利用两亲木质素衍生物优化同步糖化发酵条件，以生产高浓度生物乙醇。

Optimization of simultaneous saccharification and fermentation conditions with amphipathic lignin derivatives for concentrated bioethanol production.

机构信息

Graduate School of Agriculture, Hokkaido University, Sapporo 060-8589, Japan.

Research Faculty of Agriculture, Hokkaido University, Sapporo 060-8589, Japan.

出版信息

Bioresour Technol. 2017 May;232:126-132. doi: 10.1016/j.biortech.2017.02.018. Epub 2017 Feb 8.

DOI:10.1016/j.biortech.2017.02.018

PMID:28214699

Abstract

Amphipathic lignin derivatives (A-LDs) prepared from the black liquor of soda pulping of Japanese cedar are strong accelerators for bioethanol production under a fed-batch simultaneous enzymatic saccharification and fermentation (SSF) process. To improve the bioethanol production concentration, conditions such as reaction temperature, stirring program, and A-LDs loadings were optimized in both small scale and large scale fed-batch SSF. The fed-batch SSF in the presence of 3.0g/L A-LDs at 38°C gave the maximum ethanol production and a high enzyme recovery rate. Furthermore, a jar-fermenter equipped with a powerful mechanical stirrer was designed for 1.5L-scale fed-batch SSF to achieve rigorous mixing during high substrate loading. Finally, the 1.5L fed-batch SSF with a substrate loading of 30% (w/v) produced a high ethanol concentration of 87.9g/L in the presence of A-LDs under optimized conditions.

摘要

从日本扁柏苏打制浆黑液中制备的两亲性木质素衍生物（A-LD）是在分批补料同步酶糖化和发酵（SSF）过程中强力促进生物乙醇生产的物质。为了提高生物乙醇的生产浓度，在小规模和大规模分批补料 SSF 中优化了反应温度、搅拌程序和 A-LD 负载等条件。在 38°C 下添加 3.0g/L A-LD 的分批补料 SSF 可获得最大乙醇产量和高酶回收效率。此外，设计了一个带有强力机械搅拌器的罐式发酵罐，用于 1.5L 规模的分批补料 SSF，以便在高底物负荷下实现严格混合。最后，在优化条件下，1.5L 分批补料 SSF 在 A-LD 存在下，在 30%（w/v）的底物负荷下可生产出 87.9g/L 的高乙醇浓度。

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利用两亲木质素衍生物优化同步糖化发酵条件，以生产高浓度生物乙醇。

Optimization of simultaneous saccharification and fermentation conditions with amphipathic lignin derivatives for concentrated bioethanol production.

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