Optimization of hydrolysis conditions of crop straw and its effect in Chlorella sorokiniana culture

doi:10.13287/j.1001-9332.202304.029

Abstract

Abstract: Taking straws of corn, wheat, and millet as raw materials, we pretreated them with alkaline hydrogen peroxide, and then hydrolyzed by cellulase and xylanase. We selected the total sugar content in the hydrolysate as the indicator to evaluate the hydrolysis of the straws from three crop species, and further optimized the conditions. Then, the hydrolysates of three types of crop straws were used as carbon source for Chlorella sorokiniana culture to assess their effects on microalgal cultivation. The results showed that the optimal hydrolysis conditions for the three crop straws were identified as solid-liquid ratio of 1:15, temperature of 30 ℃, and treatment time of 12 h. Under such optimal condition, the total sugar contents increased up to 1.677, 1.412, and 1.211 g·L^-1 in the corn, millet and wheat straw hydrolysate, respectively. The hydrolysates from the three crop straw could significantly increase both algal biomass and lipid content of C. sorokiniana. Corn straw hydrolysate had the best effect, with high levels of algal biomass (1.801 g·L^-1) and lipid content (30.1%). Therefore, we concluded that crop straw hydrolysates as carbon source could significantly promote microalgal biomass and lipid enrichment. The results could lay the foundation for the efficient conversion and utilization of straw lignocellulose raw materials, provide new knowledge for the resource utilization of agricultural wastes, as well as the theoretical basis for the efficient cultivation of microalgae using crop straw hydrolysates.

Key words: crop straw, pretreatment condition, hydrolysis, Chlorella sorokiniana, lipid accumulation

LI Ruichun, JI Chunli, SU Sheng, CUI Hongli, ZHANG Chunhui, XUE Jinai, SUN Xiping, LI Runzhi. Optimization of hydrolysis conditions of crop straw and its effect in Chlorella sorokiniana culture[J]. Chinese Journal of Applied Ecology, 2023, 34(4): 1123-1129.

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