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Microbial Biocatalysis

Microbial Biocatalysis

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Biocatalysis is a sustainable alternative for the chemical industry in manufacturing, monitoring, and waste management. Biocatalytic processes perform with isolated enzymes or whole cells as biocatalysts. Whole-cell biocatalysts offer some unique advantages of cascade reactions catalyzed by multienzymes as well as a single bioredox reaction with cofactor regeneration in a single strain. Therefore, whole-cell biocatalysts are widely applied for biosynthesis/biotransformation to produce value-added chemicals as well as the complete mineralization of organic pollutants.Biological catalytic processing using whole-cell biocatalysts includes biocatalyst engineering, bio-reaction engineering, and downstream processing. In addition to the traditional screening of microbial strains and immobilized whole-cell biocatalysts, modern genetic engineering, metabolic engineering, and synthetic biology make tailored whole-cell biocatalysts possible. At the same time, some integrated processes have successfully been applied in the catalytic processing using living whole-cell biocatalysts, such as harnessing biocompatible chemistry to interface with the microbial metabolism as well as using various separation techniques for in situ product removal.This reprint on “Microbial Biocatalysis” provides a comprehensive overview of the recent developments of catalyst discovery, catalyst modification, and process intensification for whole cell catalysis in fermentation, biotransformation or biodegradation processes.

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Keywords

  • (R)-1-phenylethanol
  • Absidia coerulea
  • acetophenone tolerance
  • aerobic composting
  • Arthrobacter sp. ST11
  • atrazine
  • Biochemical engineering
  • Biodegradation
  • biopolymers
  • Biotechnology
  • biotransformation
  • C058
  • C7-hydroxylation
  • Cadmium
  • cell immobilization
  • culture conditions optimization
  • Cunninghamella blakesleeana 3.970
  • depolymerization
  • DHEA
  • diclofenac
  • directed evolution
  • Enzymes
  • Extracellular Polymeric Substances
  • Gibberella sp.
  • glycerol
  • immobilization
  • laccase
  • Marine enzymes
  • metabolites
  • microbial transformation
  • microcosmic structure
  • microflora composition
  • multifunctional enzymes
  • mycelium biofloc
  • n/a
  • nicotinic acid
  • nitrilase
  • nonaqueous-phase liquid
  • nysfungin
  • nystatin A1
  • nystatin A3
  • O-demethylation rabeprazole sulfide
  • p-coumaric acid
  • Persian Gulf
  • phase inversion
  • phenol
  • phenylalanine ammonia-lyase
  • phytosterols
  • Pickering emulsion
  • plant oil
  • polyfungin B
  • post-modifying enzymes
  • rabeprazole
  • rapeseed oil
  • reaction optimization
  • secondary metabolic
  • semi-continuous packed-bed bioreactor
  • Sewage treatment
  • short-chain dehydrogenase/reductase
  • starch hydrolysis
  • Streptomyces noursei
  • sulfide
  • sustainability
  • synthases
  • Technology, engineering, agriculture
  • Technology: general issues
  • Toxicity
  • trans-cinnamic acid
  • UV mutagenesis
  • whole genome sequencing
  • whole-cell biotransformation
  • whole-cell catalyst
  • xenobiotics
  • Yarrowia lipolytica
  • α-amylase
  • α-ketoglutaric acid biosynthesis

Links

DOI: 10.3390/books978-3-0365-7190-4

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