DE889819C - Process to prevent the self-oxidation of fats and oils - Google Patents

Description

Process to prevent the self-oxidation of fats and oils Fats and oils, including essential oils, are easily susceptible to oxidation in the air more or less diminishes or abolishes their usefulness. So take z. B. the When oxidized, they give off an unpleasant rancid smell and taste render them unusable for human consumption. To prevent such oxidations numerous compounds have already been proposed, e.g. B. inorganic acids, unsaturated polybasic aliphatic acids, amino acids, arylamines, phenols. The application this connection is limited. Sometimes they cause a disruptive discoloration of the material to be protected, in part they cause odor and taste Disorders, some of them are harmful to health and therefore for food and the like. not suitable. In particular, the proposed phenols for the protection of food, Medicines and the like unsuitable against self-oxidation because of their toxicity, see above also the previously proposed hydroquinone (cf. H. Oettel, Archiv für exper. Pathologie and Pharmacology, Vol. 183, S, 319 [1936]).

Well-effective means of preventing the self-oxidation of oils and fats, which are certainly harmless to health, have now been found in the alcohol esters of gallic acid. These gallic acid esters are to be assessed pharmacologically in the same way as gallic acid, which is completely non-toxic. They are well tolerated in the wild, even in large doses (cf. Beilstein's Handbook of Organic Chemistry, Vol. Zo, p. 476 [xga7]). -. The suitability of such esters for preventing the self-oxidation of fat and oil is shown by the following experiments on the behavior of peroxide formation. It is well known that the formation of peroxides initiates the self-oxidation of fats. The gallic acid esters were dissolved in the fats in the specified concentrations, and the samples were stored in open vessels in a thin layer with a large surface area with cod liver oil at room temperature in a diffuse manner. Light, in the case of peanut oil at 42 ° in the dark, and in the case of cod liver oil after 10 and 40 days, in the case of peanut oil after 10 days, the peroxide content was determined in the following manner. 0.5 cc of oil was dissolved in 10 cc of a mixture of 2 parts of glacial acetic acid and 1 part of chloroform, 1 cc of saturated aqueous iodine-potassium solution was added, the mixture was kept in the dark for 3 minutes, then 10 cc of water was added immediately and the iodine excreted with n / 500 sodium thiosulphate solution titrated. The peroxide content of the oil was determined in the same way before the experiment. The respective consumption of n / 500 sodium thiosulphate solution is referred to as the peroxide number. A. Try cod liver oil Peroxide number at the beginning of the experiment 6.7 Peroxide number according to io days i qo days added 0.05 0 / Q propyl gallate ... 8, o 8.9 0.1 0/0 - .. 8, o 8.0 0.15 ') / o - ... 7.8 7.8 o, 2 0/0 - .. 7.7 7.7 0.000 /, - ... 24.4 100.0 While without the addition of ester the peroxide number rose by 17.7 in 10 days and by 93 in 40 days, with the small addition of 0.05% ester it rose by only 1.3 in 10 days and by 2.2 in 40 days. B. Experiment with peanut oil Peroxide number at the beginning of the experiment 1.5 Peroxide number according to io days added o, oi% gallic acid methyl ester .. 2.0 0.025% -. . 1.9 0.05% - .. i, 8th 0.1 0/0 - .. 1.7 0.00 0/0 - - - 5.9 While the peroxide number rose by 4.4 in 10 days without the addition of ester, it only rose by 0.5 with the very low addition of o, oi 0/0 ester under the same test conditions, and only by o with the addition of 0.1% ester , 2 at.

Experiments with other alcohol esters led to similar results of gallic acid and other oils. As can be seen from the two examples, need oils with a strong tendency to self-oxidize, d. H. those with a high iodine number, somewhat higher Ester additives as oils with a lower iodine number, i.e. oils with a lower tendency to self-oxidation. The ester additives necessary for adequate protection against self-oxidation are depending on the composition of the fat, oil or essential oil, the storage conditions and the duration of storage o, oi to i, o 0/0.

This strong ability to prevent oil and the like from self-oxidation Like. Is closely linked to the structure of the gallic acid ester. The esters of a hydroxyl group less protocatechuic acid contained have a considerably lower preventive capacity on, a somewhat lower one, the esters of isomeric gentisic acid. Etherification too of the phenolic hydroxyl groups of the gallic acid ester leads to compounds with less ability to prevent the oils from self-oxidizing.

In this way, both the oils and the like also when mixed with other materials, such as emulsions, creams, etc., against self-oxidation protection.

Example i To protect peanut oil against self-oxidation, one dissolves therein 0.0250 / 0 ethyl gallate. Example 2 To pork fat against self-oxidation To protect it, it is mixed with 0.05% of a mixture of equal parts by weight of methyl gallate and butyl gallate.

Example 3 To protect cod liver oil against self-oxidation, one dissolves therein 0.150 / 0 propyl gallate.

Claims (1)

PATENT CLAIM: Process for preventing the self-oxidation of fats and oils, also essential ones, characterized by the addition of small amounts of alcohol esters of gallic acid alone or in mixtures with one another. -