• Applied Biological Chemistry
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• v.34 no.3
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• pp.242-248
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• 1991

The sucrose, MSG, fresh oyster and salted-fermented anchovy and shirmp were added into Kimchi in the concentration range of $1{\sim}3%$ and studied for their effects on the changes in chemicl properties and fermentation rate. The control Kimchi was prepared with addition of 2% red pepper, garlic, Welsh onion and 1% ginger. It was found that the fermentation rate was increased as the concentration of all of ingradients tested increased. Among them M.S.G affected most significantly. However, ascorbic acid formed was reduced for those Kimchi added with salted-fermented anchovy and shrimp while the changes in pH and titrable acidity was affected a little.

• Applied Biological Chemistry
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• v.39 no.5
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• pp.398-402
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• 1996

This study was carried out to compare the fermentation rates of Dongchimi as affected by fermentation temperature and salt concentration of brining solution. The Dongchimi was prepared by fermentation of the radish in salt solutions of 2.0, 3.2 and 5.1% NaCl respectively with addition of garlic, green onion, ginger at $4^{\circ}C,\;10^{\circ}C,\;20^{\circ}C$. The fermentation was classified into 3 steps of initial, intermediate and final stages according to pH changes and the rates of fermentation and color change were calculated from intermediate stage. The time reached equilibrium in hardness of radish and salt concentration and their equilibrated values were also compared. Fermentation rate became more rapid as fermentation temperature and salt concentration increased. The rates of Hunter color change of Dongchimi liquid were increased as the temperature increased. The 'L' values decreased slowly, and 'a' and 'b' values increased rapidly to maximum at the intermediate stage. The time required to reach equilibrium was reduced for both salt concentration and hardness of radish as the fermentation temperature increased. The equilibrated values of salt concentration were increased while those of hardness of radish were decreased as the temperature and salt concentration increased. The data obtained can be used for prediction of some of the major characteristics of Dongchimi during fermentation.

• Journal of the Korean Society of Food Science and Nutrition
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• v.29 no.6
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• pp.1062-1067
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• 2000

상품성이 떨어지는 감자의 효율적 활용을 위하여 감자식포 제조공정을 반응표면분석에 의해 최적화하였다. 품질이 일정하고 단기간에 대량생산이 가능한 발효조건을 확립하기 위하여 반응표면분석으로 식초 제조조건 설정을 위해 알콜 발효와 초산발효 2단계로 구분하여 모니터링하였다. 그 결과 1단계 알콜발효에서 알콜함량이 최대치를 나타내는 조건은 감자에 대한 백분율로 첨가한 가수량 241.35%(v/w), 교반속도 8.05 rpm 및 발효시간 34.81 hr으로 나타났다. 알콜발효에서 알콜함량에 대한 최적조건으로 알콜발효 후 2단계로 초산발효를 행하여 초산발효조건을 예측하였다. 그 결과 총산이 최대치를 나타내는 조건은 교반속도 169.89 rpm 및 발효시간 285.12 hr로 나타났다. 최적조건에서 예측된 알콜발효 및 초산발효의 결과는 최적조건에서 실제 발효를 행한 결과와 유사하였다.

• KSBB Journal
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• v.4 no.3
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• pp.253-258
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• 1989

It was investigated that the influent sugar concentration and the dilution rate have an influence on the ethanol fermentation characteristics at steady state in a chemostat culture of K. fragilis using Jerusalem Artichoke juice as substrate. And also the optimum condition of high ethanol productivity and low residual sugar output in the ethanol production by K. fragilis, was clarified to be given at a dilution rate of 0.22/hr and at an influent sugar concentration of 85g/l.

• Korean Journal of Food Science and Technology
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• v.30 no.5
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• pp.1203-1208
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• 1998

To utilize astringent persimmon (Diospyros kaki, T.) effectively, response surface methodology (RSM) was applied to optimize and monitor the vinegar fermentation conditions by two stage fermentation. In the first stage, the fermentation conditions for maximum alcohol content was $20.51\;^{\circ}brix$ in sugar concentration of astringent persimmon, 139.52 rpm in agitation rate, and 94.88 hr in fermentation time. When sugar concentration of astringent persimmon was $14\;^{\circ}brix$, maximum alcohol content predicted by response surface methodology was 7.1% at agitation rate of 40 rpm and fermentation time of 120 hr. In the second stage, the fermentation conditions for maximum acidity was 224.40 rpm in agitation rate, 176.07 hr in fermentation time. Alcohol content and acidity predicted at the optimum conditions were similar to experimental values.

• Proceedings of the Korean Society for Applied Microbiology Conference
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• 1986.12a
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• pp.531.1-531
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• 1986

L. acidophilus를 대두유에 젖산발효 시킬 때 단독배양과 효모인 K. fragilis와의 혼합배양에 대하여 검토하였다. 젖산의 생성량은 젖산균 단독배양보다는 효모와 혼합배양 하는 것이 2.6배나 많았으며 L. acidophilus를 단독배양 하였을 경우 균의 생육속도와 PH 강하속도는 K. fragilis를 단독배양한 것에 비교하여 늦었다. 그러나 혼합배양 함으로써 생육속도와 PH 강하속도는 K, fragilis를 단독배양한 것보다 빨랐다. 단독 또는 혼합젖산발효에 미치는 온도의 영향을 조사한 결과는 L. acidophilus.는 37$^{\circ}C$, K. frahilis는 3$0^{\circ}C$, 두 균의 혼합배양시는 35-37$^{\circ}C$ 범위에서 산생성이 가장 좋았다. 혼합배양 시 검토한 젖산발효 최적조건은 L. acidophilus와 K. fragilis의 접종비율이 1:5, sucrose 0.5-1.0% SKIMMILK 1.5%를 각각 첨 가한 것이 좋았다.

• Microbiology and Biotechnology Letters
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• v.12 no.4
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• pp.261-264
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• 1984

The optimal condition of the ethanol fermentation from raw cassava starch by simultaneous saccharification - fermentation (SSF) was studied using glucoamylase from Aspergillus sp. and a yeast strain. The rate and yield of ethanol production were optimum at pH 3.6 with shaking. The fine milling treatment was effective for both saccharification and SSF of raw cassava starch. The presaccharification at 6$0^{\circ}C$ for 1 hr before SSF increased the rate and yield of ethanol production, as well. To increase the ethanol concentration after fermentation the substrate concentration could be increased up to 2195 without the problem of viscosity. The use of high concentration ethanol tolerant yeast strains and high substrate concentration produced ethanol higher than 10%(W/V) after fermentation for 5 days.

• Journal of the Korean Society of Food Science and Nutrition
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• v.30 no.3
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• pp.460-465
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• 2001

To prepare vinegar using concentration apple juice, response surface methodology (RSM) was applied to optimize and monitor the vinegar fermentation properties by two stage fermentation. In the first stage, the optimum conditions for maximum alcohol contents were 18.56。Brix of initial sugar concentration, 61.96 rpm of agitation rate and 67.32 hr of fermentation time. The optimum condition for maximum acidity in the second stage (vinegar fermentation) were 201.53 rpm of agitation rate and 179.42 hr of fermentation time. Malic acid content was the highest and its content little changed during acetic acid fermentation. Lactic acid content increased a little during alcohol fermentation. Acetic acid content apparently increased during acetic acid fermentation.

• Journal of the Korea Organic Resources Recycling Association
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• v.9 no.4
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• pp.99-104
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• 2001

The influence of agitation speed on the yeast growth was investigated in the production of probiotic feed from pulverized liquified food wastes by aerobic fermentation. A yeast Kluyvermyces marxianus was selected through a preliminary screening. The yeast was cultured by 2liter jar fermenter. in 10% solid(w/v) substrate of liquified food waste at $35^{\circ}C$ with each different agitation speed of 500, 900 and 1200 rpm. For the acceleration of enzyme excretion mixed culture with Aspergillus oryzae was also attempted and the results were compared to those of single culture. As results the viable cell number was increased by increasing agitation speed. But it showed highest value in 900rpm and then decreased in 1200rpm. The mixed culture increased amylase activity and growth rate, but did not seem to enhance the highest viable cell count in the final fermentation stage.

• Journal of the Korean Society of Food Science and Nutrition
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• v.32 no.6
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• pp.812-817
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• 2003

In the first stage, strawberry wine was manufactured in 14$^{\circ}$Brix initial sugar content, for 50 hr at 28$^{\circ}C$ using Saccharomyces kluyeri DJ97. In the second stage, the acetic acid fermentation conditions for maximun acidity (4.60%) were 1.48% initial acidity and 195.76 rpm in agitation rate for 7.34 day. The fermentation conditions for maximun Hunter color a value were 1.78% initial acidity and 117.63 rpm in agitation rate for 7.35 day. Therefore, optimum acetic acid fermentation conditions were 1.5% initial acidity and 196 rpm in agitation rate for 176 hr using Acetobacter sp. PA97.