School of Biochemical Engineering, Pontificia Universidad Católica de Valparaíso, Avenida Brasil 2147, Valparaíso, Chile.
Bioresour Technol. 2011 Nov;102(22):10180-6. doi: 10.1016/j.biortech.2011.09.025. Epub 2011 Sep 13.
Response surface methodology was used as an optimization tool for the production of short chain fructooligosaccharides (sc-FOS) using the commercial cellulolytic enzyme preparation, Rohapect CM. Three independent variables, temperature, concentrations of sucrose and enzyme were tested in the reaction medium. The responses of the design were, yield (gsc-FOS/100 g initial sucrose), 1-kestose (g/100 g sc-FOS) and volumetric productivity (gsc-FOS/Lh). Significant effects on the three responses included a quadratic effect (temperature), a linear effect (sucrose and enzyme concentrations) and an interaction between temperature and sucrose concentration. The cost-effective conditions to support the process in a high competitive market were 50 °C, 6.6 TU/mL enzyme, 2.103 M sucrose in 50 mM acetate buffer at pH 5.5, and the synthesis for a 5 h reaction time. Under these conditions, a high YP/S (63.8%), QP (91.9 g/Lh) and sGF2 (68.2%) was achieved.
响应面法被用作优化工具,用于使用商业纤维素酶制剂 Rohapect CM 生产短链果寡糖 (sc-FOS)。在反应介质中测试了三个独立变量,温度、蔗糖浓度和酶浓度。该设计的响应包括产率(每 100g 初始蔗糖产生的 gsc-FOS)、1-蔗果三糖(g/100g sc-FOS)和比生产率(gsc-FOS/Lh)。对这三个响应有显著影响的因素包括二次效应(温度)、线性效应(蔗糖和酶浓度)以及温度和蔗糖浓度之间的相互作用。在高竞争市场中支持该过程的具有成本效益的条件是 50°C、6.6 TU/mL 酶、2.103 M 蔗糖在 50mM 乙酸盐缓冲液 pH5.5 下,以及 5h 的反应时间。在这些条件下,实现了高 YP/S(63.8%)、QP(91.9 g/Lh)和 sGF2(68.2%)。
