Saccharification and Bioethanol Fermentation of Carbohydrate-Extracted Microalgal Biomass by Genetically Identified Organisms

O. Agwa, Nwosu Ig, G. Abu
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引用次数: 2

Abstract

Saccharification of biomass to fermentable sugar is a major constraint for bioethanol production due to high cost of enzyme production and complications associated with the removal of hearse acid, alkali and salts formed after neutralization. This led to the search for low cost enzyme and its combination with dilute acid to enhance biomass hydrolysis. In this study, the microalgal biomass was hydrolysed using amylase and cellulase enzymes produced by solid state and submerged fermentation processes. Saccharification of algal biomass was studied using dilute tetraoxosulphate (VI) acid, crude enzyme complex and a combination of both. The highest yield of reducing sugar of 0.63 mg/ml was obtained with the co-combination hydrolysis of acid and enzyme, followed by acid hydrolysis (0.41 mg/ml) while the least was found with enzyme hydrolysis (0.36 mg/ml). The hydrolysate of the algal pretreated biomass was used for bioethanol production by Saccharomyces cerevisiae and co-cultures of S. cerevisiae and Aspergillus niger. The highest ethanol yield of 0.33 mg/ml at a percentage of 10.82% v/v was obtained from hydrolysates pretreated with co-combination of dilute acid and crude enzyme complex. The result showed that crude enzyme can increase the yield of hydrolyzed microalgal biomass for bioethanol production.
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糖提取微藻生物质的糖化和生物乙醇发酵
生物质糖化为可发酵糖是生物乙醇生产的主要制约因素,因为酶的生产成本高,并且与去除中和后形成的酸、碱和盐相关的并发症。这促使人们寻找低成本的酶,并将其与稀酸结合以增强生物质水解。在本研究中,利用固态发酵和深层发酵过程中产生的淀粉酶和纤维素酶对微藻生物量进行水解。采用稀硫酸四氧硫酸盐(VI)酸、粗酶配合物及两者的组合对藻类生物质糖化进行了研究。酸酶联合水解的还原糖得率最高,为0.63 mg/ml,酸水解次之,为0.41 mg/ml,酶水解最低,为0.36 mg/ml。经过预处理的藻类生物质的水解产物被酿酒酵母和酿酒酵母与黑曲霉共同培养用于生产生物乙醇。稀酸与粗酶配合物复合预处理的水解产物在10.82% v/v的浓度下乙醇得率最高,为0.33 mg/ml。结果表明,粗酶可提高微藻生物质水解乙醇的产率。
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