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Current Trends in <strong>Biotechnology</strong> <strong>and</strong> <strong>Pharmacy</strong>Vol. 5 (1) 982-992 January 2011. ISSN 0973-8916 (Print), 2230-7303 (Online)Jute-Based Fabrics Isidore Gomes1.Bangladesh Journal <strong>of</strong> Microbiology,24:109-114.19. Vyas, A., Vyas, D. <strong>and</strong> Vyas, K.M. (2005).Production <strong>and</strong> optimization <strong>of</strong> cellulases onpretreated groundnut shell by Aspergillusterreus AV49. Journal <strong>of</strong> Scientific & IndustrialResearch, 64:281-286.20. Singh, A. <strong>and</strong> Kumar, P.K. (1991).Fusarium oxysporum: status in bioethanolproduction. Critical Review in <strong>Biotechnology</strong>,11(2):129-47.21. Wen, Z., Liao, W. <strong>and</strong> Chen, S. (2005).Production <strong>of</strong> cellulase by Trichodermareesei from dairy manure. BioresourceTechnology, 96:491-499.22. Sharma, S.K., Kalra, K.L. <strong>and</strong> Kocher, G.S.(2004). Fermentation <strong>of</strong> enzymatichydrolysate <strong>of</strong> sunflower hulls for ethanolproduction <strong>and</strong> its scale-up. BiomassBioenergy, 27:392-402.23. Arslan, Y. <strong>and</strong> Eken-Saraçoðlu, N. (2010).Effects <strong>of</strong> pretreatment methods forhazelnut shell hydrolysate fermentation withPichia Stipitis to ethanol. BioresourceTechnology, 101(22):8664-8670.24. Nigam, J.N. (2001). Ethanol productionfrom wheat straw hemicellulose hydrolysateby Pichia stipitis. Journal <strong>of</strong> <strong>Biotechnology</strong>.87(1):17-27.99225. Ch<strong>and</strong>el, A.K., Singh, O.V., Rao, L.V.,Ch<strong>and</strong>rasekhar, G. <strong>and</strong> Narasu, M.L. (2011).Bioconversion <strong>of</strong> novel substrateSaccharum spontaneum, a weedy material,into ethanol by Pichia stipitis NCIM3498.Bioresource Technology, 102:1709-1714.26. Gupta, R., Sharma, K.K. <strong>and</strong> Kuhad, R.C.(2009). Separate hydrolysis <strong>and</strong>fermentation (SHF) <strong>of</strong> Prosopis juliflora,a woody substrate, for the production <strong>of</strong>cellulosic ethanol by Saccharomycescerevisiae <strong>and</strong> Pichia stipitis-NCIM 3498.Bioresource Technology, 100(3):1214-1220.27. Kuhad, R.C., Gupta, R., Khasa, Y.P. <strong>and</strong>Singh, A. (2010). Bioethanol productionfrom Lantana camara (red sage): Pretreatment,saccharification <strong>and</strong> fermentation.Bioresource Technology, 101(1): 8348-8354.28. Cho, D.H., Shin, S., Bae, Y., Park, C., Kim,Y.H. (2010). Enhanced ethanol productionfrom deacetylated yellow poplar acid hydrolysateby Pichia stipitis. Bioresource Technology,101:4947-4951.29. Stoutenburg R.M., Perrotta, J.A., Amidon,T.E., <strong>and</strong> Nakas, J.P. (2008). Ethanol productionfrom â membrane purified hemicellulosichydrolysate derived from sugar mapleby Pichia stipitis NRRL Y-7123.Bioresources, 3(4):1349-1358.Fermentation <strong>of</strong> Enzymatically Saccharified Groundnut