Springer Approaches to Enhance Industrial Production of Fungal Cellulases (Fungal Biology)

Product Description Cellulase is a key enzyme of industrial interest and plays a crucial role in the hydrolysis of cellulose, a prime component of plant cell walls. Cellulase covers a broad area in the global market of industrially important enzymes and it is considered as the third largest industrial enzyme globally. Additionally, cellulase contributes about 20% of the total enzyme market globally because of its massive demand in various industries such as in biofuel production, pulp, paper, textile, food, and beverages, as well as in detergent industries. Among these, the demand of cellulase may become frequently selected in the commercial production of biofuels in the future and thus will further increase demand of cellulase in the biofuel industry. Because biofuel production is still not realized in a cost-effective, practical implementation due to its high cost (the higher cost of biofuels is due to higher production costs of enzymes), there is a need to introduce these types of approaches, which will help to lower the cost of enzyme production for developing overall economic biofuel production. From the Back Cover Cellulase is a key enzyme of industrial interest and plays a crucial role in the hydrolysis of cellulose, a prime component of plant cell walls. Cellulase covers a broad area in the global market of industrially important enzymes and it is considered as the third largest industrial enzyme globally. Additionally, cellulase contributes about 20% of the total enzyme market globally because of its massive demand in various industries such as in biofuel production, pulp, paper, textile, food, and beverages, as well as in detergent industries. Among these, the demand of cellulase may become frequently selected in the commercial production of biofuels in the future and thus will further increase demand of cellulase in the biofuel industry. Because biofuel production is still not realized in a cost-effective, practical implementation due to its high cost (the higher cost of biofuels is due to higher production costs of enzymes), there is a need to introduce these types of approaches, which will help to lower the cost of enzyme production for developing overall economic biofuel production. About the Author Manish Srivastava is working as DST INSPIRE faculty in the Department of Physics and Astrophysics, University of Delhi, India. He has published 41 research articles in peer reviewed journals, authored several book chapters and filed 1 patent. He worked as a post doctorate fellow in the Department of BIN Fusion Technology, Chonbuk National University from August 2012 to August 2013. He was an Assistant Professor in the Department of Physics, DIT School of Engineering, Greater Noida, from July 2011 to July 2012. He received his Ph. D. in Physics from the Motilal Nehru National Institute of Technology (MNNIT), Allahabad, India in 2011. Presently, he is working on the synthesis of graphene based metal oxide hybrids and their applications as catalysts. His area of interest is synthesis of nanostsructured materials and their applications as catalyst for development of electrode materials in energy storage, biosensors and biofuels production. Neha Srivastava is currently working as Post-doctorate fellow in Department of Chemical Engineering and Technology, IIT (Banaras Hindu University) Varanasi, India. She has published 26 research articles in the in peer reviewed journals and have 03 patents. She has been completed her PhD from Department of Molecular and Cellular Engineering, SHUATS, India in 2016 in the area of bioenergy. She has been received 06 Young Scientist Awards. Presently, she is working on biofuels production (Cellulase enzymes; production and enhancement, biohydrogen production from waste biomass, bioethanol production). P. K. Mishra is currently Professor and Head in the Department of Chemical Engineering & Technology, Indian Institute of Technology (BHU), Varanasi, In