Biocatalytic Process Optimization
Kuo, Chia-Hung
Biocatalytic Process Optimization - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2021 - 1 electronic resource (296 p.)
Open Access
Biocatalysis is very appealing to the industry because it allows, in principle, the synthesis of products not accessible by chemical synthesis. Enzymes are very effective, as are precise biocatalysts, as they are enantioselective, with mild reaction conditions and green chemistry. Biocatalysis is currently widely used in the pharmaceutical industry, food industry, cosmetic industry, and textile industry. This includes enzyme production, biocatalytic process development, biotransformation, enzyme engineering, immobilization, the synthesis of fine chemicals and the recycling of biocatalysts. One of the most challenging problems in biocatalysis applications is process optimization. This Special Issue shows that an optimized biocatalysis process can provide an environmentally friendly, clean, highly efficient, low cost, and renewable process for the synthesis and production of valuable products. With further development and improvements, more biocatalysis processes may be applied in the future.
Creative Commons
English
books978-3-03943-916-4 9783039439157 9783039439164
10.3390/books978-3-03943-916-4 doi
Research & information: general
catechin degalloylation flavonol glycoside hydrolase optimization tannase immobilized DERA statin side chain continuous flow synthesis alginate-luffa matrix design of experiments Anguilla marmorata eel protein hydrolysates functional properties herbal eel extracts agarose agarase agarotriose agaropentaose expression calycosin calycosin-7-O-β-D-glucoside glucosyltransferase sucrose synthase UDP-glucose recycle UGT–SuSy cascade reaction Candida antarctica lipase A surface-display system shear rate mass transfer rate enzymatic kinetic study enzymatic synthesis β-amino acid esters microreactor aromatic amines Michael addition kraft pulp cellulose xylan enzymatic hydrolysis Penicillium verruculosum glucose xylose lipase acidolysis docosahexaenoic acid ethyl ester eicosapentaenoic acid ethyl ester ethyl acetate kinetics styrene monooxygenase indole monooxygenase two-component system chiral biocatalyst solvent tolerance biotransformation epoxidation NAD(P)H-mimics superoxide dismutase (SOD) catalase (CAT) glutathione reductase (GR) aluminum (Al) selenium (Se) mouse brain liver phosphatidylcholine 3,4-dimethoxycinnamic acid enzymatic interesterification biocatalysis Pleurotus ostreatus enenzymatic hydrolysis peptide antioxidant hepatoprotective activity Yarrowia lipolytica whole–cell biocatalysis indolizine cycloaddition trehalose viscosity enzymes protein dynamics Kramers’ theory protein stabilization enzyme inhibition Lipase transesterification 2-phenylethyl acetate packed-bed reactor solvent-free cyclic voltammetry electrochemical impedance spectroscopy carbon nanotubes redox mediators CYP102A1 naringin dihydrochalcone neoeriocitrin dihydrochalcone regioselective hydroxylation n/a
Biocatalytic Process Optimization - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2021 - 1 electronic resource (296 p.)
Open Access
Biocatalysis is very appealing to the industry because it allows, in principle, the synthesis of products not accessible by chemical synthesis. Enzymes are very effective, as are precise biocatalysts, as they are enantioselective, with mild reaction conditions and green chemistry. Biocatalysis is currently widely used in the pharmaceutical industry, food industry, cosmetic industry, and textile industry. This includes enzyme production, biocatalytic process development, biotransformation, enzyme engineering, immobilization, the synthesis of fine chemicals and the recycling of biocatalysts. One of the most challenging problems in biocatalysis applications is process optimization. This Special Issue shows that an optimized biocatalysis process can provide an environmentally friendly, clean, highly efficient, low cost, and renewable process for the synthesis and production of valuable products. With further development and improvements, more biocatalysis processes may be applied in the future.
Creative Commons
English
books978-3-03943-916-4 9783039439157 9783039439164
10.3390/books978-3-03943-916-4 doi
Research & information: general
catechin degalloylation flavonol glycoside hydrolase optimization tannase immobilized DERA statin side chain continuous flow synthesis alginate-luffa matrix design of experiments Anguilla marmorata eel protein hydrolysates functional properties herbal eel extracts agarose agarase agarotriose agaropentaose expression calycosin calycosin-7-O-β-D-glucoside glucosyltransferase sucrose synthase UDP-glucose recycle UGT–SuSy cascade reaction Candida antarctica lipase A surface-display system shear rate mass transfer rate enzymatic kinetic study enzymatic synthesis β-amino acid esters microreactor aromatic amines Michael addition kraft pulp cellulose xylan enzymatic hydrolysis Penicillium verruculosum glucose xylose lipase acidolysis docosahexaenoic acid ethyl ester eicosapentaenoic acid ethyl ester ethyl acetate kinetics styrene monooxygenase indole monooxygenase two-component system chiral biocatalyst solvent tolerance biotransformation epoxidation NAD(P)H-mimics superoxide dismutase (SOD) catalase (CAT) glutathione reductase (GR) aluminum (Al) selenium (Se) mouse brain liver phosphatidylcholine 3,4-dimethoxycinnamic acid enzymatic interesterification biocatalysis Pleurotus ostreatus enenzymatic hydrolysis peptide antioxidant hepatoprotective activity Yarrowia lipolytica whole–cell biocatalysis indolizine cycloaddition trehalose viscosity enzymes protein dynamics Kramers’ theory protein stabilization enzyme inhibition Lipase transesterification 2-phenylethyl acetate packed-bed reactor solvent-free cyclic voltammetry electrochemical impedance spectroscopy carbon nanotubes redox mediators CYP102A1 naringin dihydrochalcone neoeriocitrin dihydrochalcone regioselective hydroxylation n/a