New and Future Developments in Microbial Biotechnology and Bioengineering From Cellulose to Cellulase: Strategies to Improve Biofuel Production
Coordonnateurs : Srivastava Neha, Srivastava Manish, Mishra P.K., Ramteke Pramod W., Singh Ram Lakhan
New and Future Developments in Microbial Biotechnology and Bioengineering: From Cellulose to Cellulase: Strategies to Improve Biofuel Production outlines new methods for the industrial production of the cellulose enzyme. The book compares the various processes for the production of biofuels, including the cost of cellulose production and availability. Biofuels are considered to be the main alternatives to fossil fuels in reducing environmental pollution and climate change. Currently, all existing biofuel production is suffering because of the high costs of production processes. As a result, cost effective practical implementation is needed to make this a viable energy alternative.
2. Cellulose to biofuels production: Market analysis
3. Microorganisms as efficient tool for cellulase production: Availability, diversity and efficiency
4. Role of bioprocess parameters to improve cellulase production
5. Bioprocess technology in cellulase production
6. Strategies to improve solid state fermentation technology
7. Cellulase via mutation mode: Way to improve production
8. Genetic engineering application to improve cellulase production and efficiency
9. Biofuel Cell Based on Enzyme
10. Cellulase: Catalysis and Reaction Engineering
11. Algal Cellulase
Dr. Neha Srivastava has received PhD in Biotechnology from Department of Molecular and Cellular Engineering, SHIATS, India in the area of bioenergy. She is working as Research Scientist Department of Chemical Engineering and Technology, IIT (BHU) Varanasi, India. She has published more than 80 research articles in the in peer reviewed journals of SCI impact factor and have filed 03 patents, 1 technology transfer and 24 published books & two book series of international renowned publisher. She is working on bioprocess technology and waste to biofuels production followed by nanocatalyst development through green route (Microbial screening and enzymes; production and enhancement, biohydrogen production from waste biomass, bioethanol production).
Field of Expertise :Synthesis of nanomaterials and their application as catalyst for development of electrode materials in energy storage, biosensors and biofules productions.
Manish Srivastava is working as DST INSPIRE faculty in the Department of Physics and Astrophysics, University of Delhi, India. He has published 39 research articles in the 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, 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.
Professor P.K Mishra is presently working as the Full time professor and Head, Department of Che
- Introduces new and innovative strategies for cellulase enzyme production at industrial scale
- Provides sustainable approaches to produce cellulase at low cost
- Covers all aspect and possible factors for economical, low cost, cellulase mediated biofuels production
Date de parution : 05-2019
Ouvrage de 314 p.
21.4x27.6 cm
Thème de New and Future Developments in Microbial Biotechnology... :
Mots-clés :
1G ethanol; 2G ethanol; Algal biomass; Biocathode; Bioethanol; Biofuel; Biofuel cell; Biofuels; Biomass; Bioprocess parameters; Bioprocess technology; Bioreactor; Bioreactor types; Biorefineries; Biorefinery; Cellulase; Cellulase system; Cellulases; Cellulose; Cellulose and lignocellulose; Central composite design; Cloning; Compositional analysis; Consolidated bioprocessing; Downstream processing; Energy economics; Enzymatic hydrolysis; Enzyme; Enzyme production; Enzymes; Epigenetics; Extremophilic; Fermentation; Filter-paper activity unit; Fungi; Genes; Genetic engineering; Hemicellulose; Immobilization methods; Lignin; Lignocellulose; Lignocelluloses; Lignocellulosic biomass; Microbes; Microorganisms; Nanomaterials; Optimization; Optimum; Parameters; Physicochemical and nutritional parameters; Pure cellulose; Reactor design; RSM; SmF process; Solid state fermentation; Solid-state fermentation; Solid-state fermentation (SSF); SSF; Submerged fermentation; Submerged fermentation (SmF); Trichoderma reesei
