• Journal of the Korean Society of Food Science and Nutrition
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• v.23 no.5
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• pp.837-844
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• 1994

In order to making the good quality soybean cheese, it is prepared byover growing cow's milk added soybean curd with Actinomucor elegans and the nold-overgrown curd soked in salt-brine/ethanol mixture. The physicochemical changes and sensory evaluation were investigated during the aging period. Crude protein, carbohydrate, crude fat ash contents of the pehtze were increased by elapsing the fermentation time, whereas moisture's decreased . Amino-N and ammonia -N contents of cow's milk added pehtze and soybean phetze were increased 17.25%, 7.23% and 16.16%, 8.42% respectively. Total nitrogen content of the pehtze was decreased by elaping the aging time but soaking solution's increased. Free amino acid content of soybean cheese was increased as a result of the proteolytic action of molds. As a result, sulfur containing amino acid such as methionine and cysteine of the cow's milk added soybean cheese were enriched 1.3 times more than the soybean cheese. Flavor, taste and texture of the cow's milk added soybean cheese were higher than soybean cheese.

• The Korean Journal of Food And Nutrition
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• v.31 no.6
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• pp.811-820
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• 2018

This study suggests a method of making cheese using soybeans for healthy food for people that are allergic to animal proteins, vegetarians, people on a diet, infants and toddlers. Additionally, the study was conducted to provide basic data that can contribute to the development of a quality control class of Korean cheese and underdeveloped cheese industry. Soybean cheeses have a high protein content and low fat. The free amino acids of soybean cheeses contained 11.48 mg of arginine per 100 g, 9.33 mg of glutamate, and leucine 4.91 mg, in that order. The free amino acids of Company A's milk cheese contained 20.95 mg of glutamate, 8.95 mg of proline and 8.02 mg of lysine per 100 g. In soybean cheeses, there were 2.21 mg of tryptophan and 0.73 mg of cysteine, which were not analyzed in the milk cheese of company A. The contents of the constituent amino acids was 1,070.22 mg of glutamate, 467.30 mg of aspartate and 446.30 mg of leucine in 100 grams of soybean cheeses per 100 grams. The milk cheese of Company A was 1,715.97 mg of glutamate, 798.72 mg of leucine and 685.31 mg of proline. The mineral contents of the soybean cheese were 120.29 mg/100 g of calcium, 0.92 mg/100 g of iron, 0.78 mg/100 g of zinc and 0.40 mg/100 g of selenium, respectively. The contents of vitamin $B_1$ and ${\beta}$-glucan in soybean cheese were higher than that of the milk cheese in Company A at 0.08 mg/100 g and 13.73 mg/g, respectively. Therefore, it is considered that the soy cheese is excellent in nutritional aspect and will contribute to health promotion. It is also suitable for people that are allergic to animal proteins, vegetarians, people on a diet and healthy foods for infants.

• Korean journal of food and cookery science
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• v.3 no.2
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• pp.75-80
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• 1987

For the manufacture of soybean cheese, curds were made from soy milk using either lactic starter or CaCl$_2$and ripened for 3 weeks. When papain was added during ripening, the amout of soluble protein increased. The yields of 3 soybean cheese were 76~88%, indicating that considerable loss of soy protein did not occur during the processing. During the period of ripening the change of moisture content was about 1 n. Total acidity of 3 soy cheese increased, demonstrating the production of lactic acid through lactic fermentation. Texture determined by Instron showed that 3 soy cheese had their own characteristic texture profile curve and that the cheese without papain treatment received the highest textural parameters. 3 manufactured soy cheese received 3-4 (good-very good) sensory scores in appearance, flavor and texture. General acceptibility of 3 cheese were evaluated as desirable or very desirable.

• Korean journal of food and cookery science
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• v.17 no.1
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• pp.65-79
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• 2001

The effects of ${\alpha}$-chymotrypsin and trypsin treatments on the functional properties (degree of hydrolysis, solubility, and emulsifying capacity) of the soy protein isolate prepared from Jinpum soybean milk(JS milk) which has been developed as low lipoxidase-active soybean variety in Korea and extracted from commercially defatted soybean meal milk(DSM milk). The mixing ratios of JS milk to DSM milk were adjusted to 10:0, 7:3, and 5:5, respectively. The general quality attributes(yield, pH, titrable acidity, moisture contents, crude protein contents, color, textural properties, and sensory characteristics) of soybean cheese which has been prepared with the resulting soy protein hydrolysates were evaluated. Jinpum SPI was better subjected to trypsin than ${\alpha}$-chymotrypsin hydrolyses as indicated by better solubility and emulsifying capacity of the hydrolysates. The degree of hydrolysis and solubility of Jinpum SPI were higher than the soybean isolates from DSM milk. The increased ratios of DSM milk in the mixture resulted in the reduced yields and crude protein content along with the lowered titratable acidity while the pH values and moisture contents showed the opposite trends. In color characteristics, the increased amount of DSM milk brought about the significantly lower Hunter color reflectance values of lightness of the cheese products, along with the higher redness and total color difference value(ΔE). However, the enzyme treatment alone was not enough to cause any color differences. The increased ratios of DSM milk also caused the significantly lowered textural parameters such as hardness, adhesiveness and cohesiveness of the soybean cheese. Between the enzyme treatments, the ${\alpha}$-chymotrypsin treated samples resulted in the higher hardness and cohesiveness values of the products than those from the trypsin-treated ones. In organoleptic properties of the product, the better mouthfeel and overall quality scores were obtained from the trypsin treatments as compared with those from the ${\alpha}$-chymotrypsin ones. The mixing ratios of 10:0 and 7:3 were more favored than that of 5:5 as far as mouth-feel, yellowness and overall quality of the products were concerned. On the overall, the mixing ratio of 7:3(JS milk: DSM milk) and the trypsin treatment of the mixture was recommended for better manufacturing of high-quality soybean cheese.

• Microbiology and Biotechnology Letters
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• v.9 no.3
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• pp.153-157
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• 1981

After Penicillium candidum and Actinomucor elegans were inooculated to soybean curd and incubated for 4-6 days at 10-13$^{\circ}C$, respectively, and the fresh soybean cheeses were soaked in ethanol-brine solution which was composed with 10% ethanol and 5% sodium chloride, for 16 weeks at above temperature. Total nitrogen content of soybean cheese was reduced by eloping the ripening time, but in soaking solution the content was increased. In amino nitrogen and reducing sugar of the cheese and the solution, the contents were continuously increased to the certain period, and after that time the rate was stupid. Nitrogen in the cheese inoculated with Act. elegans was highly hydrolysed and amino nitrogen and reducing sugar were much more produced than that inoculated with Pen. candidum.

• Korean Journal of Food Science and Technology
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• v.17 no.3
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• pp.213-218
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• 1985

As a way of improving the texture and flavor of soybean cheese, whey-say cheeses were made by coprecipitation of various mixtures of whey, whey powder, soy milk and soy protein powder, and mixed culture of str. lactis, str. cremoris and rennet were added, then the cheeses were cured at $15^{\circ}C$ for up to 10 weeks. Physicochemical characteristics of the cheese were investigated by analyzing pH, titratable acidity(TA), water soluble nitrogen, 10% TCA soluble nitrogen, amino acid composition, beany flavor, color and hardness. The pH of whey-soy cheeses during ripening changed from 5.3 to 4.2 after 5 or 6 weeks and maintained that value while that of soybean cheese maintained a higher pH value. TA of whey-soy milk cheeses was gradually increased to the value of 0.4-0.45 after 8 weeks, but that of soybean cheese reached only 0.2 after the same period. Water soluble and 10% TCA soluble-nitrogen increased steadily during ripening. Hardness of the whey-soy milk cheeses reached maximum after three weeks of ripening and greatest at those made from 3 : 1 mixture of whey and soy milk and that from soymilk. Color of the whey-soy milk chesses was lighter than that of soybean cheese. The bean flavor of soybean cheese was strong and persistent for the whole ripening period. Acid flavor was dominant in the whey-so milk cheese and masked the beany flavor partially.

• Korean Journal of Food Science and Technology
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• v.10 no.2
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• pp.231-236
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• 1978

It has been investigated that preparation of cheese-like product from defatted soybean milk and changes during 6 weeks' ripening. Obtained results were as follows: 1. Defatted soybean milk was fermented at $37^{\circ}C$ for 4 hours with Streptococcus lactis YUFE L-4 without addition of any other carbon sources. 2. Optimum concentration of coagulant such as $MgCl_2{\cdot}6H_2O$ and $CaCl_2$ were 0.0125M and 0.0375M, respectively. 3. Coagulating time for 30 minutes was sufficient to make curd. 4. Optimal reaction temperature for coagulating were $50^{\circ}C$. 5. After 6 weeks' ripening, moisture content was approximately $62{\sim}63%$. Water and 10%-TCA soluble nitrogen contents of soybean cheese with Asp. saitoi protease were higher than those of Mucor rennet. Water soluble nitrogen content of Asp. saitoi protease cheese was 50.5% and 10%-TCA soluble nitrogen was 27.5%.

• Journal of the Korean Society of Food Science and Nutrition
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• v.23 no.6
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• pp.973-979
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• 1994

Microorganisms, including the strain IJ-3 isolated from soil, were found to secrete an extracellular soybean protein coagulating enzyme and the strain, IJ-3 was identified as Genus Bacillus according to the Bergey's manual . The enzyme coagulated protein in soymilk , thus forming a curd at pHs 5.8-6.4 and at 55-75℃. The optimum temperature for soybean protein coagulating activity was 65-75℃ and the enzyme was stable at temperature below 50℃ and was found to be stable with about 60-100% of the original activity at a with pH ranges(pH6-7). The molecular weight of enzyme was estimated to be 28,000 by SDS-PAGE. The curd formed with the enzyme from Bacilus sp. IJ-3 has a smooth texture, and a mild taste without any bitterness or a beany flavor.

• Korean Journal of Food Science and Technology
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• v.17 no.4
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• pp.276-282
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• 1985

To characterize bitter peptides in fermented protein foods, peptides were extracted with 2:1 (v/v) chloroform-methand from various samples and separated into fractions I, II, and III by Sephadex G-25 gel chromatography. Amino acid compositions of Mozzarella cheese, soybean paste, and each fraction from the two samples were analyzed to calculate the average hydrophobicity. All the solvent extracts of the food samples had strong bitter taste, although the original samples did not taste bitter. The yield of solvent extraction ranged from 0.08 to 62.50% of total nigrogen of food samples. The average hydrophobicity calculated from the amino acid composition of Mozzarella cheese was 1376 cal/mole, solvent extract 1,623 cal/mole, gel chromatography traction I, 1,797 cal/mole, fraction II, 2,454 cal/mole, and fraction III, 1,559 cal/mole. In the case of soybean paste, the average hydrophobicity of original sample, solvent extract, gel chromatography fraction I, II, and III wre 1,229, 1,654, 1,900,998 cal/mole, respectively. The important amino acids in bitter peptides were leucine, 2016, phenylalanine, proline, and voline.

• Korean Journal of Food Science and Technology
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• v.17 no.5
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• pp.361-370
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• 1985

The effect of major ingradients (Water, Soybean oil, Na-caseinate, Soybean protein isolate, Corn starch. Lactic acid and disodium phosphate) on the textural properties of imitation cheese were studied by response surface methodology and evaluated by contour diagram. The hardness of imitation cheese was directly influenced by the contents of water, oil and Na-caseinate and also affected by the interactions between water and oil and corn starch and lactic acid/phosphate. The adhesiveness was strongly affected by the interactions between caseinate and lactic acid/phosphate, SPI and corn starch and corn starch and lactic acid/phosphate. The springiness was directly influenced by the contents of oil, caseinate and lactic acid/phosphate, and also affected by the interactions between SPI and lactic acid/phosphate and corn starch and lactic acid/phosphate. The melting property was strongly influenced by the contents and interactions of lactic acid/phosphate.