Jams, Jellies, and Preserves.
The preparation of various fruits or fruit juices with sugar is an important industry both for domestic purposes and for commerce in the United States. When the fleshy portion of the fruit is treated with sugar sirup and boiled, it produces the product known as preserves. When a fruit is reduced to a pulp and treated with sugar sirup and boiled, it makes a product known as jam. When the fruit juice itself is treated with sugar and boiled, it forms a product known as jelly. The above are general definitions of three important classes of fruit products, though it is not intended by any means in the definitions to describe the details of preparation. These vary greatly in respect of the method of preparation, the fruit, the quantity of sugar used, the length of time the boiling is continued, and the consistency of the final product. These definitions merely outline the three distinct classes of products which are made from fruits.
Selection of the Fruit.
—In the selection of the fruit for making these sweet products it is highly important that only the very best quality should be used. The fruit should be of a proper degree of maturity, and yet not overripe. The practice of using immature, waste, or partially deformed or decayed fruit for the purposes named cannot be too strongly condemned. The great advantage of preparing these products at the home consists in the fact that the character of the material used is under the immediate supervision of the housewife. In large factories where no official inspection is exercised it is possible that any kind of fruit or any portion of the fruit may be devoted to the purpose. All deteriorated raw material should be rigidly excluded from the factory. Various fruits are utilized in different manners in the preparation of the above-named products. Large fruits with tough skins, such as apples, peaches, and pears, are pared, the cores removed, and all decayed or infected portions cut away, and the clean, fresh, fleshy portion of the fruit used for manufacturing purposes. Small fruits, such as berries, after the exclusion of all dirt, immature or imperfect samples, and the removal of the stem, are used in the whole state for the purposes named.
It would be manifestly impracticable, as a rule, to remove even the seeds of small fruits, except where jelly is to be manufactured. The fruits, having been properly prepared, are mixed with sugar or thick sugar sirup and subjected to heat for two purposes. The first purpose of heat is to sterilize completely the material so that no bacteria, germs, or spores may be left alive in the finished product. The second purpose of heating is to concentrate the material to a proper consistence and to thoroughly saturate all portions with sugar sirup. Incidentally, the heating also by the combined action of temperature and free acids in the fruit inverts a large quantity of the cane sugar that is used and thus prevents the finished product from granulating. The crystallization of the sugar in these bodies renders them very much less desirable and suitable for consumption. For this reason, among others, the precaution above mentioned, namely, that the fruit should not be overripe, should be observed. It has been seen that overripe fruit diminishes in acidity, and hence it is less suitable for converting the cane sugar than fruit just short of complete maturity. For this reason, too, the more strongly acid fruits are better suited for making these sweetened products than those in which the acidity is less strongly developed.
Jams.
—As has already been said, jams differ from jellies in that they contain not only the juice of the fruit but the whole pulp of the fruit or the whole fruit. The methods of preparation in effect produce the same changes upon the sugars that are produced by the fruit juice. The fruit after proper comminution is boiled with large quantities of sugar a sufficient length of time to reduce the fruit flesh to a pulp and to invert more or less of the sugar which is used. The insoluble matter which jam contains consists chiefly of the cellulose and pectose matter in the fruit, together with the seeds of the small fruit. The various solids are made up of the solid bodies in the fruits, including the sugars which are added. The character of the ash of the jams is a good indication whether or not they are pure, that is, made out of sugar and fruit only. While it is true that the ash of fruit varies, it is also true that the real ash of fruit has certain characteristics in regard to alkalinity which are not possessed by the ash of adulterated fruit products. For the sake of convenience and reference it is seen advisable to append a table showing the composition of the ash of some of the fresh fruits (Bulletin 66, Bureau of Chemistry).
| Fruit. | Pure Ash. | K2O. Potash. | Na2O. Soda. | Lime. | P2O5. Phos- phoric Acid. | SO3. Sul- furic Acid. | Cl. Chlorin. |
|---|---|---|---|---|---|---|---|
| Percent. | Percent. | Percent. | Percent. | Percent. | Percent. | Percent. | |
| Apple, | 0.264 | 55.21 | 11.69 | 4.79 | 12.83 | 4.62 | 0.83 |
| Apricots, | .508 | 59.36 | 10.26 | 3.17 | 13.09 | 2.63 | .45 |
| Banana, | 1.078 | 63.06 | 2.34 | .86 | 1.62 | 2.32 | 26.93 |
| Cherries, | 0.440 | 57.67 | 6.80 | 4.20 | 15.11 | 5.83 | 1.83 |
| Figs, | .682 | 57.16 | 2.38 | 10.90 | 12.76 | 3.90 | 2.05 |
| Grapes, | .500 | 50.95 | 6.32 | 4.96 | 21.27 | 4.28 | 1.54 |
| Lemons, | .526 | 48.26 | 1.76 | 24.87 | 11.09 | 2.84 | .39 |
| Oranges, | .432 | 48.94 | 2.50 | 22.71 | 12.37 | 5.25 | .92 |
| Prunes, | .486 | 63.83 | 2.65 | 4.66 | 14.08 | 2.68 | .34 |
From the above table it is seen that there is not a very large percentage of sulfuric acid in the natural ash in fruits, and very little chlorin, with the exception of the banana, in which the ash is principally potassium chlorid. Since the ash of glucose, as it is made at the present time, consists almost entirely of sulfates and chlorids, any considerable increase of these ingredients of an ash over the normal may be regarded as an indication that the fruit product from which the ash is obtained contains added glucose. Inasmuch as there are chemical and physical methods of detecting glucose which are entirely reliable, the utility of the composition of ash for this purpose is rather confirmatory than otherwise. Since the added sugar is the chief constituent of jams there is little difference in other respects in the composition of jams made from different fruits, as will be seen by the table of analysis given below:
| Description. | Total Solids. | Acidity. | Reducing Sugar. | Cane Sugar. | Total Sugar. |
|---|---|---|---|---|---|
| Jams. | Percent. | Percent. | Percent. | Percent. | Percent. |
| Apple, | 63.22 | 0.282 | 25.52 | 29.11 | 54.63 |
| Blackberry, | 55.42 | .851 | 18.77 | 29.00 | 47.77 |
| Grape, | 56.64 | .744 | 33.44 | 11.33 | 44.77 |
| Orange, | 80.52 | .433 | 13.61 | 54.23 | 67.84 |
| Pear, | 61.52 | .163 | 13.20 | 33.74 | 46.94 |
| Peach, | 65.65 | .500 | 36.48 | 23.16 | 59.64 |
| Pineapple, | 73.92 | .314 | 14.05 | 46.40 | 60.45 |
| Plum, | 50.43 | 1.012 | 28.29 | 9.70 | 37.99 |
The characteristics of fruit which give the special flavors to the jams are imparted by constituents such as ethers, essential oils, and other aromatic substances, together with the free acids which are present in such quantities as not to be susceptible of easy quantitative determination by chemical means. The relation which exists between the cane sugar and the invert sugar is not a safe index of the method of preparation, but is rather an indication of the excess or deficiency of the acid in the fruit employed. The greater the quantity of active acids, other things being equal, the larger the quantity of inverted sugar and the smaller the quantity of cane sugar in the finished product.
In the following table is given the composition of a number of jams made in the laboratory of the Bureau of Chemistry. These analyses are selected from a great many which are available because the character and amount of sugar in the composition of the jam were carefully controlled, and thus the chemical data afford a base of direct composition.
| Se- rial Num- ber. | Descrip- tion of Sample. | Total Solids. | Ash. | Total Acids Ex- pressed as H2SO4. | Pro- teids (N × 6.25). | Sugars. | Polarizations. | ||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Re- ducing sugar. | Cane sugar added. | Cane sugar found. | Cane sugar inverted. | Direct at 18° C. | Invert at 18° C. | Invert at 86° C. | |||||||||
| P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | °V. | °V. | °V. | |||||
| 20446 | Apple (fall pippin) | 63.22 | 0.20 | 0.282 | 0.175 | 25.52 | 51.31 | 29.11 | 43.22 | + | 26.3 | - | 13.0 | + | 4.8 |
| 20414 | Blackberry | 55.42 | .48 | .851 | .737 | 18.77 | 43.99 | 29.00 | 34.08 | + | 24.6 | - | 14.6 | + | 1.6 |
| 20445 | Grape (fox) | 61.80 | .19 | .698 | .200 | 50.06 | 54.21 | 3.70 | 92.96 | - | 9.0 | - | 14.0 | + | 2.2 |
| 20416 | Grape (Ives seedling) | 56.64 | .48 | .744 | .525 | 33.44 | 42.45 | 11.33 | 73.38 | + | 3.5 | - | 11.8 | 0 | |
| 20443 | Orange (Florida navel) | 80.52 | .44 | .433 | .944 | 13.61 | 69.13 | 54.23 | 21.55 | + | 55.9 | - | 17.5 | + | 2.0 |
| 20448 | Pear (Bartlett) | 61.52 | .28 | .163 | .312 | 13.20 | 46.52 | 33.74 | 18.87 | + | 32.3 | - | 13.2 | + | 1.0 |
| 20442 | Pineapple | 73.92 | .30 | .315 | .312 | 14.05 | 60.20 | 46.40 | 22.90 | + | 52.3 | - | 10.3 | + | 6.2 |
| 20421 | Plum (damson) | 50.43 | .54 | 1.102 | .525 | 28.29 | 37.75 | 9.70 | 74.42 | + | 3.1 | - | 10.0 | + | 1.2 |
| 20423 | Plum (wild fox) | 62.10 | .46 | 1.355 | .212 | 28.78 | 47.86 | 23.26 | 53.43 | + | 13.9 | - | 17.5 | 0 | |
The following table represents the data relating to the composition of jams from samples purchased in the open market, free from glucose and apparently pure:
| Description. | Total Solids. | Acidity. | Reducing Sugar. | Cane Sugar. | Total Sugar. |
|---|---|---|---|---|---|
| Percent. | Percent. | Percent. | Percent. | Percent. | |
| Apricots, | 70.15 | .407 | 38.96 | 26.00 | 64.96 |
| Currants, | 66.32 | 1.117 | 52.45 | 1.64 | 54.09 |
| Figs, | 69.89 | .744 | .... | 45.92 | .... |
| Grape fruit, | 69.20 | .387 | 27.00 | 35.51 | 62.51 |
| Guava, | 82.46 | .299 | 25.14 | 52.73 | 77.87 |
| Peach, | 65.65 | .500 | 36.48 | 23.16 | 59.64 |
| Strawberries, | 75.83 | .480 | 37.15 | 31.43 | 68.58 |
The average composition of a large number of pure jams, some of which were made in the laboratory and some purchased in the open market, is as follows:
| Total Solids. | Acidity. | Reducing Sugar. | Cane Sugar. | Total Sugar. | |
|---|---|---|---|---|---|
| Percent. | Percent. | Percent. | Percent. | Percent. | |
| Average, | 65.98 | .536 | 36.41 | 22.15 | 58.56 |
| Maximum, | 82.46 | 1.355 | 61.02 | 54.23 | .... |
| Minimum, | 50.43 | .163 | 13.20 | .30 | .... |
The analytical data show that the jams, in so far as active food constituents are concerned, are composed chiefly of sugar. These sugars include both that natural to the fruit and that which has been added. The average content of sugar in round numbers is 58.5 percent, while in round numbers the average content of solids, not sugar, is 7.5 percent. It is thus seen that the amount of sugar present in round numbers is eight times as great as that of the other solids. It is also noticed that the percentage of reducing sugar is about one-third greater than the cane sugar, indicating that the inversion of the sugar, when the real fruits have been used in the manufacture, has been carried to such an extent as to avoid any danger of crystallization. These data are all in complete refutation of the claims made by many manufacturers that it is necessary to add glucose in the manufacture of complex products of this kind in order to prevent crystallization. If the real fruit is used in the proper quantity and the manufacture conducted according to the approved method, there is no danger of crystallization except in those rare cases where the fruits used have little or no acid.
Adulteration of Jams.
—The adulterations of jams are practically the same as those which are practiced with jellies. Artificial colors have been very extensively used together with the artificial flavors resembling the fruits, the names of which appear erroneously upon the packages. Glucose is used to a large extent in these adulterated goods. In the adulterated articles a preservative is nearly always present. Starch is used but very rarely for adulterating articles of this kind.
Fifty-eight samples of jams which proved to be adulterated were bought on the open market by the Bureau of Chemistry, none of which bore any label or description indicating that it was an adulterated article. The character of the principal adulterant (glucose) in each case is revealed at once by the polarization, which is always strongly right-handed, and also by other chemical tests for glucose. The quantity of sulfate and chlorid in the ash of these samples is always very considerably increased over that of the natural product. The quantity of glucose in some of the samples is so great as to indicate that practically the whole of the solid matter is composed of this substance. In two samples the alleged jam contained no fruit product whatever. In many cases more than 70 percent of glucose is found and in one instance as high as 76 percent. In a great majority of the cases the glucose is approximately one-half of the whole weight of the jam. In a great many cases the glucose was present in quantities which indicated the utilization of some fruit product. There were a few cases where the amount of glucose fell below 10 percent. Artificial coloring matter was present in almost every case, and in the great majority of cases either benzoic acid or salicylic acid is present as a preservative. The colors used are coal tar dyes and cochineal.
It is evident that articles of food adulterated in this manner should not be permitted to bear the name of the natural product, and in many of the states the local laws forbid the use of a misleading name. The national law, which was approved on the 30th of June, 1906, also forbids misbranding of this description.
In addition to the jams which on their labels bore no indication of the adulterations, a number of samples of jam were purchased labeled “Compound,” or in some way indicating that they were not the pure article. Thirteen samples of this kind were examined in the Bureau of Chemistry and all of them had very large quantities of glucose, the largest amount present in any one case being 37 percent. They were all artificially colored, and ten of them contained preservatives, either benzoic or salicylic acid.
Jellies.
—In addition to the jellies which were made in the laboratory of the Bureau of Chemistry for the purpose of controlling the manufacture, 44 samples of jelly were bought upon the open market. Of these commercial samples 19 contained no glucose, 13 of them contained glucose, but were not so labeled, and 12 were labeled as compound or adulterated articles. Nearly all of the commercial jellies were made with apple jelly as the base. The apple jelly and glucose made up practically the total solids, no matter what name was applied. The flavors were artificial, and a very large number of the samples contained preservatives. The samples of jelly which contained no glucose were evidently made of the natural fruit,—they contained no artificial coloring matter and in only a few instances did they contain preservatives. On the other hand the jellies which were made of glucose were uniformly colored and contained preservatives.
It is of interest here to say a few words about the very cheapest of adulterated jellies which are found upon the market. These jellies were made with some apple juice, but chiefly of glucose. They contained large quantities of preservatives, and the ash was rich in sulfates and chlorids except in two instances. In these cases it is possible that the glucose which was used was manufactured by some special process not involving the use of either sulfuric or hydrochloric acid.
Adulteration of Jelly.
—Jellies are of the class of fruit products which have been extensively adulterated. The markets of the country have been flooded for years with so-called “compound jellies” or imitations of jelly. The chief forms of adulteration are the following: The use of apple stock for making all kinds of jelly. Attention has already been called to the fact that apples contain a large number of pectose bodies which favor jellification. A common method of manufacturing jelly has been to use a stock of apple juice or cider or a preparation made from the cores, skins, and rejected portions of the apple at evaporating factories or from whole rejected apples. This stock is used as a common base for the manufacture of jellies of different kinds. Whenever apple juice enters into the composition of a jelly made from any other fruit than the apple it becomes an adulteration. Apple juice is not an adulteration in the sense of being an injury to health, but in the sense of being substituted for other fruit juices.
Artificial Coloring.
—In as much as each kind of fruit tends to give to a jelly a particular color, it is evident that if apple stock is used the natural colors of the other fruits must be imitated.
To this end coal tar dyes have been generally employed, and sometimes vegetable or animal coloring matter to imitate the color of the fruit whose name is given to the product.
Artificial Flavors.
—Since when apple stock is used as a base of manufacture it imparts to the finished product only the flavor of apples, artificial chemical flavors resembling other fruits are employed. Thus the jellies which, presumably, are made from other fruits, have the particular flavor of those fruits imitated in a wholly artificial way.
Composition of Jelly.
—The properties of a jelly, in respect of its distinct character, are due solely to the fruit from which it is made. Each one of the fruits contains essential oils, ethereal substances, acids, etc., which give to it a distinct character. These bodies are carried with the fruit juice into the finished product and give to it its distinct characteristics. The sugar, of course, in all these products is the same. In the following table are found the data showing the composition of jellies made from different fruits in the Bureau of Chemistry.
COMPOSITION OF JELLY.
| Se- rial Num- ber. | Descrip- tion of Sample. | Total Solids. | Ash. | Total Acids Ex- pressed as H2SO4. | Pro- teids (N × 6.25). | Sugars. | Polarizations. | ||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Re- ducing Sugars. | Cane sugar added. | Cane sugar found. | Cane sugar inverted. | Direct at 18° C. | Invert at 18° C. | Invert at 86° C. | |||||||||
| P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | P. ct. | °V. | °V. | °V. | |||||
| 20408 | Apple (fall pippin) | 59.18 | 0.22 | 0.279 | 0.175 | 20.78 | 51.76 | 33.04 | 36.17 | + | 24.0 | - | 20.6 | - | 1.2 |
| 20405 | Blackberry | 59.63 | .33 | .475 | .243 | 12.51 | 54.89 | 44.90 | 18.20 | + | 47.0 | - | 20.1 | 0 | |
| 20410 | Crab apple | 63.28 | .11 | .171 | .137 | 34.93 | 57.61 | 23.68 | 58.88 | + | 13.0 | - | 19.0 | 0 | |
| 20405 | Grape (Ives seedling) | 63.66 | .45 | .524 | .175 | 32.29 | 60.29 | 30.52 | 49.33 | + | 22.3 | - | 18.9 | + | .2 |
| 20412 | Huckleberry | 63.02 | .28 | .245 | .069 | 24.27 | 53.39 | 32.74 | 37.54 | + | 24.1 | - | 20.1 | - | .4 |
| 20435 | Orange (Florida navel) | 68.56 | .30 | .171 | .418 | 3.95 | 65.59 | 62.52 | 4.91 | + | 61.3 | - | 23.1 | - | .2 |
| 20437 | Peach | 69.98 | .21 | .245 | .175 | 8.75 | 63.70 | 56.59 | 11.16 | + | 53.4 | - | 23.0 | - | .6 |
| 20434 | Pear (Bartlett) | 69.12 | .34 | .181 | .156 | 6.58 | 63.09 | 58.46 | 7.33 | + | 52.7 | - | 26.2 | - | 1.8 |
| 20436 | Pineapple | 80.28 | .43 | .328 | .387 | 22.13 | 72.98 | 56.70 | 28.45 | + | 50.4 | - | 26.1 | 0 | |
| 20433 | Pineapple husk | 76.34 | .73 | .352 | .350 | 7.40 | 70.22 | 65.22 | 7.12 | + | 63.7 | - | 24.3 | - | .6 |
| 20404 | Plum (damson) | 45.56 | .68 | 1.127 | .350 | 19.18 | 38.00 | 22.67 | 40.38 | + | 17.8 | - | 12.8 | 0 | |
| 20409 | Plum (wild fox) | 54.49 | .40 | 1.029 | .138 | 24.00 | 48.05 | 25.48 | 46.97 | + | 16.7 | - | 17.8 | 0 | |
| 20411 | Plum (wild fox), boiled down | 73.01 | .65 | 1.529 | .175 | 44.22 | 64.66 | 22.37 | 66.18 | + | 7.6 | - | 22.6 | - | .6 |
| 20407 | Mixed fruit | 66.58 | .21 | .367 | .069 | 39.70 | 59.72 | 24.22 | 40.38 | + | 14.8 | - | 17.9 | + | 2.2 |
As is to be expected the chief constituent of these jellies is the sugar which is derived both from the sugar present in the natural juice and from that added in the manufacture. The data show that the quantity of cane sugar inverted varies greatly with the different fruits. Some of the fruit juices appear to have little or no effect whatever in the inversion of sugar. This is particularly true of the orange, the pear, and the jelly made from the husks of pineapples.
Manufacture of Jellies.
—In the manufacture of jellies the fruit juices are separated from the pulpy mass of the fruit, and these alone are used in the process. The most common method of procedure is to boil the fruit with more or less water until the juices are more or less separated and then to remove them by straining or pressure. The fruits are heated for this purpose with sufficient water to prevent scorching until they are thoroughly softened and then reduced to a pulp. The best jellies are made from juices which are obtained by simply allowing the pulpy mass to drain through cloth. The juices thus obtained are clear and free of any suspended matter. When pressure is used the juices are less clear and contain more or less suspended solid matter. In the preparation of jellies approximately equal portions of pure cane sugar and the strained juices are used, and the mixture is heated to the boiling point. It is evident that in the manufacture of jelly where boiling is not continued for any length of time the amount of sugar inverted is less than in the manufacture of jams and preserves where the boiling is continued for a greater length of time.
The quantity of non-crystallizing material in the juices from which the jellies are made, namely, the pectose bodies in fruits, is sufficient in most cases to prevent the crystallization of the cane sugar in the jelly. The jelly is formed by these pectose bodies being present in the juice in sufficient quantities to become semi-solid on cooling after manufacture. The solidifying may take place in a short time or only after several hours. The juice at the time of completion of the boiling is thoroughly sterilized, and in this hot condition should be placed in sterilized vessels and covered before setting away with sterilized parchment paper or a thin film of sterilized paraffine. The covering of the surface will prevent the deposition of the seed of moulds and bacteria which often infect the top layer of jellies or other fruit products prepared in a similar manner whose surface is not properly protected.
Preservatives.
—Since the care which is necessary to prepare a jelly in a thoroughly sterilized condition and to protect the exposed surface so that infection thereof cannot take place is a matter of expense and requires great attention to details, it has been sought to avoid these by the use of chemical preservatives. Salicylic acid and benzoic acid or benzoate of soda have been the principal preservatives employed, and until state and municipal laws introduced a proper inspection or analysis of these products the use of these chemical preservatives was very common. In later years their use has been gradually diminished, owing to the objections on the part of the laws and the public to the presence of these bodies in the finished products. There are, however, still on the market many products which are preserved by salicylic acid, benzoic acid, or benzoate of soda or some similar active agent.
From the above résumé it is seen that the consumer who buys in the open market is not quite certain that he is getting the product for which he pays. This condition of affairs will doubtless pass away with the advent of the proper inspection of fruits which are used in manufacturing on a large scale and a proper supervision of the manufacturing establishments, together with a rigid execution of the national and state food laws. Under such conditions the adulterations will either disappear from the market or be so labeled as to practically inform the purchaser of their character.
Marmalade.
—The term “marmalade” is applied to a special character of fruit product prepared in the same manner as jam in which the fruit is not so thoroughly pulped. The orange is a fruit which is used very extensively for making marmalade,—an orange marmalade, in other words, is only a fruit product of the character of jam and made after the same manner. This class of fruit products is so nearly the same as jam as not to need any special description.
Adulteration.
—The adulterations to which the marmalades are subjected are practically the same as for jams. In the study of marmalade in the Bureau of Chemistry 96 samples were examined. Of this number 86 were commercial products and 10 were prepared in the laboratory of the Bureau. Of the commercial articles 18 samples, somewhat less than 20 percent, contained no glucose. Fifty-three contained glucose, but were not so labeled, and 15 were labeled as compound or artificial. The percentage of solids in these products varied within a wide limit. The maximum percentage of solids found was 82.46 and the minimum 53.43. The average percentage of ash in the marmalade not containing glucose was 0.32, and the average alkalinity of the ash as measured by a standard acid was 0.26. In the adulterated marmalade containing glucose the average percentage of ash was 0.59, almost as great as in the pure article, and the average alkalinity was 0.29, somewhat greater than in the pure article.
Compound Jams and Jellies.
—A word should be said respecting the meaning of the word “compound” as attached to fruit products, especially jams and jellies, since it is a word which has been selected as somewhat more euphonious than the term “adulterated” or “misbranded.” So true is this that the word “compound” when placed upon a food product indicates at once to the purchaser that the article is a mixture or substitute. The term, therefore, indicates the character of sophistication. To such an extent may this be practiced that the actual material named in connection with the word “compound” may be absent from the mixture altogether. The term arose first on account of the desire of the manufacturer to leave off of the labels a statement of the exact composition of the contents of the package and to substitute a word of less significance, and at the same time to comply with certain state laws which require that all fruit products containing glucose be labeled with the word “compound” or some similar term. A much simpler and more direct method would be to make the label a truthful one, indicating, as nearly as possible, the character of the product. A compound generally means a jelly or jam made without the fruit named, that is, largely of glucose. It also indicates, as a rule, that the product is artificially colored and artificially flavored. In these cases the word “imitation” is to be preferred, inasmuch as the mixtures bearing the word “compound” can only be regarded in reality as a mixture of unlike substances.
General Conclusions.
—In regard to fruit products made by boiling with sugar, the general statement that they should be true to name and free from artificial colors, preservatives, or other adulterations apparently covers the whole ground. If it is desired to make a cheaper article for the benefit of consumers of small means, the principles which should guide the manufacturers are plain. The materials which are added should be wholesome and free of deleterious or injurious matter. The poor man, while entitled to get a cheaper article, is likewise entitled, as well as the rich man, to protection against deleterious substances. In the present state of our knowledge, glucose is not regarded by the majority of hygienists as a substance injurious to health. If it be injurious it is due more to a lack of care in manufacture than to any inherent properties. Pure glucose, being simply a hydrolyzed production of starch, cannot be regarded as a substance injurious to health. The objections to glucose which have been legitimately made are due to the fact that the acids which have been used in converting the starch and also the sulfurous acid which has been used in bleaching the product have not been entirely removed. It appears that the glucose used for food purposes can be freed from all objection by inverting the starch with which it is made with diastase and avoiding the use of all bleaching reagents. The glucose thus made would not be water-white, nor is it desirable for edible purposes that it be so, since it is always, except, perhaps, in the manufacture of certain candies, used in connection with naturally colored food products. There is no reason to believe that a glucose made as above and possessing, as it naturally would, an amber or reddish color would be made less desirable than a product which is absolutely colorless. This suggestion, therefore, is made to the manufacturer of glucose for edible purposes in the interest of public health and to avoid any possible condemnation of the glucose by reason of the method of manufacture, namely, that the use of acid in the manufacture of glucose be discontinued, that malt or some other form of diastase be substituted and that bleaching, except by passing through animal charcoal, be entirely omitted. The product made in this way would be free from the objections which have been, and may in the future still be, urged with reason against the use of the article at the present time.
Preserves.
—The term “preserves” is a general one which is applied in common language to a preparation of fruit preserved by boiling with sugar until complete sterilization is accomplished. The term in its general application includes the different varieties of preserves which have already been mentioned, namely, jams, marmalades, etc. It must also be extended to include the class of fruit products known as jellies, though, as a rule, it is not made so comprehensive in meaning, inasmuch as the jelly does not contain any of the solid particles of fruit. Perhaps there is no other part of the food-manufacturing industry which is so universally practiced in the household as the manufacture of preserves. Not only is this true of farm life in the country but also of those living in the city. The sterilization of fresh fruit without the use of sugar is not nearly so common as the making of the domestic supply of preserved fruits in the sense above mentioned. There is only one sufficient reason for the preparation of such foods, namely, the suspicion which attaches to the manufactured article appearing upon the market. So universal has been the custom of artificially coloring the product, and of the use of glucose and preservatives, as to create a general impression among consumers that the articles thus purchased in the open market are adulterated and misbranded. When these preparations are made in the household we are at least assured of the genuineness of the product. It must be admitted that the art and technique of manufacture cannot possibly be so perfect in the home as in the large factories. It follows as a necessary consequence that such goods as those indicated ought to be better and cheaper and more readily preserved if made in large manufacturing centers than when made at home. Even those who make the genuine product suffer in common with those who make adulterated articles, since the suspicion of adulteration attaches to the whole output. The practice of domestic manufacture will undoubtedly continue until the public is fully convinced that better and cheaper articles can be purchased in the open market.
Peach Preserves.
—A common practice among the housewives throughout the United States is to boil peaches with sugar or sugar sirup, forming the well known product, peach preserves. Preserves of this kind are considered a delicacy, and, as they are easily made and kept, they are a very common article of diet throughout all parts of the country where peaches are grown.
Fruit Butter.
—There are several preparations of fruit which differ in some respect from those just mentioned, to which the term “butter” has been applied, such as apple butter, peach butter, etc., and these are common articles of domestic manufacture. This type of article is illustrated by a description of apple butter.
Apple butter is made by boiling comminuted, sound, carefully selected apples of a proper degree of maturity with cider until the whole mass forms a bulk of the proper consistence. The preparation thus made is treated with certain spices according to the desire of the manufacturer and the taste of the consumer. There is quite a quantity of material insoluble in water in genuine fruit butter. The rest consists of water, the added sugar, if any, and the fruit juice with which the butter is made.
Adulteration of Fruit Butter.
—Very extensive adulterations are practiced with fruit butter offered in the open market. In the Bureau of Chemistry as high as 30 percent of glucose has been found as an added product. The addition of cane sugar cannot be regarded as an adulteration but the best fruit butters are made without it. Artificial colors are sometimes used, and preservatives, especially benzoic acid, are quite common in the commercial article.
Brandied Fruit.
—The use of brandy in common with sugar in the preservation of fruit is widely practiced. Sometimes alcohol alone is relied upon as a preserving agent. At other times greater or less quantities of cane sugar are used. Usually heat is employed in addition to the other preserving agents to complete sterilization. Nearly all forms of fruit may be preserved in this way. Brandied cherries and peaches are perhaps the most abundant. The quantity of alcohol employed varies between 15 and 20 percent of the total weight of the goods. The quantity of cane sugar used has been found to range from six to 20 percent of the weight of the fruit. Fruit preserved in this way cannot be regarded in the light of food solely, but only as a condimental substance. The eating of any large quantity of food containing that percentage of alcohol could not be accomplished without danger of intoxication. The utilization of such foods upon the table should be of a restricted character, and, especially, they should not be used with children or very young people where the danger from the direct effects of the alcohol is magnified and the possibility of forming the alcohol habit is also present.
Adulteration of Brandied Fruits.
—The principal adulteration of brandied fruit is in the use of alcohol which is not genuine brandy. It is well known that much of the brandy offered in commerce is fictitious, that is, is not the pure distilled alcoholic product from sound wine properly aged in wood before using. When brandy is purchased for preserved fruit, unless special care is taken to secure the genuine article the imitation article may be supplied. Instead of the real brandy the manufacturers may use an article which is entirely devoid of any product of the distillation of wine or containing only a small amount thereof. The term “brandy” used with the fruit in such a case is a misnomer and the article would be deemed misbranded under the provisions of the law. The manufacturer can assure himself of the purity of the brandy by obtaining it from a bonded warehouse, since it is made under the supervision of the officials of the internal revenue and kept under such supervision until delivered to the consumer. Inasmuch as preparations of this kind are regarded as delicacies and the cost of the product does not enter materially into consideration it is highly advisable that only genuine brandy, distilled from sound wine and aged in wood for a period of not less than four years, be employed in the manufacture.
Importance of the Canning and Preserving Industries.
—The statistics for the canning and preserving industries for the calendar year ending December 31, 1904, form a part of the census of manufactures, which is made in conformity with the act of Congress of March 6, 1902, and are compared with similar statistics for the census of 1900, which covered the fiscal year ending May 31st.
There has been a large increase in those industries. The slight decrease in the average number of wage-earners is more apparent than real, and is due largely to the fact that a considerable number were employed in fish canneries under a contract system. The contractor furnishes the laborers and is paid for an agreed quantity of product. The establishment reporting has no record of the number employed by the contractors, and they were not included in the number reported, the amount paid for such contract work being included in the item of miscellaneous expenses. Fishermen were not included in the census, and it is possible that a larger proportion of the salted fish was prepared in connection with the actual catch than at the census of 1900, thus accounting in part, at least, for the decrease in the quantity.
CANNING AND PRESERVING FRUITS AND VEGETABLES, AND FISH AND OYSTERS.
| Comparative summary—Censuses of 1904 and 1900. | ||||
|---|---|---|---|---|
| 1904. | 1900. | Percent of Increase. | ||
| Number of establishments, | 2,687 | 2,182 | 23.1 | |
| Capital, | $69,589,316 | $47,970,787 | 45.1 | |
| Salaried officials, clerks, etc.: | ||||
| Number, | 3,604 | 2,418 | 49.0 | |
| Salaries, | $3,216,773 | $1,926,639 | 67.0 | |
| Wage-earners: | ||||
| Average number, | 50,258 | 51,955 | 3.3 | [35] |
| Wages, | $14,154,730 | $12,759,459 | 10.9 | |
| Miscellaneous expenses, | 8,544,497 | 3,290,459 | 159.7 | |
| Materials used, | 69,814,330 | 52,243,948 | 33.6 | |
| Products:[36] | ||||
| Aggregate value, | $107,534,464 | $81,020,384 | 32.7 | |
| Fruits and Vegetables— | ||||
| Total value, | $72,570,974 | $44,460,665 | 63.2 | |
| Canned Vegetables— | ||||
| Pounds, | 1,672,759,438 | 1,142,327,265 | 46.4 | |
| Value, | $45,262,148 | $28,734,598 | 57.5 | |
| Canned Fruits— | ||||
| Pounds, | 295,760,355 | 293,637,273 | .7 | |
| Value, | $11,644,042 | $11,311,062 | 2.9 | |
| Dried Fruits— | ||||
| Pounds, | 343,579,623 | 81,189,406 | 323.2 | |
| Value, | $15,664,784 | $4,415,005 | 254.8 | |
| Fish— | ||||
| Total value, | $24,452,533 | $20,542,691 | 19.0 | |
| Canned— | ||||
| Pounds, | 259,469,861 | 167,836,808 | 54.6 | |
| Value, | $15,966,513 | $14,308,723 | 11.6 | |
| Smoked— | ||||
| Pounds, | 35,439,619 | 21,252,066 | 66.8 | |
| Value, | $2,362,740 | $973,041 | 142.8 | |
| Salted— | ||||
| Pounds, | 112,156,655 | 125,669,131 | 10.8 | [35] |
| Value, | $6,123,280 | $5,260,927 | 16.4 | |
| Oysters— | ||||
| Value, | $3,799,412 | 2,054,800 | 84.9 | |
| All other products, | 6,711,545 | $13,962,228 | 51.9 | [35] |
[35] Decrease.
[36] Exclusive of fruits and vegetables valued at $715,920, fish at $274,403, and oysters at $12,900, manufactured by establishments classified as food preparations, pickles, preserves and sauces, slaughtering and meat packing, wholesale, etc.
Importance of the Industry.
—The importance of the canning industry is not to be measured solely by its commercial extent. The principle of the conservation of food products by sterilization or pasteurization is of immense significance in the nutrition of man. It enables nourishing foods of a perishable character to be kept and transported to great distances and to be used in localities where fresh foods of similar kinds are otherwise unobtainable. Such preserved foods mean everything to pioneers, explorers, armies, and navies. The “winning of the west” in the United States has been marked by the débris of the rusty cans. The roads along which the pioneers who settled the great American desert marched since 1865 have been bordered with the discarded packages in which they carried their foods.
It is doubtless true that foods when they can be had fresh are to be preferred to those which have been sterilized. It is also true that many unsterilized foods from unsanitary environments are more dangerous in the fresh state than when they have been exposed to a high temperature. Taking into consideration all the circumstances in the case, it must be conceded that the process of sterilization, first practiced by Appert and afterward placed on a scientific basis by Pasteur, has proved of almost immeasurable advantage to mankind. Thus for this greater reason the character and quality of foods thus preserved should be wholly above suspicion, and no adulteration or sophistication of any kind should be practiced therewith. The manufacturer is quite as much interested as the consumer in placing the whole output of sterilized foods on a plane above suspicion.