
 7 
 4 
 
 4 
 3 
 4 
 
 10 
 8 
 
 10 
 6 
 
 7 
 5 
 5 
 
 
 5 
 16 
 
 
 
 10 
 
 12 
 
 15 
 
 4 
 
 
 
 
 
 14 
 
 
 
 
 
 91 
 
 3 
 
 
 
 2 
 
 2 
 
 
 
 7 
 
 4 
 
 6 
 
 14 
 
 
 
 15 
 
 90 
 93 
 93 
 92 
 94 
 90 
 75 
 89 
 87 
 94 
 85 
 85 
 80 
 89 
 
 100 
 95 
 77 
 
 100 
 
 96 
 
 7 
 
 91 
 
 100 
 91 
 94 
 
 100 
 89 
 93 
 90 
 76 
 92 
 75 
 
 DAIRY PRODUCTS 
 
 ♦Butter. . Ordinary pat. . 
 
 ♦Buttermilk IK-o glass 
 
 ♦Cheese, Am., pale 1 J^ cubic in. . . 
 
 ♦Cheese, cottage 4 cubic in. . . 
 
 ♦Cheese, full cream l}4 cubic in. . . 
 
 ♦Cheese, Neufchatel 1 }^ cubic in. . . 
 
 ♦Cheese, Swiss 1 H cubic in. . . 
 
 ♦Cheese, pineapple 114 cubic in. . . 
 
 ♦Cream M ord. glass . 
 
 Kumyss 
 
 ♦Milk, condensed, sweetened 
 
 ♦Milk, condensed, unsweet'd . 
 
 ♦Milk, skimmed 1 '<; glass 255 
 
 ♦Milk, whole Small glass 140 
 
 Milk. Iiuman, 2nd week 162 
 
 .Milk, human, 3rd month 171 
 
 *W!iey Two glasses. . . . 3G0 
 
 213 
 
Name of Food 
 
 " Portion " Con- 
 taining 100 Food 
 Units (ai)prox.) 
 
 VVt. of 100 
 Calories 
 
 O 
 
 Per cent of 
 
 V 
 O 09 
 
 OS (S >. 
 
 CAKES, PASTRY, PUDDINGS AND DESSERTS 
 
 ♦Cake, chocolate layer Half ord. sq. pc 28 
 
 *Cake, gingerbread Half ord. sq. pc 27 
 
 Cake, sponge Small piece .... 25 
 
 Custard, caramel 71 
 
 Custard, milk Ordinary cup . . 122 
 
 Custard, tapioca Two-thirds ord. 69 
 
 *Doughnuts Half a doughn't 2.3 
 
 *Lady fingers Two 27 
 
 ♦Macaroons Four 2'.i 
 
 *Pie. apple One third piece 38 
 
 *Pie, cream One-fourth pc. . 30 
 
 *Pie, custard One-third piece 55 
 
 *Pie, lemon One-third piece 38 
 
 *Pie, mince One-fourth pc. . 35 
 
 *Pie, squash One-third piece 55 
 
 Pudding, apple sago 81 
 
 Pudding, brown betty Half ord. s'v'g . 56 
 
 Pudding, cream rice Very small s'v'g 75 
 
 Pudding, Indian meal Half ord. ser'g. . 56 
 
 Pudding, apple tapioca Small serving . . 79 
 
 Tapioca, cooked Ord. serving ... 108 
 
 7 
 
 6 
 
 7 
 
 19 
 
 26 
 
 9 
 
 6 
 
 10 
 
 6 
 
 5 
 
 5 
 
 9 
 
 6 
 
 8 
 
 9 10 
 
 02 6 
 7 
 
 65 8 
 12 
 
 8 1 
 1 
 
 3.85 
 
 22 
 23 
 25 
 10 
 56 
 12 
 45 
 12 
 33 
 32 
 32 
 32 
 36 
 38 
 42 
 3 
 12 
 13 
 25 
 1 
 1 
 
 71 
 71 
 68 
 71 
 18 
 79 
 49 
 78 
 61 
 63 
 63 
 59 
 58 
 54 
 48 
 91 
 81 
 79 
 63 
 98 
 98 
 
 SWEETS AND PICKLES 
 
 ♦Catsup, tomato, av 170 
 
 Candy, plain 2() 
 
 Candy, chocolate 30 
 
 ♦Honey Four teasp'ns. . 30 
 
 ♦Marmalade (orange) 28 . 3 
 
 ♦Molasses, cane 35 
 
 ♦Olives, green edible portion . .Five to seven. . 32 
 
 ♦Olives, ripe, edible portion . . .Five to seven. . 38 
 
 ♦Pickles, mixed 415 
 
 ♦Sugar, granulated Three heaping tsp 
 
 or 1 ' 2 hmips. 24 
 
 ♦Sugar, maple Four teaspoons 29 
 
 ♦Syrup, maple Four teaspoons 35 
 
 9 
 
 1 
 
 .05 
 
 1 
 1 
 1 
 
 1.2 
 
 1.1 
 
 1 .3 
 
 14.6 
 
 .86 
 1.03 
 1.2 
 
 .5 2.5 
 
 .5 
 
 84 
 
 2 91 
 
 18 15 
 
 1 
 
 87 
 100 
 95 
 99 
 97 
 99. 
 15 
 7 
 67 
 
 100 
 100 
 100 
 
 NUTS, EDIBLE PORTION 
 
 ♦Almonds, av Eight to 15 15 .53 13 77 10 
 
 ♦Beechnuts 14.8 .52 13 79 8 
 
 ♦Brazil Nuts, Three ord. size. 14 .49 10 86 4 
 
 ♦Butternuts 14 .50 16 82 2 
 
 ♦Cocoanuts 16 .57 4 77 19 
 
 ♦Chestnuts, fresh, av 40 1.4 10 20 70 
 
 ♦Filberts, av Ten nuts 14 .48 9 84 7 
 
 ♦Hickory nuts 13 .47 9 85 6 
 
 ♦Peanuts, av Thirteen double 18 .62 20 63 17 
 
 ♦Pecans, polished .About eight. ... 13 46 6 S7 7 
 
 ♦Pine nut.-i, (pignolias) About eighty. . . 16 .50 22 74 4 
 
 *Walnuts, Californm About six H .48 lU 83 7 
 
 m 
 
Name of Food 
 
 " Portion " Con- 
 taining 100 Food 
 Units (approx.) 
 
 Wt. of 100 
 Calories 
 
 Per cent of 
 
 CEREALS 
 
 *Bread, brown, average 
 
 ♦Bread, corn (johnnycake) av. . 
 
 ♦Bread, white, home made. . . 
 
 *Cookie.<, sugar 
 
 Corn flakes, toasted 
 
 *Corn meal, granular, av 
 
 Corn meal, unbolted, av 
 
 ♦Crackers, graham 
 
 ♦Crackers, oatmeal 
 
 ♦Crackers, soda 
 
 ♦Hominy, cooked 
 
 ♦Macaroni, av 
 
 ♦Macaroni, cooked 
 
 ♦Oatmeal, boiled 
 
 ♦Popcorn, 
 
 ♦Rice, uncooked 
 
 ♦Rice, boiled 
 
 ♦Rice, flakes 
 
 ♦Rolls, Vienna, av 
 
 ♦Shredded wheat 
 
 ♦Spaghetti, average 
 
 ♦Wafers, \anilla 
 
 ♦Wheat, flour, e't'e w'h't, av. . 
 
 ♦Wheat, ffour, graham, av. . . . 
 
 ♦Wheat, flour, patent, family 
 and straight grade spring 
 wheat, av 
 
 ♦Zweiback 
 
 Ord. thick slice., 
 Small square. ... 
 Ord. thick slice 
 
 Two 
 
 Ord. cer. disli f'l 
 2 '.2 level tbsp. . 
 
 Three tbsp 
 
 Two crackers. . 
 Two crackers. . 
 3H "Uneedas" 
 Large serving. . 
 
 Ord. serving 
 1 ) 2 serving. 
 
 4:5 
 38 
 38 
 24 
 27 
 27 
 26 
 23 
 23 
 24 
 120 
 27 
 110 
 1.59 
 24 
 28 
 87 
 27 
 35 
 27 
 
 28 
 
 Four 24 
 
 Four tbsp 27 
 
 4M tbsp 27 
 
 Four tbsp 27 
 
 Size of thick slice 
 of bread 23 
 
 Ord. cereal dish 
 Ord. cereal dish. 
 One large roll . . 
 One biscuit. . . . 
 
 1.5 
 
 1.3 
 
 1.3 
 .83 
 .97 
 .96 
 .92 
 .82 
 .81 
 .83 
 
 4.2 
 .96 
 
 3.85 
 
 5.6 
 .86 
 .98 
 
 3.1 
 .94 
 
 1.2 
 .94 
 .97 
 .84 
 .96 
 .96 
 
 .97 
 
 .81 
 
 9 
 12 
 13 
 
 7 
 11 
 10 
 
 9. 
 
 9.5 
 11 
 
 9.4 
 11 
 15 
 14 
 18 
 11 
 
 9 
 10 
 
 8 
 12 
 13 
 12 
 
 8 
 15 
 15 
 
 12 
 9 
 
 1 
 
 5 
 11. 
 20.5 
 24 
 20 
 
 2 
 
 2 
 15 
 
 7 
 11 
 
 1 
 
 1 
 
 1 
 
 7 
 
 4.5 
 
 1 
 13 
 
 84 
 
 72 
 
 81 
 
 71 
 
 88 
 
 85 
 
 80 
 
 70 
 
 65 
 
 70.6 
 
 87 
 
 83 
 
 71 
 
 75 
 
 78 
 
 90 
 
 89 
 
 91 
 
 81 
 
 82.5 
 
 87 
 
 71 
 
 80 
 
 80 
 
 85 
 70 
 
 MISCELLANEOUS 
 
 ♦Eggs, hen's boiled One large egg. . 59 2.1 32 68 00 
 
 ♦Eggs, hen's whites Of six eggs 181 6.4 100 00 
 
 ♦Eggs, hen's yolks Two yolks 27 .94 17 83 00 
 
 ♦Omelet 94 3.3 34 60 6 
 
 ♦Soup, beef, av 380 13. 69 14 17 
 
 ♦Soup, bean, av Very large plate 150 5.4 20 20 60 
 
 ♦Soup, cream of celery Two plates 180 6.3 16 47 37 
 
 ♦Consomme 8.30 29. 85 00 15 
 
 ♦Clam chowder Two plates 230 8.25 17 18 65 
 
 ♦Chocolate, bitter Half-a-square. . . 16 .56 8 72 20 
 
 ♦Cocoa 20 .69 17 53 30 
 
 Ice Cream (Phila) Half serving 45 1.6 5 57 38 
 
 Ice Cream (New York) Half serving ... . 48 1.7 7 47 46 
 
 ♦Chemical Composition of American Food Materials, Atwater and Bryant, U. S. 
 Department of Agriculture Bull. No. 28. 
 
 tExperiments on Losses in Cooking Meats. (1900-03), Grindley, U. S. Depart- 
 ment of Agriculture Bull. No. 141. 
 
 ^Laboratory number of specimen, as per Experinicnta on Losses in (looking Jlestt, 
 
 213 
 
FOOD VALUES IN CALORIES PER OUNCE 
 
 In some respects Dr. Kellogg's method of giving the com- 
 position of foods in food' units (calories) per ounce is simpler 
 and more useful in the actual calculation of dietaries. By 
 having a table with composition in food units, the day's 
 ration may be calculated by simple addition, combined with 
 a little mental multiplication. If the results are wanted in 
 ounces, the calories of proteid or carbohydrate are divitled 
 by 116, and calories of fat by 264. For grams, the factor is 
 4.1 for proteids and carbohydrate and 9.3 for fats. 
 
 Such a table is given in the Battle Creek Sanitarium Diet 
 List which contains the composition of all foods served at 
 that institution in calories per ounce. Dr. Fisher's method 
 of serving the food in "standard portions" has been adopted 
 and the figures by that method of calculation are also given 
 in the last edition of the booklet. 
 
 The Diet List also contains tables giving normal height, 
 weight, skin surface and calories required, on the average, 
 for men and women, boys and girls, per day. Some of these 
 tables are given in the following pages, also the calculation 
 t)f a dietary with the fiuures in calories per ounce and one 
 with food served in 100 calorie portions. 
 
 These tables are based on Professor Chittenden's 
 standards and so are lower in proteid requirements and total 
 food value than the Atwater standard dietaries. For exam- 
 ple, the diet for an average man, 5 feet 8 inches tall and 
 weighing 157 pounds, is given as 236 calorics of proteid, 7()S 
 calories of fat, 1,416 calories of carbohytlruteSj with a totUrl uf 
 2,300 galories per day. 
 
 819 
 
DIET CALCULATION'S 217 
 
 The Atwater standard for man with light exercise is 100 
 grams of proteid, 100 grams of fat, 360 grams of carbohy- 
 drate, or on a calorie basis: 410 calories of proteid, 930 
 calories of fat, 1,476 calories of carbohydrate, total 2,816 
 calories or nearly 20 per cent higher in total food value. 
 
 Under the Chittenden standard, of every 100 food units 
 about 10 should be proteid, 30 fat and 60 carbohydrate. Based 
 on the Atwater standard, of 100 food units, about 14 are 
 proteid, 32 fat, and 52 carl)ohydrate. 
 
 It must be remembered that no one in formulating a " stand- 
 ard diet" attempts to give anything more than a possible 
 average, from which to vary, according to conditions. It is 
 recognized that health may be maintained on various pro- 
 portions of proteid and that the i-atio of fat to carbohydrates 
 is immaterial, provided digestion remains perfect. 
 
 The following table has been taken from some of the figures 
 in the Diet List. The figures based on standard portions are 
 omitted. 
 
 Note — Members of the School are expected hereafter to solve 
 (|uestion No. 21, Part I, Food and Dietetics — "Calculate the amount 
 of proteiu, carbondrate and fat in your own diet for one day," in the 
 usual way, as shown on page 193, and by the " calories per ounce " 
 method, using the following figures. The total calories should be 
 found by each method. The two figures will not come out exactly 
 the same, but should be approximate. 
 
 Also plot one of these meals on the enlarged "Food Map "on 
 page 223. Find the "center of gravity" by the method shown in 
 Figs. 9 and 10. This is most easily done by marking and folding a 
 strip of paper to find halves, thirds, etc. Say what the resulting 
 point represents in terms of calories and of ounces of proteids, fats 
 and carbohytlrates. Give full tlctails. 
 
 These "Food Maps" may be obtained of the Scliool in quantity, 
 printed on good paper— 25 for 10 cents, 100 for 30 ceijts (in stamp!?). 
 
FOOD VALUES IN FOOD UNITS PER OUNCE 
 
 Calories Per Ounce 
 
 Apples, baked .6 
 
 Apples, fresh 2 . 75 
 
 Apple sauce .3 
 
 Apricots 1.3 
 
 Asparagus in cream 2.8 
 
 Bananas 1.5 
 
 Barley, pearl 2 . 97 
 
 Beans, string, (cooked) .9 
 
 Beets, (cooked) : 2.7 
 
 Biscuit, cream 10.3 
 
 Blanc Mange, Farina 4.16 
 
 Bread, corn 8.5 
 
 Bread, graham 10.4 
 
 Bread, rye 10.5 
 
 Bread, white 9.3 
 
 Bread, whole wheat 1 1 . .3 
 
 Buns 7.3 
 
 Butter, (dairy) 1.2 
 
 Buttermilk 3.5 
 
 Cake, frosted 6.8 
 
 Cake, layer 8.2 
 
 Cake, sponge 12.4 
 
 Candy, (Sanitas chocolates) 1 
 
 Canteloupe '. .7 
 
 Carrots, creamed 2.01 
 
 Cashew nuts 28 . 87 
 
 Celery 1.3 
 
 Cheese, cottage 19.9 
 
 Crackers, graham 11.7 
 
 Crackers, oatmeal 13.3 
 
 Cream 2.9 
 
 Cream sauce 3.7 
 
 Custard, caramel 5.2 
 
 Custard, plain 5.7 
 
 Dates, 2.5 
 
 Eggs, poached, etc 16.3 
 
 Eggs (eadi, whole, a'v'g.) 26 . 3 
 
 Eggs {white) each 15.5 
 
 Eggs {yolk) each 10.8 
 
 Figs .5 
 
 Grape fruit .9 
 
 Grapes, 1.16 
 
 Gruel, barley 1 . 48 
 
 Gruel, oatmeal 1.3 
 
 Honey 5 
 
 Macaroni and tomato 5 
 
 Maple syrup 
 
 Mayonnaise, Qook^d ,,,.,,,,, 6 .87 
 
 21§ 
 
 1.3 
 
 28.4 
 
 30 . 3 
 
 7.15 
 
 91.3 
 
 101.1 
 
 .8 
 
 20.6 
 
 21.7 
 
 
 
 15.6 
 
 16.9 
 
 17 
 
 4.9 
 
 24.7 
 
 1.6 
 
 25.7 
 
 28.8 
 
 .87 
 
 27.24 
 
 31.08 
 
 2.9 
 
 2.2 
 
 6 
 
 .3 
 
 8.6 
 
 11.6 
 
 27.5 
 
 49.6 
 
 87.5 
 
 21.56 
 
 18.6 
 
 44.4 
 
 12.3 
 
 52 
 
 72.8 
 
 4.8 
 
 60.8 
 
 76 
 
 1.6 
 
 62.1 
 
 74.2 
 
 3.7 
 
 63.4 
 
 76.4 
 
 2.4 
 
 58 
 
 71.7 
 
 17.3 
 
 66.8 
 
 91.4 
 
 226.6 
 
 
 
 227.8 
 
 1.3 
 
 5.6 
 
 10.4 
 
 24 
 
 74.9 
 
 105.7 
 
 45.1 
 
 76.5 
 
 130.6 
 
 14.2 
 
 94.2 
 
 120.8 
 
 3.8 
 
 85.2 
 
 90 
 
 
 10.9 
 
 11.6 
 
 7.5 
 
 10.3 
 
 19.8 
 
 125.7 
 
 28.24 
 
 182.81 
 
 .3 
 
 3.9 
 
 5.5 
 
 12.4 
 
 5.1 
 
 37.3 
 
 25.1 
 
 86.1 
 
 122.9 
 
 29.6 
 
 80.5 
 
 123.8 
 
 49.3 
 
 5.3 
 
 57.5 
 
 22.9 
 
 9 
 
 35.6 
 
 11.4 
 
 23.6 
 
 40.2 
 
 13 
 
 12.5 
 
 31.2 
 
 7.5 
 
 91.5 
 
 101.5 
 
 32 
 
 
 48.3 
 
 41.9 
 
 
 68.2 
 
 .6 
 
 
 16.1 
 
 41.3 
 
 
 52.1 
 
 8 
 
 86.6 
 
 92.4 
 
 .5 
 
 11.8 
 
 13.2 
 
 3.2 
 
 16.6 
 
 20.9 
 
 .7 
 
 10.2 
 
 12.39 
 
 1.4 
 
 5.8 
 
 8.5 
 
 
 94.7 
 
 95.2 
 
 3.86 
 
 17.16 
 
 26 
 
 
 S3 
 
 83 
 
 '^7,1 
 
 i-M 
 
 7Q.8 
 
Calories Per Ounce 
 
 Milk, skimmed 4 .8 6 10.8 
 
 Milk, whole 3.8 11 5.8 20.6 
 
 Nut butter 34.2 124 20 178.2 
 
 Nuts, almonds 24.5 146.4 20.2 191.1 
 
 Nuts, Brazil 19.8 178.1 8.2 206.1 
 
 Nuts, Filberts • 18.2 174.1 15.2 207.5 
 
 Nuts, Pecans 11.2 188 17.8 217.8 
 
 Nuts, walnut, Eng 19.4 169.2 18.2 206.8 
 
 Oats, rolled (cooked) 3.3 1.3 13.4 18 
 
 Olive oil 264.1 264.1 
 
 Olives, ripe (7) 2 69.1 5 76.1 
 
 Onions, boiled 1.13 4.29 5.1 10.52 
 
 Oranges 9 .5 13.5 14.9 
 
 Parsnips, creamed 2.56 6.5 17.29 26.35 
 
 Peanuts 30.1 102.9 8.5 161.5 
 
 Pears 7 1.3 16.5 18.5 
 
 Peas, green 7.8 9.1 17.5 34.4 
 
 Pie, apple 7.5 18 37.2 62.7 
 
 Pie, custard 4.9 16.8 30.5 52.2 
 
 Pie, squash 4.27 22.7 36.5 63.5 
 
 Potatoes, baked 3.4 .4 28.9 32.7 
 
 Potatoes, boiled 2.9 .3 24.4 27.6 
 
 Potatoes, mashed 3 8 20 .8 31.8 
 
 Potatoes, sweet, browned 4.11 11.25 59. 7 75 
 
 Prunes (cooked) 8 .3 26.4 27.5 
 
 PuddinK, baked Indian 4.8 21.8 20 46.6 
 
 Pudding, bread custard 6.44 32 19.12 37.56 
 
 Pudding, snow 4.78 9.22 16.37 30.38 
 
 Pudding, apple tapioca 4.5 17.58 26.44 48.5 
 
 Raisins 3 8.8 88.8 100.6 
 
 Rice, boiled 3.3 .3 28.5 32.1 
 
 Salad, apple and celery 2.26 4.27 26.16 32.7 
 
 Salad, egg mayonnaise 13.37 30.66 1.46 44.5 
 
 Salad, potato 4.56 25.77 15.06 45.39 
 
 Sandwich, cottage cheese 11.2 33.9 37.6 82.8 
 
 Soup, cream of celery 2.8 19 4.7 26.5 
 
 Soup, cream of potato 2.7 19.2 .9 30.9 
 
 Soup, split pea 7.18 1.85 18.07 27.1 
 
 Soup, tomato bisque 3.1 10.5 2.4 16 
 
 Soup, vegetable 96 5.71 6.9 13.5 
 
 Spinach 3.3 1 4.93 9.3 
 
 Squash, steamed or canned 1 1.3 12.3 14.6 
 
 Sugar (granulated) 116.6 116.6 
 
 Toast, breakfast 11.4 27.5 86.2 125.15 
 
 Toast, cream 4.15 29.9 13.6 47.6 
 
 Tomatoes, stewed or canned 1.4 .5 4.7 6.6 
 
 Wheat flakes, toasted 11 3.9 88.9 103.8 
 
 Zwieback 11.4 26.4 85.8 123.6 
 
 219 
 
Calories Per Ounce 
 
 
 ^« 
 
 
 
 
 3 
 
 136.85 
 
 
 
 155.26 
 
 4.54 
 
 
 
 45.6 
 
 .3 
 
 3 
 
 3 
 
 6.56 
 
 
 
 31.16 
 
 1.02 
 
 
 
 20.32 
 
 95,4 
 
 
 
 113.5 
 
 13.9 
 
 
 
 35.68 
 
 79.7 
 
 
 
 105 
 
 33.3 
 
 
 
 55.5 
 
 13.9 
 
 
 
 35.68 
 
 4.8 
 
 
 
 23.82 
 
 54.1 
 
 
 
 83.2 
 
 3.23 
 
 
 
 10.43 
 
 177.3 
 
 
 
 188.6 
 
 65.4 
 
 
 
 90.3 
 
 84.5 
 
 
 
 103 
 
 46.6 
 
 
 
 66.6 
 
 25.71 
 
 
 
 47.61 
 
 55 . 5 
 
 
 
 77.7 
 
 59.1 
 
 
 
 83.2 
 
 11.2 
 
 
 
 41.6 
 
 FLESH FOODS 
 
 Beef, roasted (fat) 18.14 
 
 Beef, round (boiled, lean) 40 . 9 
 
 Bouillon 2.3 
 
 Chicken (broilers) 24 . 6 
 
 Cod fish 19.3 
 
 Goose 18.1 
 
 Halibut (steak) 21 . 78 
 
 Lamb chops (boiled) 25 . 3 
 
 Lamb (leg, roast) 22 . 2 
 
 Liver (veal) 21 . 78 
 
 Lobsters 19 
 
 Mutton (leg, boiled) 29 . 1 
 
 Oysters 7.2 
 
 Pork (bacon, smoked medium fat) 11.3 
 
 Pork (ham, boiled) 25 . 4 
 
 Pork (loin, chops) 18.5 
 
 Salmon (California) 20. 4 
 
 Shad 21.9 
 
 Trout (-brook) 22 . 2 
 
 Turkey . 24 1 
 
 Veal (leg, boiled) 30 . 4 
 
 UNCOOKED FOODSTUFFS. 
 
 Barley, pearled 9.9 
 
 ISeans (dried) 26 . 3 
 
 Cocoa 25 . 2 
 
 Corn, green 3.6 
 
 Cornmeal 10.7 
 
 Cornstarch 
 
 Flour, graham 15 . .5 
 
 I'lour, rye 7.9 
 
 Flour, wheat (entire wheat ) 16 . 1 
 
 I'lour, wheat (.P'ltent) ' 12.0 
 
 Lemon .iuice ' 
 
 Macaroni •. 3.5 
 
 Oatmeal 18.8 
 
 Oats, rolled 19.5 
 
 Peas (dried) 28 . 7 
 
 Peas, green 8.2 
 
 Potatoes 2.6 
 
 Pice 9.0 
 
 Sweet potatoes 2.1 
 
 Wheat, cracked 13.0 
 
 2.9 
 
 90.8 
 
 103.6 
 
 4.8 
 
 69.5 
 
 100.6 
 
 77.1 
 
 44.0 
 
 146.3 
 
 2.9 
 
 23.0 
 
 29.5 
 
 5.1 
 
 87.9 
 
 103.7 
 
 
 105.0 
 
 105.0 
 
 5.9 
 
 83.3 
 
 104.7 
 
 2.4 
 
 91.8 
 
 102.1 
 
 5.1 
 
 83.8 
 
 105.0 
 
 2.9 
 
 87.7 
 
 103.2 
 
 
 
 11.4 
 
 11.4 
 
 4.0 
 
 18.4 
 
 25.9 
 
 19.2 
 
 78.8 
 
 116.8 
 
 19.5 
 
 77.2 
 
 116.2 
 
 2.7 
 
 72.3 
 
 100.7 
 
 1.3 
 
 19.7 
 
 29.2 
 
 .3 
 
 21.5 
 
 24.4 
 
 .8 
 
 92.0 
 
 101.8 
 
 1.9 
 
 32.0 
 
 36.0 
 
 4.3 
 
 88.1 
 
 106.6 
 
 220 
 
Tables Showing Average Height, Weight, Skin Surface and Food 
 
 Units Required Daily With Very Light Exercise 
 
 BOYS 
 
 A -Hoiirlit in Weieht in Surface in Calories or 
 
 Age ^l£bes PoSndB Square Feet Food Units 
 
 r ^1 ^7 41 09 7.9 816.2 
 
 tlM tll7 8.. 855.9 
 
 7 4.-,. 74 49.07 8.8 912.4 
 
 M 47 76 53.92 9-4 . 981.1 
 
 5 I96M 59.2:5 9.9 1,043.7 
 10 5i:58 65.30 10.5 1,117.5 
 TY fS'^ -43 70.18 110 1,178. J 
 ]h till 76 92 11.6 1,254.8 
 
 3 57:2} 84.85 12.4 1,.S52.6 
 
 {4 59.88 94.91 13. 4 1,471.3 
 
 GIRLS 
 
 W£.ioht ;r. Weieht in Surface in Calories or 
 
 Ag«^ Infhes Pounds Square Feet Food Units 
 
 41.29 39.66 7.7 784.5 
 
 6 43.35 43.28 8.1 831.9 
 -7 Ar, cL.i 47.46 8.5 881.7 
 I tl'U 5204 9.2 957.1 
 Q 49 7 57.07 9.7 1,018.5 
 
 iP, 5134 62.35 10.2 l.OSl.O 
 
 n 5342 68.84 10.7 l-l^^^^ 
 
 i-j .55.88 78.31 11.8 1,276.8 
 
 MEN 
 
 Ti . 1 t iv.jiir>if Siirf'icp in Calories or Food TTiiita 
 
 "n!n inVo^nds s'.uare'^t". Proteid. Fats Carb.ih.vdrates Total 
 
 Ki ■ 131 15.92 197 591 1,182 1,970 
 
 tl ll:5 10.06 200 600 1.200 2,000 
 
 RQ 136 16.27 204 612 1.224 2.0 <0 
 
 11 140 16 55 210 630 1,260 2,100 
 
 B^ Us l6 76 215 645 1.290 2.150 
 
 fii 111 17 06 221 663 1.326 2,210 
 
 R7 152 17 40 228 684 1.368 2.280 
 
 II Igy 17 76 236 708 1.416 2.360 
 
 fiq 166 18 12 243 729 1,458 2.430 
 
 70 167 18 48 251 753 1.506 2.510 
 
 7Y .tva 18 91 260 780 1,560 2.600 
 
 70 i79 19'34 269 807 l,<il4 2,690 
 Ti 185 19:89 278 834 1,668 2.780 
 
 71 192 20.33 288 864 1,728 2,880 
 75 200 20.88 300 900 1,800 3.000 
 
 WOMEN 
 
 •HoioVif Weieht Surface in Calories or Food Units 
 
 inln inPounds Squa.e F?. Proteids Fats Carbohydrates Total 
 
 .-.o 119 14 82 179 537 1,074 1.790 
 
 fO 122 15.03 183 549 1.098 1,830 
 
 (1 124 15 29 186 558 1,116 l,86t) 
 
 62 127 15.50 191 573 1,146 . 1.910 
 
 63 131 15.92 197 591 1.182 1,970 
 ot 134 16 13 201 603 1.206 2.010 
 65 139 16.48 209 627 1.254 2.090 
 06 143 16.76 215 645 1.290 2.150 
 67 1I7 i7 06 221 663 1,326 2.210 
 tl l51 17 34 227 681 . 1.362 2.270 
 69 \^\ 17 64 232 696 1.392 2.320 
 7U 159 17.92 239 717 1,434 2,390 
 
 Note— With active e.Kcrcise an increase of about 20 per cent total food units 
 may be neeUeU. ^ 
 
Dietary Calculation with Food Values in Calories 
 per Ounce 
 
 Breakfast Froteids Fats Carbohydrates Total 
 
 Gluten Gruol 5 oz. 23.5 1.0 30.0 
 
 (i-ach) £'y.o' 41.<i 
 
 Soft-Boiled E^i,' 26.3 41.9 
 
 86.2 
 
 Malt Honey 1 oz. 86.2 
 
 .?.r? .<? 2(1. s 
 
 Creamed Potatoes .1 oz. 15.0 40.0 104.0 
 
 1J.4 2i;.4 8.>.S 
 
 Zwieback 2 OZ. 22.8 52.8 171.6 
 
 11.2 IHN.O 17. s 
 
 Pecans 3| oz. 8.4 141.0 13.4 
 
 .5 J..V io:6 
 
 Apple 5 OZ. 2.5 6.5 830 
 
 98.5 283.2 488.2 869.9 
 
 Dietary Calculation with Food Served in 100 Calories 
 
 Portions 
 
 Dinner I'ortioiis I'roteins P'ats Carbo- 'J'otal 
 
 in >erviiii; Indrates 
 
 French Soup i ., ' 10 20 ' 20 
 
 Nut Sauce 1 " 29 55 16 
 
 Macaroni, Egg 1 15 59 26 
 
 Baked Potato 2 22 2 176 
 
 Cream Gravy H 5 33 12 
 
 Biscuit 111 20 2 128 
 
 Butter l' 1 99 
 
 Honey 2 200 
 
 Celery ^i 4 21 
 
 Apple Juice }/2 ^0 
 
 lOi-i 106 270 649 1,025 
 
 Hourly Outgo in Heat and Energy from the Human Body as 
 Determined in the Respiration Calorimeter by the 
 U. S. Dept. of Agriculture 
 Average (154 lbs.) Calories 
 
 Man at rest (asleep) 65 
 
 Sitting up (awake) ICO 
 
 Light exercise 170 
 
 Moderate exercise 190 
 
 Severe exercise 450 
 
 Very severe exercise 600 
 
 222 
 
10 20 30 40 50 60 70 80 90 100 
 
 DR. FISHER'S FOOD MAP 
 Normal Rectangle for a Balanced Diet, Chittenden's Standard 
 
PROTEIN METABOLISM IN ITS RELATION 
 TO DIETARY STANDARDS* 
 
 Otto Folin, Ph. D, McLean Hospital, Waverly, Mass. 
 
 Present views concerning the role of fats, carbohy- 
 drates, and proteins in the animal organism are not 
 essentially different from views that prevailed a 
 generation ago. An earlier theory, brilliant but 
 untenable in the light of later more exact experi- 
 ments, was advanced by Liebig about the middle of 
 the 19th century. This theory held that the protein 
 taken with the food constitutes the sole source of 
 muscular energy and that fats and carbohydrates serve 
 only to maintain the body tem.perature. 
 
 LIEBIG'S THEORY 
 
 Voit, in the course of experiments undertaken to 
 test the validity of Liebig's theory, established the 
 remarkable fact that severe physical work is not 
 accompanied by any material increase in the 
 destruction of protein within the animal organism, 
 as of course would be the case if protein were the sole 
 or even the chief source of muscular energy. The 
 destruction of Liebig's erroneous but definite theory 
 of metabolism naturally led to renewed investigations 
 concerning the function of fats, carbohydrates, and 
 
 *Paper read at the Lake Placid Conference on Home Economics, June, 
 1905. 
 
 224 
 
PROTEIN METABOLISM 225 
 
 protein; and in this necessary constructive work, 
 Voit became the recognized leader. From his labor- 
 atory came investigations and deductions which 
 have since been almost universally accepted as 
 final. 
 
 Voit's dietary standards, the practical outcome 
 of all this work, are intended to represent a few 
 fundamental facts. A man of average size gives ofT 
 in a day a certain quantity of energy (in the form of 
 work and heat). This energy can be measured and 
 often has been measured, with a fair degree of ac- 
 curacy. The more physical work a man does the 
 more energy both in the form of work and of heat 
 is given off, and the increase in energy consumption 
 due to work or exercise has also been measured. 
 The daily consumption of energy in the animal 
 organism is obtained at the expense of food. 
 And since it is known just how much energy 
 can be obtained from burning a given quantity 
 of fat, starch, or protein, it becomes theoreti- 
 cally simple, and practically quite possible, to 
 calculate the amount of food that a given individual 
 doing a certain work must consume in order to main- 
 tain the equilibrium of the intake and outgo of energy. 
 Such calculations are based on the assumption that 
 food materials when oxidized within the animal 
 organism liberate the same amount of energy as when 
 burned in ordinary air or oxygen, and there is no 
 reason to doubt the correctness of this assumption. 
 
226 FOOD AND DIETETICS 
 
 VOIT'S DIETARY STANDARDS 
 
 In so far as Voit's dietary standards prescribe the 
 amount of dry food material, of available energy- 
 giving material necessary under given conditions, 
 they have undoubtedly been of very great service. 
 The dietary standards, however, prescribe not only 
 how much available energy the daily food must con- 
 tain, but also how much of that energy can be most 
 profitably supplied in the form of protein and how 
 much in the form of fats and carbohydrates. Voit's 
 well known average diet, for example, calls for 56 
 gm. fat, 500 gm. carbohydrates, and 118 gm. protein. 
 
 The justification and probable value of such more 
 specific standards of diet is the subject of this paper, 
 and it is a subject on which I think there is room for 
 differences of opinion. It should, however, at once 
 be stated that such differences of opinion do not 
 concern the non-nitrogenous part of the dietary 
 standards. Voit, and with hiin all competent to 
 have an opinion, are agreed that the fats and carbo- 
 hydrates need not at all be provided in the ratio of 
 56 to 500. 
 
 PROPORTION OF FATS TO CARBOHYDRATES 
 
 It is a well-known fact that if more fat than the 
 animal organism can advantageously oxidize is sup- 
 plied, such fat, in so far as it is absorbed, is stored 
 as fat in the body. If an excess of carbohydrates is 
 taken, such excess is also converted into fat and is 
 
PROTEIN METABOLISM 227 
 
 likewise stored as fat for future use. Further Pfluger 
 has recently advanced the not improbable hypothesis 
 that fats are not completely oxidized as such within 
 the animal organism, but are first converted into 
 carbohydrates. The animal organism is then able 
 to convert carbohydrates into fat and fat into car- 
 bohydrates according to its needs, and the logical 
 conclusion therefore is quite in harmony with the 
 accepted view that it is theoretically a matter 
 of relatively small importance what ratio is selected 
 for the fats and carbohydrates. The two taken 
 together must of necessity furnish the greater part 
 of the fuel value of the food, but upon individual 
 peculiarities, relative cost, and a number of other 
 accidental factors depends what ratio between the 
 two may be most suitable in any given case. 
 
 PROTEIN IN THE DIETARY 
 
 With regard to the protein prescribed by the die- 
 tary standards the case is different. The animal or 
 human organism, while able to convert carbohydrates 
 into fat and probably also fat into carbohydrates, can 
 effect no such transformation of non-nitrogenous 
 food into the highly nitrogenous proteins. It may 
 be able to produce carbohydrates, and therefore also 
 fat, out of protein, but it certainly can not produce 
 protein out of fat or carbohydrates. The protein of 
 the food not only furnishes energy and heat, as do 
 the fats and carbohydrates, but it, and it alone, 
 
228 FOOD AND DIETETICS 
 
 furnishes the material which replaces the constant 
 loss of living protoplasm. It is therefore clearly 
 necessary that the daily food should contain enough 
 protein to protect the organism against loss of body 
 tissue. On the other hand, it is generally believed 
 that instead of being advantageous it is probably 
 detrimental to the full-grown organism to have to 
 take care of more protein than is needed for the re- 
 placement of lost tissue inaterial. An excess of fat 
 or carbohydrates, the human organism can to a very 
 great extent take care of b}^ adding it to its store of 
 body fat, but it has not the power similarly to in- 
 crease its supply of reserve protein. Any excess of 
 nitrogenous material supplied with the food leads at 
 once to a correspondingly increased destruction of 
 protein. And the formation of excessive quantities 
 of nitrogenous katabolism products within the body 
 is supposed to be more or less a source of danger. 
 I think all are agreed that gout at least is largely the 
 result of "high living." 
 
 MINIMUM PROTEIN 
 
 The iinportant question then is. How much pro- 
 tein must the diet of normal persons contain ? Voit 
 came to the difinite conclusion that ii8 grams are 
 needed for a man weighing 70 kilos (150 lbs.), and 
 for more than a generation this figure has been gen- 
 erally accepted as substantially correct. But is it? 
 Since the publication in 18S1 of Voit's great mono- 
 
PROTEIN METABOLISM 229 
 
 graph on metabolism it has been shown by Hirsch- 
 feld, Klemperer, Pechsel, and Siven that the daily 
 protein destruction in men of average size can be 
 reduced to 40 grams or less, and that nitrogen equi- 
 librium can be maintained by furnishing such small 
 amounts of protein with the food. The experiments 
 by means of which Voit secured the almost universal 
 acceptance of his standard minimum protein re- 
 quirement are essentially similar and in no way 
 superior to these more modern experiments which 
 seem to prove that 40 grams of protein, or less, are 
 enough to maintain nitrogen equilibrium. One 
 might therefore suppose that the later experiments 
 would have been accepted as proving the erroneous- 
 ness of Voit's figures, or that they would at least have 
 been deemed sufficiently important to lead to a gen- 
 eral reopening of the whole question. But the earlier 
 conclusions and generalizations of Voit had in the 
 meantime, so to speak, survived the probation period, 
 and had become the accepted doctrine, not to say 
 tradition, of the scientific public. In addition, 
 it must be remembered that Voit's standard 
 comes much nearer the average common usage. 
 The widespread and earnest acceptance of Voit's 
 figure is undoubtedly in a great measure due to the 
 fact that it agrees tolerably well with the protein 
 consumption actually prevailing among the people, 
 specially among those not too poor to procure the 
 more expensive articles of food. 
 
230 FOOD AND DIETETICS 
 
 AVERAGE CONSUMPTION 
 
 It has frequently been asserted that the people 
 at large do as a matter of fact consume on the 
 average about ii8 grams of protein per 70 kilos of 
 weight. But I venture to insist that the question of 
 average protein consumption has little or nothing 
 to do with the problem before us. To argue that 
 the customary or the average consumption of pro- 
 tein is the necessary consumption suggests that the 
 necessary potein consumption is after all far more 
 flexible than is indicated by the standard diets. It 
 also implies that the people have solved the problem 
 without the aid of science, and further that their 
 average health and vigor is now all that we can hope 
 for in so far as the protein contents of the food have 
 anything to do with it. 
 
 Voit, himself, remained, I think, somewhat under 
 the strong influence of Liebig's teachings concerning 
 the peculiar value of protein as a food. It is diffi- 
 cult to see how he could otherwise have failed to 
 find that it is possible to maintain nitrogen equili- 
 brium on a comparatively small fraction of the pro- 
 tein which he declared to be the minimum. It was 
 right and natural that Voit should not put the nec- 
 essary protein requirement at too low a figure; its 
 great practical import demanded cautiousness. But 
 the minimum protein requirement for man could of 
 course not be found except by studying the meta- 
 bolism of man under the influence of smaller and 
 
PROTEIN METABOLISM 231 
 
 smaller quantities of protein. This is clearly demon- 
 strated by the results of the modern low nitrogen 
 equilibrium experiments. 
 
 The disciples of Voit can not and do not question 
 the accuracy of the results recorded from the low 
 protein feeding experiments. But it is now rightly 
 enough held that to prove that a person can main- 
 tain nitrogen equilibrium for a limited length of time, ' 
 as for a few days, on a very small amount of protein 
 does not at all prove that he can permanently do 
 so with advantage or even with impunity. The 
 correctness of this position must be granted, and it 
 is, in fact, the position taken by the more conserva- 
 tive experimenters on low nitrogen equilibrium, as 
 for example by Siven. But while freely admitting 
 this, it must, in my opinon, be insisted that the low 
 protein experiments of even such short duration, as 
 a few days, have completely destroyed the scien- 
 tific basis on which the protein prescriptions of Voit 
 and his disciples are supposed to rest. 
 
 LOW PROTEIN EQUILIBRIUM 
 
 As far as we yet know there is no reason for assum- 
 ing that a diet capable of maintaining nitrogen equi- 
 librium for a week should fail to do so at the end of 
 a month or any other time. In fact, investigations of 
 the last three or four years clearly indicate that nitro- 
 gen equilibrium can be maintained for long as well as 
 for short periods on very small quantities of protein. 
 
232 FOOD AND DIETETICS 
 
 In 1902 Dr. R. O. Neumann, privatdocent in the 
 Hygiene Institute at Kiel, published an account of 
 metabolism experiments with himself covering a 
 period of over two years. The average composition 
 of his diet during that time corresponded to 117 
 grams fat, 213 grams carbohydrates, and 74.2 grams 
 protein per 70 kilos of body weight. Neumann's ex- 
 periments covering such a long period would cer- 
 tainly seem to constitute definite proof that Voit's 
 so-called minimum protein requirement is at least 
 half again as large as is really necessary for the per- 
 manent maintenance of nitrogen equilibrium, physi- 
 cal vigor, and efficiency. 
 
 More striking still are the mstabolism records pub- 
 lished last year by Professor Chittenden. I shall 
 not go into details of this work, as Mrs. Richards is 
 on the program for a report on it. But I must cite 
 the fact that Chittenden maintained a body weight 
 of 57 kilos as well as nitrogen equilibrium from July, 
 
 1903, until the publication of his book in the fall of 
 
 1904, on an average protein consumption of less 
 than 35 grams a day. 
 
 DR. FOLIN'S STUDIES 
 
 My own studies of protein metabolism in man, 
 though pursued in a different way and for a different 
 purpose, have a direct bearing on the problem of the 
 necessary minimum protein consumption. The 
 specific waste products formed from the destruction 
 
PROTEIN METABOLISM 233 
 
 of protein within the human organism are ehminated 
 in soluble form with the urine. They are therefore 
 easily available for detailed chemical investigations, 
 and as the result of innumerable studies much exact 
 knowledge has been gained concerning the normal 
 katabolism products of protein. My investigations 
 lie within this field. 
 
 The views that have till recently prevailed con- 
 cerning the chemistry of urine, in so far as it relates 
 to the problem of protein metabolism, may be con- 
 cisely stated as follows: All the nitrogen of the protein 
 destroyed in the body is eliminated with the urine, 
 and almost 90% of it appears in the form of urea. 
 From 95% to 98% of the nitrogen is eliminated as urea, 
 kreatinin, ammonia, and uric acid. The absolute 
 amount of each of these nitrogenous products depends 
 upon the amount of protein katabolized, but changes 
 in the amount of protein destroyed affect them all 
 equally, thus leaving them always in about the same 
 proportion to each other and to the total nitrogen. 
 This fact, if correct, is very important, ^because it 
 clearly indicates a certain unity in the chemical pro- 
 cesses concerned with the use and destruction of 
 protein within the body. It indicates that the pro- 
 tein of the food and the protein of the living tissues 
 are essentially alike and in the same condition with 
 reference to the organism at the time of their final 
 destruction. The two rival theories concernintr 
 this subject accordingly agree in assuming the essen- 
 
234 FOOD AND DIETETICS 
 
 tial unity of the chemical processes involved in pro- 
 tein katabolism, and the only point of difference 
 between the two is that one, the theory of Voit, 
 holds that the protein must be in solution and dead 
 before being oxidized and destroyed, while the other, 
 that of Pfiuger, assumes that it is only actually liv- 
 ing protoplasm that is destroyed. 
 
 It would be useless in this connection to go into 
 a detailed discussion of these two theories, because 
 I think it can be shown that the fundamental pre- 
 mise of both, namely, the supposed constancy in 
 the relative distribution of the urinary nitrogenous 
 products, is no longer tenable. 
 
 RELATIVE PROPORTION OF NITROGEN WASTE PRODUCTS 
 
 The -fact that the relative proportions of the vari- 
 ous nitrogenous constituents of normal human urine 
 have so long been supposed to be approximately 
 constant is in a measure directly the result of 
 Voit's teachings concerning the minimum protein 
 requirement. The destruction of loo grams pro- 
 tein or more within the organism, as demanded by 
 the dietary standards, rendered it well nigh impos- 
 sible to discover the laws that govern the formation 
 and elimination of each product. About a year and 
 a half ago I discovered accidentally that the urine 
 corresponding to a very low protein katabolism has 
 a chemical composition which is very different from 
 that of urine derived from the standard diets. This 
 
PROTEIN METABOLISM 235 
 
 led to numerous attempts to reduce the daily pro- 
 tein destruction in normal persons to the lowest pos- 
 sible level. 
 
 Nearly all preceding attempts to reduce the pro- 
 tein katabolism have also been attempts to main- 
 tain at the same time nitrogen equilibrium. In 
 mine the question of nitrogen equilibrium, or loss 
 of protein, was not considered, and I have as a matter 
 of fact used a diet containing almost no protein. I 
 have kept several normal persons for a week or more, 
 two or three persons for two weeks, and one for 17 
 days on a diet consisting exclusively of pure arrow 
 root starch and 300 cc. of cream. In this way the 
 daily protein katabolism has repeatedly l)een reduced 
 to about 20 grams a day. 
 
 Detailed chemical studies of the urines corresi)ond- 
 ing to such greatly reduced protein katabolism have 
 shown that the relative proportion which the nitro- 
 genous products bear to each other and to the total 
 nitrogen does change and very greatly. For ex- 
 ample, the kreatinin elimination is entirely inde- 
 pendent of the total amount of protein katabolized. 
 It is just as great on a diet containing no protein as 
 on one containing 118 grams of protein. In the one 
 case it represents from 17% to 20% of the total nitro- 
 gen, in the other from 3% to 4%. The urea, on the other 
 hand, is peculiarly a product of excessive protein 
 katabolism. When the urinary nitrogen represents 
 a kataboHsm of 100 grams of protein, 90% of that 
 
236 FOOD AND DIETETICS 
 
 nitrogen is present as urea, while when the protein 
 katabolism has been reduced to 20 grams, only from 
 50% to 60% of its nitrogen appears in the form of 
 urea. 
 
 DIFFERENT KINDS OF PROTEIN METABOLISM 
 
 These facts concerning urea and kreatinin suffice 
 to show how entirely erroneous has been the assump- 
 tion that the nitrogen of katabolized protein is 
 always distributed in the same proportion among 
 the different waste products. It may therefore be 
 superflous now to go into further details concerning 
 the laws that govern the formation and elimination 
 of the different products. The fact that these laws 
 are widely different for different products, as for 
 urea and kreatinin, demonstrates with a fair degree 
 of certainty that protein metabolism is not all of 
 one kind. 
 
 The true minimum katabolism or protein, as ob- 
 tained in my feeding experiments with starch and 
 fats, is clearly very different from the katabolism 
 of the large quantities of protein demanded by the 
 dietary standards. The former converts not over 
 60% of the protein nitrogen into urea, and is the 
 source of all the kreatinin eliminated with the urine. 
 The katabolism of that food protein which is not 
 absolutely needed for the maintenance of nitrogen 
 equilibrium, on the other hand, yields probably at 
 least 95% of its nitrogen in the form of urea and 
 yields no kreatinin whatever. The katabolism 
 
PROTEIN METABOLISM 237 
 
 which yields the kreatinin clearly tends to be con- 
 stant and independent of the food protein; it can 
 therefore fairly be said to represent the tissue meta- 
 bolism. The katabolism which yields chiefly urea 
 is the katabolism of the excessive food protein, and 
 its amount depends directly upon the amount of 
 protein contained in the food. This I have called 
 the exogenous metabolism. 
 
 EXOGENOUS METABOLISM 
 
 Since the exogenous metabolism seems to have 
 nothing to do with the tissue metabolism, and since 
 it increases immediately with every increase of pro- 
 tein furnished with the food and in porportion to 
 such increase, it represents nothing else than the 
 effort of the organism to get rid of nitrogen that it 
 does not need and can not use. The remarkable 
 ability of the human organism to establish nitrogen 
 equilibrium on almost any quantity of protein does 
 therefore not mean, as has been believed, that the 
 organism uses protein by preference instead of fats 
 and carbohydrates. This phenomenon is rherely 
 the result of our habitual consumption of more pro- 
 tein than can be used in the tissue metabolism. 
 Being always supplied with an excess, we have al- 
 ways with us the maximum amount of reserve pro- 
 tein that we can advantageously carry, and any 
 further increase in the supply simply leads to an in- 
 creased elimination. 
 
23S FOOD AND DIETETICS 
 
 CONCLUSIONS 
 
 Such, in brief, are the conclusions which I have 
 drawn from detailed studies of the waste products 
 of protein katabolism. 
 
 To recapitulate: We have learned from Voit that 
 protein is not needed to supply energy ; and the work 
 of more recent investigators has demonstrated that 
 nothing like 100 grams of protein is needed to 
 maintain nitrogen equilibrium in a man of average 
 size. Further, from detailed analytic studies, we 
 have learned that some waste products, like kreatinin, 
 represent tissue metabolism, and others, like urea, the 
 metabolism of that food protein which is destroyed 
 as rapidly as it is taken in. The two kinds of meta- 
 bolism are independent. The tissue metabolism 
 is for each individual a constant quantity, irrespec- 
 tive of the amount of protein contained in the food. 
 Obviously, therefore, there is a constant minimum 
 protein requirement to prevent loss of tissue material. 
 The amount of protein needed for this purpose is 
 very small, probably not over 25 grams a day. It 
 does, however, not necessarily follow that 25 grams 
 protein should btf prescribed instead of 118 grams. 
 The prevailing idea that consumption of more than 
 the minimum amount of protein is detrimental to 
 health may not be true. The minimum may not 
 be the optimum. But what has been considered 
 the minimum, 118 grams, may be beyond the opti- 
 mum, possibly even above the maximum amount 
 of protein that any normal person should consume. 
 
I' ROTE IN MPITABOLISM 239 
 
 DISCUSSION 
 
 Mrs. Abel — I should like to ask Dr. Folin if he 
 would recommend for tuberculosis patients a great 
 deal of milk and eggs. 
 
 Dr. Folin — Any opinion I give must simply be 
 my own. I should be inclined to think it unneces- 
 sary to prescribe any quantity of protein whatever. 
 By that I do not mean to say how much should be 
 consumed, because in our food products, say bread 
 and butter, there is enough to meet all requirements 
 as shown by these investigations, but at the same 
 time the experience of past generations shows that 
 we can at least, without any noticeable disadvan- 
 tage, consume considerable quantities of protein. 
 For instance, I should not advise stopping all use of 
 meat. I should be inclined to take the same atti- 
 tude toward protein as toward fats and carbohy- 
 drates. We must have enough food to maintain 
 the energy that is consumed, and I think the same 
 liberty can be taken toward protein as toward the 
 other two. We do not quite know just what is 
 the effect of compelling the system to eliminate 
 large quantities, and so long as we do not know I do 
 not believe we can take a very definite standpoint 
 on the question. It is generally believed that such 
 diseases as gout are more or less directly due to high 
 living, but we can not prove it, and moreover it is 
 a question whether protein consumption and meat 
 eating are at all identical. Such products as uric 
 
24o FOOD AND DIETETICS 
 
 acid are formed in large quantities by meat eaters, 
 but they are not formed when such products as 
 milk and eggs are taken; consequently, I should say 
 that we do not know. 
 
 In regard to such disease as consumption, I have 
 no personal experience, but if the point is merely 
 to build them tip and give them a laige amount of 
 reserve material, we can see that it is entirel}^ unneces- 
 sary to feed large quantities of milk and eggs, be- 
 cause the nutrition of milk and eggs is at once 
 eliminated, and presumably the rest of that food is 
 stored as fat and carbohydrates, and so I should be 
 inclined at least to consider it worth while to try 
 whether fat and carbohydrates would not produce 
 just as good results. 
 
 Mrs. Abel — There are several here I think who 
 have to do with feeding people in hospitals, and one 
 lady with tuberculosis patients, and I should like 
 very much for my own information to know whether 
 these patients take and digest and seem to flourish 
 under this high feeding of eggs and milk. I myself 
 have to visit a poorhouse where there are loo tuber- 
 culosis patients. Eggs are 40 cents a dozen in winter, 
 and the state must pay for them. Still the prescrip- 
 tion is 3 and 4 eggs a day and a large quantity of 
 milk. If it is not necessary, it is of 'immense im- 
 portance to the whole countr}^ to know it, for other 
 patients need the money which now goes for this 
 purpose. 
 
PROTEIN METABOLISM 
 
 241 
 
 MxssFrascr—\ am trying to feed consumptive 
 patients as economical!)- as possible, to give them 
 the things they like and must have and to do it all 
 on a certain sum. Our patients are fed in the fol- 
 lowing way. They have breakfast at 730 We 
 expect them to take half an hour for that meal, and 
 they may stay as much longer as they Hke. At 10 30 
 they have their lunch of milk and eggs, no limit to 
 the quantity of milk and eggs or ^gg nog. At 12 30 
 - we have dinner. A number of patients at that 
 meal take a raw Qgg and milk. At 3.30 they are 
 called to lunch, milk and eggs. At 5.45 supper 
 milk and eggs again and just as much as they can 
 eat besides. At 8.30 milk and eggs, again. Some 
 ot those patients during the night take milk and eggs 
 We give them cereal twice a day, for breakfast and 
 supper, cooked eight hours in a double boiler They 
 are very fond of that, but we find that if they know 
 there is steak they do not take so much. The same 
 at dinner with soups. I find they do not take as 
 much, for they think they must save space for roast 
 beef. Vegetables they are fond of. I try to give 
 them as much as they can eat. Thev seem to have 
 an idea that they must eat plenty of rare beef and 
 milk and eggs. I have heard patients who have 
 been cured, come back and say to the others "Now 
 eat all the meat and milk and eggs that you can and 
 never mind the other things." Farther than that 
 I .cannot tell. The patients look healthy and no 
 
242 FOOD AND DIETETICS 
 
 one would have any idea that they were a lot of sick 
 people. 
 
 Miss Bevier — Would Dr. Folin say that we can 
 not help getting from any food as much protein as 
 the system needs and so there is no such thing as 
 balanced rations? 
 
 Dr. Folin — If you eat enough bread and butter 
 to give 2500 calories, I believe you would get enough 
 protein. Be sparing of the butter if fat is too great. 
 It is exceedingly difficult to get any diet that does 
 not contain nutrition that is equal to the metabo- 
 lism. 
 
 The one point that you would need to consider 
 would be fuel value and in regard to that there is 
 now perhaps a little difference of opinion. The 
 work done by the department of agriculture is prob- 
 ably the safest guide at present,. 
 
 Dr. Laiigu'orthy — Dr. Folin's is the most impor- 
 tant contribution to the subject made in a long time. 
 It clears up some matters, throws light on others, 
 and I think when work has gone on for a time 
 longer we shall know a great deal more about this 
 subject. I like his attitude in not drawing frenzied 
 conclusions from so many and interesting results. 
 I never want to forget that whenever we find a race 
 living on a small amount of food, or largely on vege- 
 table diet, it is not a capable race. The Italian 
 peasants who live on corn meal and a little fish do 
 little work, yet bring them to this country and give 
 
PROTEIN METABOLISM 2.;:, 
 
 them better diet and they do a great deal more and 
 better work in a day. The second and third gener- 
 ation develops a larger man than his father or grand- 
 father. We find that the Japanese eat just al)out 
 the same amomit of protein as the standard covers. 
 ***** 
 Mrs. Rtrhards — One point which every one has 
 very carefully left out of this discussion is the food of 
 the child. All these experiments in lowering the 
 food protein must be practiced on our own and not 
 on the children's diet at present. 
 
SUPPLEMENTAL PROGRAM ARRANGED FOR 
 CLASS STUDY ON 
 
 FOOD AND DIETETICS 
 
 MEETING I 
 
 (Study pages i - 29) 
 The Food Problem 
 Food materials and their Adulteration, by Ellen H. Richards. 
 
 Chapter I. ($1.00, postage loc.) 
 Cost of Food, by Ellen H. Richards. Pages 1-7. ($1.00, 
 
 postage 1 20.) 
 Sanitary and Economic Cooking, by Mary Ilinman Abel. 
 
 Pages 1-5. (40c., postage loc.) 
 Cost of Food 
 
 Cost of Food, by Ellen 11. Richards. Chapters XI-XIV. 
 Bulletin No. 129 (Office of the Experiment Stations), Dietary 
 
 Studies in Boston, Springfield, Philadelphia, and Chicago. 
 
 Price IOC (coin), of the. Supt. of Documents, Washington, 
 
 D. C. 
 Sanitary and Economic Cooking — Some Cheap Dishes. 
 
 Pages 25-33. 
 Ru,mford Kitchen Leaflets — Good food for little Money, 
 
 by Ellen H. Richards, ($1.00, postage loc.) 
 Principles of Nutrition and the Nutritive Value of Food. 
 
 Farmers' Bulletin No. 142. (Free of Dept. of Agriculture, 
 
 Washington, D. C.) 
 Topic: Food in Relation to National Character. 
 
 MEETING II 
 
 (Study pages 30-49.) 
 Food and the Body 
 
 Principles of Nutrition and Nutritive Value of Food. Farm- 
 ers ' Bulletin No. 142. 
 Food and Dietetics, by Hutchison. Chapter I. ($3.00, 
 postage 30c.) 
 
 244 
 
FOOD AND DIETETICS 245 
 
 Food Principles 
 
 Make experiments on proteids described on pages 41 and 42. 
 
 Clean and grate a small potato under slowly running water, 
 pour through muslin to collect fibers, let starch settle. 
 
 Exhibit: Make up an exhibit showing quantities of food hav- 
 ing the same fuel and energy value — say 800 calorics, 
 which is a little over one-third the daily requirement for 
 a woman at moderate work according to dietary standards. 
 Show bread, meat, butter, milk, eggs, sugar, potatoes, 
 apples, etc., and label each food with the weight in ounces 
 and cost. 
 
 Calculation. Bread furnishes about 1650 calories per pound; 
 to furnish 800 calories would require 800 divided by 1650; 
 which multiplied by 16, equals 7.75 oz. — about half a 
 loaf. Milk furnishes 325 calories per pound. 800 divided 
 by 325 and multiplied by 16 equals about 40 oz., or a 
 quart and half a pint, and so on. 
 
 Exhibit: Make an exhibit of foods containing 1.126 oz., 
 of proteid, — one-third the daily ration for a woman — 
 labeling each with the weight and cost. 
 
 MEETING III 
 
 (Study pages 50-61) 
 Dietary Standards 
 
 Food and Dietetics, by Hutchison. Chapters II and III. 
 
 ($3.00, postage 26c.) 
 Dietary Computer, by Ellen H. Richards. ($1.50, postage 
 
 I2C.) 
 
 Bulletin No. 28, American Food Materials. Price 5 cents 
 (coin), of the Supt. of Documents, Washington, D. C. 
 
 Physiological Economy in Nutrition, by Chittenden. In- 
 troduction, Chapters IV, V, and Conclusion. ($3.00, 
 postage 20c.) 
 
 Article in Century Magazine, February, lyo^, by Chittetidgji, 
 
 .i**^ 
 
246 PROGRAM 
 
 Protein Metabolism in Relation to Dietary Standards, by 
 Folin. See vSupplement, pages 196-215. See " Notes on the 
 
 Questions," pages 191-195. 
 
 Send to the Battle Creek Sanitarium, Battle Creek, Mich., 
 for some of their menus giving fuel value of food served. 
 
 See articles in Good Housekeeping, — August, 1906, " Fletch- 
 erism as Household Economy," and October, 1906, " Sense 
 and Science in Dietetics," by Dr. Stedman. 
 
 Exhibit: Make up exhibits showing a standard day 's 
 ration for a woman with light exercise — 80 grams (about 
 3 oz.) of proteid — with sufficient fats and carbohydrates 
 to bring the total fuel value up to 2300 calories. See 
 Bulletin No. 28, American Food Materials, for composi- 
 tion of any foods not given in the lesson books. 
 
 (Select answers to Test Questions on Part I and send them 
 to the School and report on exhibits and supplemental 
 work.) 
 
 MEETING IV 
 
 (Study pages 63 - 1 16) 
 Special Foods 
 
 Food and Dietetics, by Hutchison, and other standard 
 
 books. 
 Food Products of the World, by Green. ($1.50, postage 
 
 14c.) 
 Meat and Fish 
 
 Meats, Composition and Cooking. Farmers' Bulletin No. 34. 
 Fish as Food. Farmers' Bulletin No. 85. 
 Poultry as Food. Farmers' Bulletin No. 182. 
 Meat on the Farm, Butchering, Keeping, Curing. Farmers' 
 
 Bulletin No. 183. 
 Roasting of Beef, Circular 71, University of Illinois. Isabel 
 
 Bcvicr. (Postage 2c.) 
 
FOOD AND DIETETICS 247 
 
 Eggs, Milk, and Milk Products 
 
 Eggs and their use as Food. Farmers' Bulletin No. 128. 
 
 Milk as Food. Farmers' Bulletin No. 74. 
 
 Facts about Milk. Farmers' Bulletin No. 42. 
 
 Food Value of Cheese, in Farmers' Bulletin No. 244. 
 
 Milk Supply of Two Hundred Cities and Towns. Bulletin 
 
 No. 46. Price 10 cents (coin), of the Supt. of Documents, 
 
 Washington, D. C. 
 Milk and its Products, by Wing. ($1.00, postage loc.) 
 Cereals and Cereal Products 
 
 Bread and the Principles of Bread Making. Farmers' Bul- 
 letin No. 1 12. 
 Wheat, Flour, and Bread. Extract No. 324. 
 Macaroni Wheat. Extract No. 326. 
 Studies in Bread and Bread Making. Bulletin No. loi. 
 
 Price 5 cents (coin), of Supt. of Documents, Washington, 
 
 D. C. 
 Cereal Breakfast Foods. Farmers' Bulletin No. 249. 
 Cereal Breakfast Foods. Bulletin No. 84 and 118, Maine 
 
 Agricultural Experiment Station, Orono, Maine. 
 Pop Corn, in Farmers' Bulletin No. 202. 
 Corn Plants, by Sargent. (75c., postage be) 
 Story of Grain of Wheat, by Edgar. ($1 . 00, postage loc.) 
 Sugar 
 
 Sugar as Food. Farmers' Bulletin No. 93. 
 Maple Syrup and Sugar, in Farmers' Bulletin No 124. 
 (Select answers to Test Questions on Part II and report on 
 
 suppleinental work.) 
 
 MEETING V 
 
 (Study pages 119- 157) 
 Vegetables, Fruits, and Nuts 
 
 Beans, Peas, and other Legumes as Food. Farmers' Bul- 
 letin No, 121, 
 
248 PROGRAM 
 
 Sweet Potatoes. Farmers' Bulletin No. 127. 
 
 Peanuts: Culture and Uses. Farmers' Bulletin No. 25. 
 
 Value of Potatoes as Food. Extract from Year Book, 1900. 
 
 Losses in the Cooking of Vegetables. Farmers' Bulletin 
 No. 73. 
 
 Mushrooms as Food, in Farmers' Bulletin No. 79. 
 
 Banana Flour; Canned Tomatoes, in Farmers' Bulletin 
 No. 119 
 
 Chestnuts, in Farmers' Bulletin No. 114. 
 
 Coffee Substitutes, in Farmers' Bulletin No. 122. 
 
 Food Value of Beans, in Farmers' Bulletin No. 169. 
 
 Nuts as Food. Bulletin No. 54, Maine Agricultural Experi- 
 ment Station, Orono, Maine. 
 
 Coffee Substitutes. Bulletin No. 65, Maine Agricultural 
 Experiment Station, Orono, Me. 
 
 Nutrition Investigations among Fruitarians and Chinese, 
 Bulletin No. 107. Price 5 cents (coin,) of the Supt. of 
 Documents, Washington, D. C. 
 
 Further Investigations among Fruitarians, Bulletin No. 132. 
 Price 5 cents (coin), of the Supt. of Documents, Washing- 
 ton, D. C. 
 
 Food and Dietetics, by Hutchison. Chapters XIV and 
 XVIII. 
 
 Cocoa and Chocolate. Walter Baker Co., Dorchester, Mass. 
 (Postage 6c.) 
 
 MEETING VI 
 
 (Study pages 158 - 180) 
 Adulteration of Food 
 
 See Articles on "Safe Food" in the Delineator, January to 
 
 July, 1906, by Mary Hinman Abel. 
 Food Materials and their Adulterations, by Ellen H. 
 
 Richards. ($1.00, postage loc.) 
 Standards of Purity for Food Products. Circular Np. 17. 
 
FOOD AND DIETETICS 249 
 
 Use and Abuse of Food Preservatives. Extract No. 221. 
 
 Some forms of Food Adulteration and Simple Methods for 
 their Detection. Bulletin No. 800, Bureau of Chemistry. 
 Price 10 cents (coin), of the Supt. of Documents, Washing- 
 ton, D. C. 
 
 Make some of the tests described in the text and above 
 bulletins. 
 
 Officials Charged with Enforcement of Food Laws. Circular 
 No. 16. 
 
 The food laws of your own state. Write to the officer given in 
 Circular No. 16 for them and send for the part of bulletin 
 of Bureau of Chemistry containing them. 
 
 Topics: Laws, if any, in your own town. Arc they en- 
 
 forced ? 
 
 The Local Milk Supply, — -nvestigale. 
 Condition of the Local Slaughter Houses. 
 
 Special Diet 
 
 Food and Dietetics, by Hutchison. Diet in Disease, Chap- 
 ter XXVIL 
 
 Diet in Obesity and Fattening Diet. Chapter XXVIIL 
 
 Food as a Factor in Student Life, by Richards and Talbot. 
 (25c., postage 2c.) 
 
 Diet in Relation to Age and Activity, by Thompson. 
 ($1.00, postage 8c.) 
 
 A, B and Z of our own Nutrition, by Fletcher.' ($1.00, 
 postage IOC.) 
 
 Vegetarianism, by Kellogg. 
 
 (Select answers to Test Questions on Part III and report on 
 supplemental work.) 
 
INDEX 
 
 Adulteration of butter, 93 
 
 of cofTee, 147 
 
 of food, 158 
 
 of milk, 91 
 
 of tea, 142 
 Albumin, 68 
 Albuminoids, 43 
 Animal food, 63 
 Apple, composition of, 131 
 Atwater's experiments, 52 
 
 Bacon, digestibilitj^ of, 6(; 
 Bacteria in butter, y2 
 
 in cheese, 96 
 
 in milk, 89 
 Balanced ration, 56, i(;4. 
 Beef, 70 
 
 digestibility of, 70 
 
 juice, 72 
 Bibliography, 181 
 Bomb calorimeter, 35 
 Borax experiment, 1O5 
 Boric acid, 91 
 Bread, 106 
 
 corn, 108 
 
 graham ,111 
 
 making, 1 10 
 
 nutritive value of, 112 
 
 rye, 108 
 
 white, 1 1 2 
 
 whole wheat, 1 1 1 
 
 yeast, 109 
 Breakfast foods, 103 
 Broth, nutritious, 72 
 Butter, 92 
 
 adulteration of, 93 
 
 effect of cooking, 9^ 
 
 ryncid, 93 
 
 Butter, renovated, 93 
 
 Butterine, 94 
 
 Buttermilk, 86 
 
 Cabbage, composition of, ] 25 
 
 Caffeine, 155 
 
 Calculations of dietaries, 56, 
 
 191 
 Caloric, 34 
 Calorimeter, bomb, 35 
 
 respiration, 32, 52 
 Carbohydrates, 64 
 
 classification of, 45 
 
 composition of, 44 
 
 in nuts, 136 
 
 in vegetables, 1 20 
 Carrots, composition of, 124 
 Casein, 41, 87 
 Cellulose, 47 
 
 effect of cooking on, 121 
 
 in vegetables, i 20 
 Cereal coffee, 156 
 Cereals, 98 
 
 composition of, 99 
 
 cooking of, 105 
 
 digestibility of, 104 
 Chart, composition of foods, 
 28, 37 
 
 division of income, 8 
 
 heat and energy, 36 
 
 of economy-of focjds 29, 84 
 Cheese, 95 
 
 digestibility of, 96 
 
 effects of cooking on, 96 
 Children, food for, 174 
 Children's parties, 175 
 Chittenden's experiments, 54 
 Chocolate, 153 
 Clams, 75 
 
 250 
 
INDEX 
 
 251 
 
 Coal tar dyes, 164 
 Cocoa, 148 
 
 digestibility of, 155 
 
 food value of, 154 
 
 nibs, 132 
 
 physiological effects of, 155 
 
 shells, 152 
 Coffee, 143 
 
 adulterants, 147 
 
 cereals, 156 
 
 composition of, 144 
 
 physiological effects of, 155 
 
 tests, 147 
 Collagen, 43 
 Coloring matters, 163 
 Composition of apple, 131 
 
 of carbohydrates, 44 
 
 of cereals, 99 
 
 of coffee, 144 
 
 of eggs, 77 
 
 of fats, 48 
 
 of fish, 74 
 
 of food, 28, 30 
 
 of meat, 67 
 
 of milk, 81, 87 
 
 of nuts, 136 
 
 of potato. 126 
 
 or proteids, 42 
 
 of tea, 141 
 
 of the body, 31 
 
 of vegetables, 1 20 
 Condensed milk, 90 
 Cookery, economical, 13 
 Cooking, cost of, 10 
 
 effect on meat, 70 
 Cost of cooking, 10 
 
 of eggs, 80 
 
 of fish, 73 
 
 of food, 7, 25 
 
 of labor, 11 
 
 of meat, 71 
 Cucumber, composition of, 1 28 
 
 Dextrin, 47 
 
 Diet, 173 
 
 for children, 174 
 
 for old age, 179 
 
 students', 178 
 
 to reduce fat, 179 
 Dietaries, 50, 52 , 197 
 
 calculations of, 56, 191 
 
 estimating, 59, 173 
 
 experimental, 52 
 
 standard, so, 52, 54, 194, 
 221, 225, 242 
 Dietaries, statistical, 53 
 
 use of, 58 
 Digestibility, 36, 65 
 
 of cereals, 104 
 
 of cheese, 96 
 
 of eggs, 79 
 
 of fruits, 133 
 
 of meat, 69 
 
 of milk, 85 
 
 of nuts, 137 
 
 of vegetables, 65, 127 
 Dyes in food, 164 
 
 Eating between meals, 177 
 
 manner of, 175 
 Economy, food, 26, 29 
 
 in cookery, xt^ 
 Eggs, 77 
 
 composition of, 77 
 ■ cost of, 80 
 
 digestibility of, 79 
 Energy, 33 
 
 kinetic, 34 
 
 potential, ■iii 
 
 source of, n 
 
 unit of, 34 
 Engel's laws, 7 
 Extractives, 43, 71 
 Extracts of meat, 72 
 
 Factors in dietary calculations, 
 
 61 
 Fats, 48 
 
252 
 
 Fats, in child's diet, 176 
 
 in milk, SS 
 Fibrin, 67 
 Fish, 72 
 
 cooking of, 76 
 
 cost of, 73 
 
 digestibility of, 72 
 
 dried, 76 
 
 shell, 74 
 
 smoked, 76 
 Flour, 10 1 
 
 bolting, 10 1 
 
 scalpings of, 102 
 
 standard, 103 
 
 testing of, 102 
 Folin's experiments, 55 
 
 studies, 204 
 Food, 30 
 
 adulteration of, 158 
 
 amount required, 50 
 
 animal, 63 
 
 building, 3 1 
 
 classification of, 49 
 
 composition of, 30 
 
 cost of, 7, 64 
 
 digestibility of, 36, 38 
 
 economy, 10 
 
 energy in, 32 
 
 for children, 174 
 
 for different ages, 50 
 
 fuel value, 32 
 
 functions of, 30 
 
 nutrients of, 49 
 
 preservatives, 161 
 
 principles, 41, 49 
 
 vegetable, 63 
 
 waste of, 1 2 
 Formaldehyde, 91 
 Fruits, 130 
 
 canned, 131 
 
 digestibility of, 133 
 
 dried, 131 
 
 unripe, 133 
 Fuel foods, 39 
 
 INDEX 
 
 Gelatine, 43 
 
 test, 172 
 Gelatinoids, 43 
 Glucose, 114, 160 
 Gluten, 41, 107 
 Glycogen, 47 
 Government bulletins, 1S2 
 
 Heat, 32 
 
 in body, 32 
 
 mechanical equivalent of, 35 
 
 unit of, 34 
 Hydration of starch, 122 
 
 Income chart, 8 
 
 Kinetic energy, 34 
 Koumiss, 86 
 
 Labelling, correct, 162 
 Labor, cost of, 1 1 
 Lact-albumin, 87 
 Lactic acid, 89 
 Lactose, 87 
 Leavening agents, loS 
 Legumin, 42 
 Liebig's theory, 196 
 Lobsters, 75 
 
 Meat, 66 
 
 cost of, 71 
 
 digestibility of, 69 
 
 effect of cooking, 70 
 
 extracts of, 72 
 
 fat of, 68 
 
 flavor of, 68 
 
 losses in boiling, 70 
 
 proteids of, 67 
 Mechanical equivalent of iieat, 
 
 35 
 Menus, 24 
 Metabolism, 224 
 exogenous, 237 
 protein, 224 
 
INDEX 
 
 253 
 
 Milk, 80 
 
 adulteration of, 91 
 
 boiled, 86 
 
 composition of, 81, 87 
 
 condensed, 90 
 
 cost of, 82 
 
 digestibilit}' of, 85 
 
 fats, 88 
 
 mineral matter in, 88 
 
 powder, 91 
 
 preservatives, 91 
 
 products, 92 
 
 pure, 90 
 
 sour, 8q 
 
 sugar, 87 
 Mineral matter, 48 
 Molasses, 116 
 Mushrooms, 127 
 Mutton, digestibility of, 70 
 Myosin, 42, 67 
 
 Nutrient ratio, 48, 51, 8r 
 Nutrients of food, 49 
 Nuts, 136 
 
 Oleomargarine, 94 
 Omnivorous tastes, 1 76 
 Ossein, 43 
 Oysters, 75 
 
 Pectin, 48, 130 
 
 Pectose, 48 
 
 Pork, digestibility of, 69 
 
 Potato, composition of, 126 
 
 Potential energy, 33 
 
 Preservatives, 165 
 
 milk, 91 
 Program for supplemental 
 
 stud}', 244 
 Proteids, 41 
 
 composition of, 42 
 
 equilibrium, 203 
 
 in nuts, 136 
 
 minimum, 200 
 
 Proteids, nomenclature of, 43 
 of meat, 67 
 
 requirements in the body, 55 
 requirements for children, 
 
 174. 215 
 source of, 66 
 Protein, 43 
 
 metabolism in relation to 
 dietarv standards, 244 , 
 243 
 Pure food, 158 
 
 food bulletins, 186 
 
 Ration, balanced, 56, 194, 214 
 Renovated butter, 93 
 Respiration calorimeter, 32 
 
 Salts, 48 
 
 of vegetables, 126 
 Serving, daint}-, 26 
 Shell-fish, 74 
 Skimmed milk, 86 
 Soup meat, nutritive value of, 
 
 71 
 
 Soups, 71 
 
 nutritive value of, 71 
 Sour milk, use of, 89 
 Special diet, 173 
 
 food stuffs, 63 
 Standard dietaries, 52, i;4, 194, 
 
 225, 242 
 Starch, 45 
 
 com, 45 
 
 hydration of, 122 
 
 in fruits, 130 
 
 structure of, 46 
 Starchy vegetables, 124 
 'Students' diet, 17S 
 Sugar, 113 
 
 beet, 114 
 
 cane, 115 
 
 digestibility of, 114 
 
 effect on diet, 116 
 
 granulated, 115 
 
254 INDEX 
 
 Sugar, in vegetables, 123 
 maple, 115 
 poA\dered, 1 15 
 test of, 115 
 value as food, 1 13 
 
 Table of comparative diges- 
 tibility, 39 
 
 of comparative food value 
 of milk, 82 
 Table of composition of cere- 
 als, 99 
 
 of cocoa, 153 
 
 of coffee, 146 
 
 of common foods, 57 
 
 of dried fruits, 135 
 
 of fish, 74 
 
 of fruits, 134 
 
 of meats, 57 
 
 of nuts, 137 
 
 of oysters, 75 
 
 of soup, 20 
 
 of starches, 22 
 
 of sugars, 22 
 
 of tea, 146 
 
 of vegetables, 23, 129 
 Table of cost of food, 17, 19, 
 
 27' 77. 
 
 of digestibility, 38 
 
 of nutritive value, 15 
 Tannic acid, 156 
 Tea, 138 
 
 adulteration of, 142 
 
 composition of, 141 
 
 names of, 140 
 
 Tea, physiological effects, 155 
 
 tests, 142 
 
 varieties of, 13S 
 Tests for aniline colors, 171 
 
 for butter, 168 
 
 home, 168 
 Theobromine, 153 
 Turnip, composition of, 124 
 
 Veal, 70 
 
 Vegetable dyes, 164 
 
 foods, 63 
 Vegetables, 119 
 
 cellulose of, i 20 
 
 classification of, 119 
 
 composition of, 1 20 
 
 digestibility of, 127 
 
 proteids of, 124 
 
 salts of, 126 
 
 starchy, 124 
 
 sugar in, 123 
 Vegetarian diet, 66 
 Voit's dietary standards, 225 
 
 Waste of food, 12 
 Water, 48 
 
 in meat, 69 
 Wheat, 99 
 
 varieties of, 99 
 
 whole, 103 
 
 winter, 10 1 
 Work, external, 33 
 
 internal, 33 
 
 Yeast, kinds of, 109 
 
SEP 19 IS^O 
 
One copy del, to Cat. Div. 
 
 SEP 27