CHAPTER IVMilk as a Food

Milk is first of all the food for the young,â€”until a certain age the only food, and a perfect food. It contains but little refuse or waste and is under favorable conditions almost wholly digestible.

All foods contain certain groups of nutrients which may be classified according to various functions in nutrition and their chemical composition.

Protein.â€”The protein group of nutrients contains nitrogen and is necessary for building up the tissues of the body, the muscles and the tendons which also contain nitrogen. Only by this group can tissues wasted by constant wear and tear be rebuilt. Proteins are the flesh-forming group. To some degree the proteins or albuminoids are also active in producing fat in the body, but the other groups of nutrients, especially the fats, also contribute.

Fats and Carbohydrates.â€”Another important function of food is to produce and maintain the animal heat. The main sources of this necessity are the fats and the carbohydrates, so called because they consist of the element carbon combined with oxygen and hydrogen, the last two in the exact proportion in which they are combined in water. All of these three groups furnish the fuel, so to speak, for the body, but theyare not equal in this respect. Pound for pound, when burned in the body, the fats yield 2Â¼ times as much heat as protein or the carbohydrates.

Mineral Matters.â€”Finally there are in all foods the mineral matters, a group containing a number of salts which are indispensable because they are constituents of every part of the body. Phosphate of lime, for instance, makes up one-half of the substance of the bones, and the sulphates and chlorides of potash and soda, iron, etc., are everywhere present in smaller quantities. No food in which any of them is lacking is complete.

Relation.â€”The value of a food depends largely upon the relation of one group of nutrients to another. Proper nutrition can only be obtained when a sufficient amount of flesh-forming as well as of heat-producing nutrients are present, when the â€œnutritive ratioâ€ is properly balanced for the particular purpose in view, be it the growth of the child, the maintenance of the body, the restoration of matter consumed by labor of body or brain, or the supply of heat to make up for cold surroundings.

Milk contains allof these groups of nutrients. The protein is represented in milk by the casein and albumin, the fats by the butter-fat, the carbohydrates by milk-sugar, and the mineral matters by the milk-ash. Human milk contains them in a perfect proportion for infants, and for all purposes of nutrition cowâ€™s milk may be used to make up a â€œbalanced ration,â€ if not alone, then in connection with other food.

Nutritive Ratio.â€”As we said before, the â€œnutritive ratioâ€ of a food means the ratio of its flesh-forming constituentsâ€”proteinsâ€”to its heat-producing nutrientsâ€”carbohydrates and fats. Cowâ€™s milk, containing3.25% protein, 4% fat and 5% milk-sugar, has a nutritive ratio of 1 : 4.3, i. e., 1 part of protein to 4.3 parts of heat-giving nutrients, counting the fat equal to 2Â¼ of carbohydrates (multiplying the 4% fat by 2Â¼ makes 9, added to the 5% of sugar, makes 14; 3.25 to 14 equals 1 to 4.3). Skim milk, containing 3.4% protein, 0.2% fat, and 5.1% sugar, has a ratio of 1 : 1.6 (3.4 : 5.45). Motherâ€™s milk, containing 2% protein, 4% fat, and 6.5% carbohydrates, has a ratio of 1 : 7.75. To substitute cowâ€™s milk for motherâ€™s, it must therefore be â€œmodified.â€

Calories.â€”Another way of comparing various foods than by the nutritive ratio is by measuring their â€œfuel valueâ€ or energy-producing capacity. The amount of heat required to raise the temperature of one kilogram of water 1Â° C., or one pound 4Â° F., is called a calorie. By extensive feeding experiments the caloric value of the various nutrient groups has been estimated as follows:

Protein at 1820 calories per pound[9]Fats at 4040 calories per poundCarbohydrates at 1820 calories per pound

Protein at 1820 calories per pound[9]

Fats at 4040 calories per pound

Carbohydrates at 1820 calories per pound

Measured by this rule the fuel value of:

Compared with other food, milk, although not suited to act as the sole food of adults, is one of the best andcheapest articles of diet, and should be much more extensively used.

The following table, compiled by specialists of the U. S. Department of Agriculture, shows the quantities of various foods needed to supply as much protein or energy as 1 quart of milk:

ProteinEnergy1 quart of milk is equal toâ€”7 ounces of sirloin steak6 ounces of round steak4.3 eggs8.6 ounces of fowl1 quart of milk is equal toâ€”11.3 ounces of sirloin steak14.9 ounces of round steak9 eggs14.5 ounces of fowl

Another method of comparison is shown by the table below, in which the relative value of certain foods as economical sources of protein is given:

Milk atâ€”Is as cheap assirloin steak atâ€”Or eggs atâ€”7 cents a quart16.3 cents a pound17.6 cents a dozen8 cents a quart18.6 cents a pound20.1 cents a dozen9 cents a quart21.0 cents a pound22.6 cents a dozen10 cents a quart23.3 cents a pound25.1 cents a dozen12 cents a quart27.9 cents a pound30.2 cents a dozen15 cents a quart34.9 cents a pound37.7 cents a dozen

According to this table, if milk is selling at 10 cents a quart, sirloin steak must sell as low as 23.3 cents a pound, and eggs at 25.1 cents a dozen to supply protein at equal cost.

To Supply Energy at Equal Cost

When milk isâ€”Sirloin steakmust notbe more thanâ€”And eggs notmore thanâ€”7 cents a quart9.9 cents a pound9.3 cents a dozen8 cents a quart11.3 cents a pound10.6 cents a dozen9 cents a quart12.8 cents a pound11.9 cents a dozen10 cents a quart14.2 cents a pound13.2 cents a dozen12 cents a quart17.0 cents a pound15.9 cents a dozen15 cents a quart21.3 cents a pound19.8 cents a dozen

Fallacy of Theoretical Valuation.â€”While the contents of protein and the ratio between digestible protein and fats and carbohydrates on one hand, and the fuel or energy value on the other, have long been the only recognized measures for food values, they are admittedly quite inadequate and insufficient and although they are a great help when used with discrimination in making up food rations, they are often abused by persons who do not take their fallacies into consideration.

Dr. E. V. McCollum

â€œSomething Unknown.â€â€”Recent investigations by Dr. F. G. Hopkins, of Cambridge, England, and Dr. E. V. McCollum, formerly of Wisconsin, now of the Johns Hopkins University, have proven conclusively that one food ingredient cannot always be substituted for another with impunity even though the most searching chemical analysis shows them both alike in contents and digestibility. There is â€œSomething Unknownâ€ in certain foodsâ€”â€œVitaminesâ€ some call itâ€”essential especially in promoting thegrowth of the young, which our present knowledge of chemistry cannot explain. In Bulletin No. 17 of the Wisconsin Experiment Station experiments with the feeding of rats are described which show how butter-fat could not be replaced in the ration by vegetable fats of apparently the same composition and digestibility without disastrous results, and similar conditions have been found in regard to other foodstuffs, proteins as well as fats. The yolk of eggs and butter-fat contain this unknown something which is absolutely essential for the growth of the child and which is missing in most substitutes, especially in lard and vegetable fats.

The rat on the left got five per cent of cottonseed oil and the one on the right got instead one and a half per cent of butter-fat, otherwise their rations were alike. These results are typical for any ration made up of purified foodstuffs with butter-fat in them as compared with any fat of plant origin. The plant fats lack an unknown something without which growth cannot proceed.

The above illustration is from the work of McCollum and Davis at the Wisconsin Experiment Station.

Realizing the fallacy of the old rules for making up rations for the feeding of farm animals, Professor Evvard of Iowa is trying thereliabilityof theinstinctsof animals as a guide to the proper selection of the mostfavorable combinations and proportions of food ingredients.[10]

We mention these experiments as a warning against placing too great reliance on the caloric theory or the relation of nutrients in making up food rations. We have yet much to learn and the good housewife trying to cook according to scientific rules will do well not to neglect the palatability of the food, but to watch the â€œinstinctâ€ which causes the child or the adult to reject or approve of, and enjoy, the food, which in most cases is a better guide than calories or protein contents, or the ration between the various groups of nutrients.

If received fresh and warm from the cow, milk should at once be strained through absorbent cotton or several thicknesses of cheese-cloth into wide-mouthed bottles or glass jars and placed in running water or ice water to cool as quickly as possible. If obtained from the milkman it may be left in the bottle in which it is received. The practice of delivering milk â€œloose,â€ dipping it from the wagon, should not be permitted, and is fast being abolished. Public safety demands that it should be bottled on the farm or in the creamery or milk station under sanitary conditions.

Keep the Milk Cool.â€”If the milk when delivered at the house is not cold enough to keep sweet as long as desired, it should, we repeat, be placed in ice water or cold running water until thoroughly cooled. Even if the air is cold, in the ice box, for instance, the milk cannot be cooled quickly enough without water. After it has been cooled in water it may be put in the icebox. In most ice boxes the temperature is allowed to rise higher than is generally supposed, and it is better to keep the milk bottle next to the ice than in the food compartments.

A clean ice box

Milk and cream easily absorb flavors from the air and should not be kept in open vessels next to other food. Any housekeeper knows how quickly milk or cream will be tainted by standing in the same compartment with onions or muskmelons; if the bottle is not covered, milk may also be contaminated by other less noticeable but more harmful vapors from nearby products. Let the milkman furnish you with some extra milk bottle caps, or cover your milk bottle with an inverted tumbler.

As has been shown in previous chapters, milk is a favorable soil for all sorts of germs and bacteria to grow in. It must therefore be kept from contamination with the utmost care, and everything that comes in contact with it must be scrupulously clean.

Top-Milk.â€”When the milk has been standing at rest three or four hours, the top-milk will be considerably richer than the rest. If such rich milk is wanted for any particular purpose it may be poured off, to beeaten with cereals, berries, etc. In twelve hours most of the cream will rise and may be skimmed off, although thirty-six or even forty-eight hours may be required to get all that can be obtained by setting. The half-skimmed milk left when the top-milk has been removed after 3 to 6 hoursâ€™ setting will still contain 2% or more of butter-fat and is very good for drinking; even the skim milk from which the cream has been taken after 12 hoursâ€™ setting is still an excellent beverage, provided it is sweet. Perfectly skimmed, almost entirely fatless, milk may be used in various ways in cooking, to make up for lack of protein in many other food products. But care must be taken that it is pure and sweet, or rather, its condition, sweet or sour, must be under the perfect control of the housekeeper. If a sample of milk will stand scalding or even boiling without curdling, it is usually fresh and in good condition for any use. On the other hand, if it curdles by scalding, it is beyond control and it may or may not make good sour milk, depending on the bacteria working in it.

MILK FOR INFANTS

Comparing cowâ€™s milk with motherâ€™s milk, it will be seen that the latter contains less protein, about the same percentage of fat and more carbohydrates than the former. A comparison may be made from the following table of average composition in round figures:

Modifying Milk.â€”Undiluted cowâ€™s milk is too rich in protein and in salts for infants and, when fed without modification, must be diluted with an equal amount of water during the first two or three months. Such dilution,however, also reduces the percentage of fat, which should remain the same, and of carbohydrates, which should be increased. In order to modify or â€œhumanizeâ€ cowâ€™s milk so as to make its composition nearly the same as that of motherâ€™s milk, simple dilution with water is therefore not sufficient.

There are, however, various other methods which may be used to advantage. For instance, top-milk from a bottle of fresh milk which has stood 4 or 6 hours in ice water will contain 6 to 8% of fat. By diluting this with an equal part of water, the percentage of protein, fat and mineral matter will be about right, and sugar, either cane-sugar or milk-sugar, may be added to supply the carbohydrates. Or carefully prepared sweet whey containing milk-sugar, or barley water, may be added to the thin cream in place of some of the pure water.

The following recipes have been used with good results:

Infant Food.â€”Warm 1Â½ quarts of milk to blood heat. Remove from fire and add one Junket Tablet dissolved in a spoonful of cold water. Let the milk set until it forms a solid mass, then stir it up in order to break the curd. Place it back on the fire and stir until quite smooth, not allowing it to get any warmer than blood heat. It is then ready to strain through two thicknesses of cheese-cloth and care must be taken to squeeze well so as to obtain as much of the whey as possible, which is very important. Add one tablespoonful of sugar to sweeten. Pour into nursing bottles, the amount being according to the age of the baby. A sufficient number of bottles are prepared for 24 hoursâ€™ feeding. Care should be taken to keep the milk in a cool place as it will sour the same as fresh milk. Every time the baby is fed the milk must be warmed by placing the bottle in a pan of water and heating to the right temperature.

Mrs. Rorerâ€™s Recipe

Where cowâ€™s milk, even when diluted, or partly modified as in the home fashion, disagrees with the infant, this mixture may be used with good results: heat two quarts of milk to 100Â° F. Add two Junket Tablets dissolved in a tablespoonful of cold water. When the milk is congealed and perfectly solid draw through it backward and forward an ordinary four-tined silver fork; this will separate the curd. Strain through two thicknesses of cheese-cloth, saving the whey as this is the part you are to use; add a pint of water, a half ounce of sugar of milk, three ounces of cream and four ounces of the white of egg. The whites may be dropped into a quart fruit jar, a pint of the whey added, the top screwed on and the jar thoroughly shaken until the whites are well mixed with the whey; then add them to the remaining quantity and stand at once in a very cold place. This will be given in quantities from two to three ounces in an ordinary nursing bottle.

Formula by Dr. A. R. Green for 1st to 4th week:â€”

Â¾ ounces of 16% Cream3 ounces of Full Milk19 ounces of Water1Â½ ounces Milk Sugar

Â¾ ounces of 16% Cream

3 ounces of Full Milk

19 ounces of Water

1Â½ ounces Milk Sugar

This mixture fills 8 bottlesâ€”each to contain 3 ounces. Feed 2Â½ hours apart.

Formula by Prof. A. Jacobi for 3d to 7th month:â€”

18 ounces of Full Milk18 ounces of Barley Water1 ounces of Cane Sugar20 grains of Table Salt (less than Â¼ teaspoonful)

18 ounces of Full Milk

18 ounces of Barley Water

1 ounces of Cane Sugar

20 grains of Table Salt (less than Â¼ teaspoonful)

This mixture fills 6 bottlesâ€”each to contain 6 ounces. Feed 3 hours apart.

Formula by Prof. R. G. Freeman for 1st to 3d month:â€”

1Â½ ounces of 16% Cream3 ounces of Full Milk13 ounces of WaterÂ½ ounce Lime Water1 ounce Milk-Sugar

1Â½ ounces of 16% Cream

3 ounces of Full Milk

13 ounces of Water

Â½ ounce Lime Water

1 ounce Milk-Sugar

This mixture fills 6 bottlesâ€”each to contain 3 ounces. Feed 3 hours apart.

Formula by Dr. A. F. Hess for 7th to 9th month:â€”

22Â½ ounces of Full Milk7Â½ ounces of Oat or Barley Water1Â½ ounces of Cane Sugar30 grains of Table Salt (about Â¼ teaspoonful)

22Â½ ounces of Full Milk

7Â½ ounces of Oat or Barley Water

1Â½ ounces of Cane Sugar

30 grains of Table Salt (about Â¼ teaspoonful)

This mixture fills 5 bottlesâ€”each to contain 6 ounces. Feed 3Â½ hours apart.

Formula by Prof. R. G. Freeman for 2d to 6th month:â€”

18 ounces of Full Milk16Â½ ounces of Water1Â½ ounces of Limewater1Â½ ounces of Milk Sugar

18 ounces of Full Milk

16Â½ ounces of Water

1Â½ ounces of Limewater

1Â½ ounces of Milk Sugar

This mixture fills 6 bottlesâ€”each to contain 6 ounces. Feed 3 hours apart.

After 9th month:â€”

Full pasteurized milk, 8 ounces every 4 hours.

When the modified milk can be obtained from a dairy laboratory where it is prepared with scientific care and accuracy, it is better to use it than to depend on home-made preparations, and in many cases a doctorâ€™s prescription may be necessary. Even if the modified cowâ€™s milk is prepared so as to contain apparently the same proportion of the various groups of nutrients as motherâ€™s milk, there may still be some essential difference. For instance, the protein in human milk consists mainly of albumin, while that of cowâ€™s milk is mostly casein. It is often a question whether the individual baby can digest the casein without trouble. A trifle of rennet ferment,â€”a fraction of a Junket Tablet,â€”added to the modified cowâ€™s milk just before feeding may be beneficial to overcome that defect. A little limewater also is healthful as it neutralizes any acid that may develop in the mixture. For the particular needs of the individual baby, a competent doctor should be asked to prescribe.

MILK FOR GROWING CHILDREN

When the child is big enough to thrive on undiluted, unmodified cowâ€™s milk, it should not only be allowed, but urged, to continue on a diet in which this, the best of all foods, is the most essential part. An excellent form in which to feed milk to the growing child is junket. Eaten slowly with a spoon as a pudding, it is exposed to the action of digestion much better than milk swallowed by the glassful in a hurry and even if it is cold there is no danger of defective rennet action in the stomach because such action has already taken place.

Doctors still disagree as to the desirability of pasteurizing milk for young children (see â€œPasteurization,â€ ChapterI), some holding that the digestibility is affectedby the process. The truth is probably that strong pasteurization at a temperature above 157Â° and holding the heated milk unnecessarily long at such high temperature do change the properties of the milk so as to make it harder to digest, but that the main difficulty is in the change of diet from raw to pasteurized milk or vice versa. Let the child get used to the change by making it gradual, diminishing the amount of one and increasing the amount of the other from day to day in a week, until the change is completed, and there will usually be little if any trouble. The secretions of digestive ferments in the stomach soon adapt themselves to the change in the food. The same holds good in case of other changes, as, for instance, from whole milk to more or less fatless milk, with additions of cereals or other partial substitutes;â€”it is always advisable to make any change in the childâ€™s diet gradual.

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