Efficient conversion of fermentable sugars from cheap lignocellulosic biomass is current need of viable ethanol production technology. In present study, agricultural waste biomass such as rice straw was pretreated by using 0.5% sulfuric acid for 60 min at 121 °C in autoclave. A statistical experimental design like central composite design (CCD) was used for optimization of enzymatic hydrolysis conditions to achieve the significant reducing sugar yield using commercial cellulase. The optimal conditions for acid pretreated rice straw were found to be 40 FPU/g enzymes loading, 17.50% biomass loading at 50 °C for 72 h. Reducing sugar yield was 0.359 g/g were achived at the optimized conditions. Experimental results under optimum conditions fit well with CCD model predictions. The structural and morphological changes in native and dilute acid treated rice straw substrate were evaluated by FTIR, XRD and SEM analysis. XRD pattern of biomass revealed an increase in the crystallite size and crystallinity index of pretreated biomass. Scanning electron micrograph reported surface porosity and distorted structure due to pretreatment. HPTLC analysis of sugars like glucose and xylose in hydrolysate produced after enzymatic hydrolysis was determined.
The efficient cellulolytic microorganism was isolated from soil samples collected from Shivaji University campus. Biochemical test and phylogenetic analysis of isolated culture identified as Klebsiella sp. PRW-1. The isolated culture could utilize pure cellulosic substrates (carboxymethylcellulose (CMC) and avicel) and different agricultural wastes like sugarcane bagasse, sugarcane barbojo, sorghum husks, grass powder, corn straw and paddy straw by producing a large amount of endoglucanase, exoglucanase, β-glucosidase, filter paperase (FPU), xylanase and glucoamylase. The reducing sugar production was found higher in the presence of grass powder and sugarcane barbojo. Effects of different physic-chemical parameters to achieve maximum cellulolytic enzymes production were systematically investigated. The effects of supplementation of different metals additives as well as the stability in the presence of higher temperature, pH and commercial detergents, on cellulolytic enzymes were also studied. The foregoing result increases the applicability of the strain for the utilization and bioconversion of lignocellulosic biomass that could be used for bioenergy production.
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