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유채대 가수분해물에서 inhibitor 저항성 효모선별과 이를 이용한 bioethanol 생산
연지현(Ji-Hyeon Yeon),김혜지(Hye-Ji Kim),오성호(Sung Ho Oh),이현용(Hyeon-Yong Lee),정경환(Kyung-Hwan Jung) 한국생물공학회 2010 KSBB Journal Vol.25 No.4
We established a strategy for bioethanol production using the hydrolysate of rape stem, in which the inhibitor cocktail was added intentionally. The final goal of this study was to circumvent the detoxification process when the hydrolysate of lignocelluloisic biomass contained the toxic substances in high concentration. When six yeast strains were examined, Sacchromyces cerevisiae ATCC 96581 and Pichia stipitis CBS 7126 were relatively resistant to inhibitor cocktail. Then, using strains 96581 and 7126, we designed a process strategy for bioethanol production, assuming that the concentration of toxic substance in the hydrolysate of rape stem was remarkably high. When strains 96581 and 7126 were inoculated simultaneously, it was observed that strain 7126 produced bioethanol as well as strain 96581, although the concentration of inhibitor cocktail was 18.2% (v/v). Finally, throughout this co-cultivation of strains 96581 and 7126, bioethanol was produced about 6.0 (g/L), and bioethanol yield reached at 0.4 (g-bioethanol/g-reducing sugar) (78.4% of theoretical value).
연지현(Ji-Hyeon Yeon),서현범(Hyeon-Beom Seo),오성호(Sung-Ho Oh),최원석(Won-Seok Choi),강도형(Do Hyung Kang),이현용(Hyeon-Yong Lee),정경환(Kyung-Hwan Jung) 한국생물공학회 2010 KSBB Journal Vol.25 No.3
We investigated the feasibility of bioethanol production from hydrolysate of brown seaweed Sargassum sagamianum. Prior to bioethanol production using yeasts, six yeast strains were compared and the best ones in terms of the ethanol production levels were selected. Pichiastipitis ATCC 7126, Pichia stipitis ATCC 58784, and Pichia stipitis ATCC 58376 were superior to others in terms of ethanol production. These yeast strains were used for producing bioethanol by the shaking bottle culture and the fermentor culture. Out of approximately 30 g/L reducing sugar, about 3~6 g/L and 4~7 g/L bioethanol were produced in the bottle culture and the fermentor one, respectively. Furthermore, it was observed that around 12~28 g-bioethanol was produced from 1 kilogram of Sargassum sagamianum. Compared with those previously published, these data were almost three to eight times higher in value.
응집성 Sacchromyces cerevisiae를 이용한 반복 유가식 ethanol 생산에서의 최적 운전전략
이상은(Sang-Eun Lee),연지현(Ji-Hyeon Yeon),서용창(Yong Chang Seo),강도형(Do Hyung Kang),이현용(Hyeon-Yong Lee),정경환(Kyung-Hwan Jung) 한국생물공학회 2010 KSBB Journal Vol.25 No.2
응집성 효모인 S. cerevisiae ATCC 96581를 이용한 최적의 에탄올 생산 공정 전략에 대하여 연구하였다. 효모의 특성을 고려하여, 효모 응집공정이 있는 반복 유가식 공정을 설계하였고, 이때 비멸균 포도당 분말을 매 12시간 마다 첨가하였고, 새로운 feeding medium을 24시간 혹은 36시간마다 세포 응집 후 교체 하였다. 이때 효모 응집이 없는 반복 유가식 공정과 비교 검토하였다. 최종적으로 24시간마다 세포를 응집시키고 상층배지를 제거하고 새로운 배지를 넣으면서 반복 유가식 에탄올 생산을 하는 것이 최적의 조건임을 알 수 있었고, 이때 120시간 동안 825 g의 에탄올을 생산 할 수 있었다. We investigated the optimal strategy for ethanol production using flocculent Sacchromyces cerevisiae ATCC 96581. Considering the characteristic of flocculent yeast, a repeated fed-batch ethanol fermentation was designed, in which non-sterile glucose powder was fed every 12 hours and, after cell flocculation, new feeding medium was exchanged every 24 or 36 hours. We particularly compared this fermentation process with those when cell flocculation was not carried out. Finally, the maximal total ethanol production was 825 g-ethanol during 120 hours, in which the time interval of withdrawal-fill of feeding medium was 24 hours and cell flocculation was carried out.