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101 0 $aeng
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200 10$aMicrobial Factories$b[electronic resource] $eBiodiversity, Biopolymers, Bioactive Molecules: Volume 2 /$fedited by Vipin Chandra Kalia
205   $a1st ed. 2015.
210  1$aNew Delhi :$cSpringer India :$cImprint: Springer,$d2015.
215   $a1 online resource (360 p.)
300   $aDescription based upon print version of record.
311   $a81-322-2594-5 
327   $a1. Biopolymers and their Application as Biodegradable Plastics -- 2. Approaches for the Synthesis of Tailor-made Polyhydroxyalkanoates -- 3. Biodegradable Polymers: Renewable Nature, Life Cycle and Applications -- 4. Phylogenetic Affiliation of Pseudomonas sp. MO2, a Novel Polyhydroxyalkanoate Synthesizing Bacterium -- 5. Synthetic Biology Strategies for Polyhydroxyalkanoates Synthesis -- 6. Frontiers in Biomedical Engineering: PHA Fabricated Implants -- 7. Sporulation, a Pitfall in the Path of PHB Production! -- 8. Microbial Biopolymers: The Exopolysaccharides -- 9. Innovations in Microalgal Harvesting using Biopolymer Based Approach -- 10. From microbial biopolymers to bioplastics: sustainable additives for PHB processing and stabilization -- 11. The Survivors of the Extreme: Bacterial biofilms -- 12. Synthetic Biology in Aid of Bioactive Molecules -- 13. Biotechnology Implications of Extremophiles as Life Pioneers and Wellspring of Valuable Biomolecules -- 14. Microbial CRISPER-Cas System: from Bacterial Immunity to Next Generation Antimicrobials -- 15. Photorhabdus: a Microbial Factory of Insect Killing Toxins -- 16. Microbial Vesicles: From Ecosystem to Diseases -- 17. Bacteriophage Diversity in Different Habitats and Their Role in Pathogen Control -- 18. Metagenomics: A Systemic Approach To Explore Microbial World -- 19. In silico Reconstitution of Novel Routes for Microbial Plastic -- 20. Investigating the Phylogeny of Hydrogen Metabolism by Comparative Genomics: Horizontal Gene Transfer -- 21. Prokaryotic Contributions Towards Eukaryotic Powerhouse. .
330   $aThis book highlights the efforts made by distinguished scientific researchers world-wide to meet two key challenges: i) the limited reserves of polluting fossil fuels, and ii) the ever-increasing amounts of waste being generated. These case studies have brought to the foreground certain innovative biological solutions to real-life problems we now face on a global scale: environmental pollution and its role in deteriorating human health. The book also highlights major advances in microbial metabolisms, which can be used to produce bioenergy, biopolymers, bioactive molecules, enzymes, etc. Around the world, countries like China, Germany, France, Sweden and the US are now implementing major national programs for the production of biofuels. The book provides information on how to meet the chief technical challenges ? identifying an industrially robust microbe and cheap raw material as feed. Of the various possibilities for generating bioenergy, the most attractive is the microbial production of biohydrogen, which has recently gained significant recognition worldwide, due to its high efficiency and eco-friendly nature. Further, the book highlights factors that can make these bioprocesses more economical, especially the cost of the feed. The anaerobic digestion (AD) process is more advantageous in comparison to aerobic processes for stabilizing biowastes and producing biofuels (hydrogen, biodiesel, 1,3-propanediol, methane, electricity), biopolymers (polyhydroxyalkanoates, cellulose, exopolysaccharides) and bioactive molecules (such as enzymes, volatile fatty acids, sugars, toxins, etc.) for biotechnological and medical applications. Information is provided on how the advent of molecular biological techniques can provide greater insights into novel microbial lineages. Bioinformatic tools and metagenomic techniques have extended the limits to which these biological processes can be exploited to improve human welfare. A new dimension to these scientific works has been added by the emergence of synthetic biology. The Big Question is: How can these Microbial Factories be improved through metabolic engineering and what cost targets need to be met?
606   $aBiodiversity
606   $aMicrobial genetics
606   $aMicrobial genomics
606   $aBiodiversity$3https://scigraph.springernature.com/ontologies/product-market-codes/L19031
606   $aMicrobial Genetics and Genomics$3https://scigraph.springernature.com/ontologies/product-market-codes/L32010
615  0$aBiodiversity.
615  0$aMicrobial genetics.
615  0$aMicrobial genomics.
615 14$aBiodiversity.
615 24$aMicrobial Genetics and Genomics.
676   $a570
702   $aKalia$b Vipin Chandra$4edt$4http://id.loc.gov/vocabulary/relators/edt
906   $aBOOK
912   $a9910298450303321
996   $aMicrobial Factories$92499332
997   $aUNINA