柠檬酸盐缓冲液在利用玉米秸秆进行丙酮-丁醇-乙醇(ABE)发酵以及通过汽提-蒸汽渗透(VSVP)工艺进行高效产物回收中的重要作用。
The vital role of citrate buffer in acetone-butanol-ethanol (ABE) fermentation using corn stover and high-efficient product recovery by vapor stripping-vapor permeation (VSVP) process.
作者信息
Xue Chuang, Wang Zixuan, Wang Shudong, Zhang Xiaotong, Chen Lijie, Mu Ying, Bai Fengwu
机构信息
School of Life Science and Biotechnology, Dalian University of Technology, Linggong Road 2, Dalian, 116024 China.
School of Life Science and Biotechnology, Dalian University of Technology, Linggong Road 2, Dalian, 116024 China ; School of Life Sciences and Biotechnology, Shanghai Jiao Tong University, Shanghai, 200240 China.
出版信息
Biotechnol Biofuels. 2016 Jul 19;9:146. doi: 10.1186/s13068-016-0566-2. eCollection 2016.
BACKGROUND
Butanol is not only an important solvent and chemical intermediate in food and pharmaceutical industries, but also considered as an advanced biofuel. Recently, there have been resurging interests in producing biobutanol especially using low-cost lignocellulosic biomass, but the process still suffers from low titer and productivity. The challenge for the bioconversion approach is to find an effective way of degrading materials into simple sugars that can then be converted into fuels by microorganisms. The pretreatment of lignocellulosic biomass is the great important process in influencing butanol production and recovery, finally determining its eco-feasibility in commercialization.
RESULTS
The effects of various strengths of citrate buffer on enzymatic hydrolysis and acetone-butanol-ethanol fermentation using corn stover or glucose as feedstock were investigated. The strengths of citrate buffer in the range of 20-100 mM had no effect on enzymatic hydrolysis, but greatly influenced the performance of ABE fermentation using corn stover hydrolysate. When 30 mM citrate buffer was used for enzymatic hydrolysis, the fermentation broth with the maximum butanol and ABE concentrations of 11.2 and 19.8 g/L were obtained from 30.9 g/L glucose and 9.7 g/L xylose, respectively, which was concentrated to 100.4 g/L butanol and 153.5 g/L ABE by vapor stripping-vapor permeation process. Furthermore, using glucose as sole carbon source, there were no cell growth and ABE production in the P2 medium with 80 or 100 mM citrate buffer, indicating that higher concentrations of citrate buffer had deleterious effect on cell growth and metabolism due to the variation of cells internal pH and cell membrane permeability. To mimic in situ product recovery for ABE fermentation, the VSVP process produced the condensate containing 212.0-232.0 g/L butanol (306.6-356.1 g/L ABE) from fermentation broth containing 10 g/L butanol (17 g/L ABE), the performance of which was more effective than pervaporation and gas stripping.
CONCLUSIONS
As it has significant impact on butanol fermentation, the strength of citrate buffer is of great importance in lignocellulosic butanol fermentation. Compared with pervaporation and gas stripping, the VSVP process has great potential for efficient butanol recovery in biobutanol production.
背景
丁醇不仅是食品和制药行业重要的溶剂及化学中间体,还被视为一种先进的生物燃料。近来,人们对生产生物丁醇再度产生兴趣,尤其是利用低成本的木质纤维素生物质来生产,但该过程仍存在产量低和生产率低的问题。生物转化方法面临的挑战是找到一种将原料降解为单糖的有效方法,然后单糖可被微生物转化为燃料。木质纤维素生物质的预处理是影响丁醇生产和回收的极其重要的过程,最终决定其商业化的生态可行性。
结果
研究了不同强度的柠檬酸盐缓冲液对以玉米秸秆或葡萄糖为原料的酶解及丙酮-丁醇-乙醇发酵的影响。20-100 mM范围内的柠檬酸盐缓冲液强度对酶解没有影响,但对使用玉米秸秆水解产物的丙酮-丁醇-乙醇发酵性能有很大影响。当使用30 mM柠檬酸盐缓冲液进行酶解时,从30.9 g/L葡萄糖和9.7 g/L木糖中分别获得了最大丁醇浓度为11.2 g/L和丙酮-丁醇-乙醇浓度为19.8 g/L的发酵液,通过汽提-蒸汽渗透过程将其浓缩至100.4 g/L丁醇和153.5 g/L丙酮-丁醇-乙醇。此外,以葡萄糖为唯一碳源时,在含有80或100 mM柠檬酸盐缓冲液的P2培养基中没有细胞生长和丙酮-丁醇-乙醇产生,这表明较高浓度的柠檬酸盐缓冲液由于细胞内部pH值和细胞膜通透性的变化对细胞生长和代谢有有害影响。为模拟丙酮-丁醇-乙醇发酵的原位产物回收,汽提-蒸汽渗透过程从含有约10 g/L丁醇(约17 g/L丙酮-丁醇-乙醇)的发酵液中产生了含有212.0-232.0 g/L丁醇(306.6-356.1 g/L丙酮-丁醇-乙醇)的冷凝物,其性能比渗透汽化和汽提更有效。
结论
由于柠檬酸盐缓冲液强度对丁醇发酵有重大影响,其在木质纤维素丁醇发酵中非常重要。与渗透汽化和汽提相比,汽提-蒸汽渗透过程在生物丁醇生产中高效回收丁醇方面具有很大潜力。
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