The microbial world has given us many surprises including microbes that grow under extremely harsh conditions (122C at 40 MPa), novel metabolisms such as the uranium and perchlorate reduction, and novel chemicals that can be used to control diseases. We continually face new and difficult problems such as the need to transition to more carbon-neutral energy sources and to find eco-friendly chemicals and to find new drugs to treat disease. Will it be possible to tap into the seemingly limitless potential of microbial activity to solve our current and future problems?The answer to this question is probably yes. We are already looking to the microbial world to provide new energy sources, green chemicals to replace those made from petroleum, and new drugs to fight disease. To help us along these paths, we are deciphering how microorganisms interact with each other. We know that microbial populations interact and communicate with each other. The language that microbes use is chemical where small molecules are exchanged among different microbial cells. Sometimes, these chemicals suppress activities of competitors and could be used as antibiotics or may have other therapeutic uses. Other times, the chemicals stimulate complex responses in microbial populations such as fruiting body or biofilm formation. By understanding the conversation that microbes are having among themselves, e. g.

Biofuels and bioenergy have emerged as an alternative option based on their sustainability, concomitant waste treatment, and site-specific flexibility. This book encompasses all the knowhow of different biofuel production processes through biological methods. It describes recent advancements in all major biofuel technologies such as biohydrogen, biomethane, bioethanol, syngas and so forth. Related protocols supported by schematic representation are included, encompassing comprehensive up-to-date scientific and technological information in biofuels and bioenergy. Features: Includes practical approaches focused on process design and analysis in biofuel production via biological routes Discusses kinetic equations of different microbial systems Provides comprehensive coverage of biochemical kinetics and equations related to biofuel process Describes protocols for setting up of experiments for pertinent biofuel technologies Emphasis on practical engineering approaches and experiments This book is aimed at researchers and graduate students in chemical, biochemical and bioprocess engineering, and biofuels.

The application of Biotechnology dates back to the early era of civilization, when people first started to cultivate food crops. While the early applications are certainly still relevant, modern biotechnology is primarily associated with molecular biology, cloning and genetic engineering not only to increase the yield and to improve the quality of the crop but also its potential impact has touched upon virtually all domains of human interactions. Within the last 50 years, several key scientific discoveries revolutionized the biological sciences that facilitated the rapid growth of the biotechnology industry. 'Biotechnology and Biological Sciences III' contains the contributions presented at the 3rd International Conference on Biotechnology and Biological Sciences (BIOSPECTRUM 2019, Kolkata, India, 8-10 August 2019). The papers discuss various aspects of Biotechnology such as: microbial biotechnology, bioinformatics and drug designing, innovations in pharmaceutical industries and food processing industries, bioremediation, nano-biotechnology, and molecular-genetics, and will be of interest to academics and professionals involved or interested in these subject areas.

The microbial world has given us many surprises including microbes that grow under extremely harsh conditions (122C at 40 MPa), novel metabolisms such as the uranium and perchlorate reduction, and novel chemicals that can be used to control diseases. We continually face new and difficult problems such as the need to transition to more carbon-neutral energy sources and to find eco-friendly chemicals and to find new drugs to treat disease. Will it be possible to tap into the seemingly limitless potential of microbial activity to solve our current and future problems?The answer to this question is probably yes. We are already looking to the microbial world to provide new energy sources, green chemicals to replace those made from petroleum, and new drugs to fight disease. To help us along these paths, we are deciphering how microorganisms interact with each other. We know that microbial populations interact and communicate with each other. The language that microbes use is chemical where small molecules are exchanged among different microbial cells. Sometimes, these chemicals suppress activities of competitors and could be used as antibiotics or may have other therapeutic uses. Other times, the chemicals stimulate complex responses in microbial populations such as fruiting body or biofilm formation. By understanding the conversation that microbes are having among themselves, e. g.

This book highlights recent advancements in such an important topic, through contribution from experts demonstrating different applications in 'day-to-day' life, both existing and newly emerging biological technologies, and thought provoking approaches from different parts of the world, potential future prospects associated with some frontier development in non-conventional energy sources. It covers different aspects of cellulosic and lignocellulosic biomass; Cellulosics Biorefinery; Algal Biofuels; Biodiesel; Bioethanol; Microbial Fuel Cells; Biofuel cells; and biohydrogen production. This book is a comprehensive and informative compilation for international readers, especially undergraduate, post graduate students and researchers.

This book highlights recent advancements in such an important topic, through contribution from experts demonstrating different applications in 'day-to-day' life, both existing and newly emerging non-biological technologies, and thought provoking approaches from different parts of the world, potential future prospects associated with some frontier development in non-conventional energy sources. It covers different types of natural energy sources such as: Ocean, Tidal and Wave energy; Nuclear energy; Solar cells; Geothermal energy; Hydrogen Fuel; Photovoltaic modules; Gas hydrates; Hydrate-based Desalination Technology; and Hydrothermal Liquefaction of Kraft Lignin/ Lignocellulosic Biomass to Fuels and Chemicals. This book is a comprehensive and informative compilation for international readers, especially undergraduate and post graduate students and researchers.