• Journal of the Korean Society of Food Culture
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• v.20 no.6
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• pp.633-637
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• 2005

The effects of adding hull powders of black soybean on quality characteristics of tobu were studied. Proximate composition of the black soybean hull powders was crude ash, crude protein, crude fat, and carbohydrate at 2.60, 11.35, 2.18, and 73.97%, respectively. The addition of 5% black soybean hull powder decreased the production of whey and consequently increased the yield of tobu. Texture properties of evaluation hardness, adhesiveness, chewiness were the best in tobu which was made with 5% black soybean hull powders. Sensory evaluation showed texture, firmness were not significantly different among tobu with yellow soybean, black soybean, and added to 0.5% black soybean hull powders. At the beginning of the period of storage, there were not differences of microbial cell count as increasing black soybean hull powders, but observed after passing 5 days. The results of total microbial cell count showed that adding 5% black soybean hull powders in processing tobu extend storage time.

• Journal of the Korean Wood Science and Technology
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• v.40 no.2
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• pp.78-90
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• 2012

Soybean hull is an attractive feedstock for glucose production. To increase the glucose conversion in acid hydrolysis, a pretreatment method combined steam explosion with alkali pretreatment for soybean hull was studied. For first step pretreatment, steam explosion conditions (log Ro 2.45) were optimized to obtain maximum solid recovery and cellulose content. In the second step pretreatment, the conditions for potassium hydroxide pretreatment of steam exploded soybean hull were optimized by using RSM (response surface methodology). The optimum conditions for minimum lignin content were determined to be 0.6% potassium hydroxide concentration, $70^{\circ}C$ reaction temperature and 198 min reaction time. The predicted lignin content was 2.2% at the optimum conditions. Experimental verification of the optimum conditions gave the lignin content in similar value with the estimated value of the model. Finally, glucose conversion of pretreated soybean hull using acid hydrolysis resulted in $97.1{\pm}0.4%$. This research of two-step pretreatment was a promising method for increasing the glucose conversion in the cellulose-to-glucose process.

• Korean Journal of Organic Agriculture
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• v.19 no.4
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• pp.513-528
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• 2011

This study was conducted to evaluate the nutritional value of locally produced organic agricultural by-products to substitute imported organic feeds for organic ruminant farming. Imported organic feeds (corn grain, soybean meal, soybean seed, oat grain, barley grain, wheat grain, buckwheat, sunflower seed meal) and byproducts (rice bran, grape seed meal, rice straw, soybean hull, soybean curd, rice hull, green kernel rice, and crushed rice grain) were analyzed for chemical composition and NDF, ADF, mineral, and amino acid contents and anti-nutritional factors. Dry matter, NDF and ADF contents in organic feeds were higher than those in conventional feeds. Especially, the 9.65% fat content of organic soybean meal was 6 times higher than the 1.95% fat content of conventional soybean meal. Fat contents of rice bran, grape seed meal, green kernel rice, and crushed rice grain were 25.66, 6.09, 3.57 and 1.59%, respectively. Protein contents of soybean hull and soybean curd were 14.68 and 19.87%, respectively, which are highest among organic by-products. Levels of aflatoxin in all feeds were below the safety level. Therefore, organic rice bran, green kernel rice and crushed rice as energy source, and soybean hull and soybean curd as protein source could partial replace imported feeds for organic ruminant farming.

• Journal of the East Asian Society of Dietary Life
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• v.20 no.3
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• pp.396-401
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• 2010

The purpose of this study was the development of adsorbents for the refining of edible oil using agricultural byproducts such as rice hull, barley hull, and soybean hull as well as evaluation of their adsorptive effects against free fatty acids and lutein, the major impurities of soybean oil. Ash-type and carbon-type adsorbents were produced from the hulls. Ash-type adsorbents such as rice hull ash (RHA), barley hull ash (BHA) and soybean hull ash (SHA) were effective for the removal of free fatty acids; the acid value of degummed soybean oil was decreased by 86% upon treatment with 5% SHA. However, carbon-type adsorbents such as rice hull carbon (RHC), barley hull carbon (BHC), and soybean hull carbon (SHC) were effective for removing lutein, resulting in a 52% decrease in the lutein content of degummed soybean oil upon treatment with 5% SHC. Whereas ash-type adsorbents were composed of mesopores or macropores with small surface areas and total pore volume, carbon-type adsorbents were mainly composed of micropores with large surface areas and total pore volume.

• Korean Journal of Food Science and Technology
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• v.35 no.2
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• pp.309-315
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• 2003

Nutritional composition, contents of phenolic compounds, and antioxidative activities of small black soybean were investigated. Proximate composition of the soybean was crude fat, crude protein, carbohydrate, and crude ash at 15.9, 34.7, 38.5, and 3.7%, respectively. Potassium was the predominant mineral, followed by phosphorus, calcium, and magnesium. Glucose and galactose were the major sugars. Twelve different kinds of fatty acids were identified in whole soybean, dehulled soybean, and soybean hull. The 75% methanol and ethyl acetate extract fractions from the soybean hull contained total phenolic compounds at 4.64 and 13.53 g/100 g, respectively. The methanol extract of soybean hull showed strongest antioxidative activity among samples tested. Ethyl acetate fraction of the soybean hull exhibited DPPH radical scavenging activity at level similar to those of ${\alpha}-tocopherol$ and BHT. Phenolic compounds were the major biological components in the soybean hull. These results suggest that small black soybean can be used as a new material for functional food.

• Journal of the Korean Society of Food Science and Nutrition
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• v.26 no.2
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• pp.203-208
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• 1997

To investigate the antioxidative effect of Korean soybeans, four kinds of soybeans(yellow, brown, black and small black bean) were selected and determined their antioxidative activities in vitro by POV method. Dark colored soybeans such as brown, black and small black soybean showed stronger antioxidative effect than pale yellow one. When compared the antioxidative effect of these soybeans in hull and dehulled condition, in dehulled soybeans, they showed the same antioxidative effect in each soybeans, but in soybean hull, dark colored soybeans showed stronger antioxidative effect than yellow soybean hull, which means the pigments of soybeans play important roles in their antioxidative activities. To separate the main components showing antioxidative effect in soybeans, these soybeans were extracted with hexane, methanol and water. The methanol extract showed the strongest antioxidative effect among them, which means the major antioxidative effect materials contained in methanol extract.

• Korean Journal of Food Science and Technology
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• v.39 no.5
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• pp.588-592
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• 2007

In this study, we evaluated the recovery effects of dietary fiber extracted from soybean hulls on diarrhea in rats. Diarrhea-induced Sprague-Dawley male rats were divided randomly into 4 groups and fed experimental diets for 24 hours. The diets, based on the AIN93G diet, were as follows: CON (control diet), S-COTL (67.2 g/kg soybean cotyledon fiber diet), S-HULL (59.6g/kg soybean hull fiber diet), CHI (55.6g/kg chicory fiber diet). The results showed significant (10-20%) reductions of fecal water content in the CON and S-HULL groups, as compared to the S-COTL and CHI groups. The change in serum osmolality, a measure of dehydration symptoms, was significantly reduced in CON and S-HULL as compared to the S-COTL and CHI groups. Based on the results, it is suggested that soybean hull fiber functions well for diarrhea recovery in rats. Consequently, soybean hull fiber is an important food source that could be used as a medical food in patients suffering from diarrhea.

• Asian-Australasian Journal of Animal Sciences
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• v.19 no.8
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• pp.1164-1173
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• 2006

Cellulase from Aspergillus niger, (${\alpha}$-amylase from Bacillus sp. and protease from Bacillus globigii were used as enzyme sources in this study to examine how their respective substrates protect them in two kinds of simulated gastrointestinal tract digesting processes. Avian total digest tract simulation test showed that filter paper, Avicel and cellulose resulted in 7.7, 6.4 and 7.4 times more activity than of unprotected cellulose, respectively. Protease with addition of casein, gelatin or soybean protein showed no significant protection response. Starch protected amylase to be 2.5 times activity of the unprotected one. Monogastric animal total tract digestion simulation test showed that filter paper, Avicel and cellulose resulted in 5.9, 9.0 and 8.8 times activity of unprotected cellulase, respectively. Casein, gelatin and soybean protein resulted in 1.2, 1.3 and 2.0 times activity of unprotected protease, respectively. Starch did not protect amylase activity in monogastric animal total tract simulation. Protection of mixed enzymes by substrates in two animal total tract simulation tests showed that filter paper in combination with soybean protein resulted in 1.5 times activity of unprotected cellulose, but all substrates tested showed no significant protection effect to protease. Soybean protein and starch added at the same time protected the amylase activity to be two times of the unprotected one. Test of non-purified substrate protection in two animal total digest tract simulation showed that cellulase activity increased as BSA (bovine serum albumin) concentration increased, with the highest activity to be 1.3 times of unprotected enzyme. However, BSA showed no significant protection effect to protease. Amylase activity increased to 1.5 times as BSA added more than 1.5% (w/v). Cellulase activity increased to 1.5 times as soybean hull was added higher than 1.5%. Amylase had a significant protection response only when soybean hull added up to 2%. Protease activity was not protected by soybean hull to any significant extent.

• Korean Journal of Food Science and Technology
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• v.28 no.3
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• pp.506-513
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• 1996

Soybean hull was microparticulated at cut-off wheel speed of 9,000 rpm and air-classified into fine and coarse fraction at air classifying wheel speeds (ACWS) of 10.000, 15,000 and 20,000 rpm. respectively. Proximate analysis of the coarse and fine fractions of the microparticulated/air-classified soybean hull showed that ash, protein and lipid were enriched in the coarse fractions and carbohydrates in the fine fraction. Dietary fiber were enriched in coarse fractions and dietary fiber and dietary fiber content increased with decreasing ACWS. Mean particle size of fine fractions ranged from $3.1{\mu}m\;to\;5.5{\mu}m$ that of coarse fractions ranged from $9.9{\mu}m\;to\;20.0{\mu}m$ and both increased with decreasing ACWS. The particles were mostly oval-shaped regardless of the fractions. Generally the fraction of low ACWS showed higher viscosity. In water holding capacity, oil absorption and emulsion capacity, there was significant difference between coarse and fine fractions while there was no significant difference as a function of different ACWS. Oil absorption of flying batter was decreased significantly in the fraction of ACWS 15,000. when cakes and cooking were prepared partially substituted with soybean hull fraction, there was no significant changes on their physical and sensory properties up to 10% substitution.

• KSBB Journal
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• v.13 no.5
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• pp.599-605
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• 1998

Soybean peroxidase was extracted from soybean hulls and purified by ammonium sulfate precipitations (25% and 75% saturation), pl fractionation, and anionic exchange and gel filtration chromatographies (DEAE-Sephadex A-50 and Superose 12). Modlecular weight and pl value were estimated to be ca. 45 kD and 4.2, respectively. Purified soybean peroxidase had an RZ value of 0.43. Compared with horseradish peroxidase, it showed superior thermal and pH stability. Assuming the first-order kinetics, the thermal deactivation rate constant of soybean peroxidase at 80$^{\circ}C$ was about 8 times lower than that of horseradish peroxidase. Deactivation energy was calculated to be 69.3 kcal/mol. Soybean peroxidase showed about 10% higher H2O2 degradation capacity than horseradish peroxidase. Exploiting these advantages, the soybean peroxidase purified from the domestic soybean hull is expected to replace horseradish peroxidase in various applications.