Systems biotechnology - Rational whole-cell biocatalyst and bioprocess design

Engineering in Life Sciences

Volumn 10, Issue 5, 2010, Pages 384-397

  Kuhn, Daniel ^a   Blank, Lars M ^a   Schmid, Andreas ^a,b   Bühler, Bruno ^a  

^a TU DORTMUND UNIVERSITY   (Germany)

^b LEIBNIZ INSTITUT FÜR ANALYTISCHE WISSENSCHAFTEN ISAS E V   (Germany)

Author keywords

Biochemical engineering; Industrial biotechnology; Systems biotechnology

Indexed keywords

BIOCATALYSIS; BIOPROCESS DESIGN; BIOPROCESSES; CELL CATALYSTS; CELLULAR FUNCTION; COMPLEX COMPOSITIONS; ENVIRONMENTALLY FRIENDLY PRODUCTS; FINE CHEMICAL INDUSTRY; GENETIC CHANGES; GROWING DEMAND; INDUSTRIAL BIOTECHNOLOGY; INTEGRATED STRATEGY; PROCESS LEVELS; QUANTITATIVE DESCRIPTION; RANDOM MUTAGENESIS; SCALE CHARACTERIZATION; SELECTED EXAMPLES; STANDARD TECHNOLOGY; SYSTEMS BIOLOGY; SYSTEMS BIOTECHNOLOGY; WHOLE CELL BIOCATALYSTS;

BIOCHEMICAL ENGINEERING; CHEMICAL CONTAMINATION; CHEMICAL INDUSTRY;

BIOTECHNOLOGY;

BIOTECHNOLOGY; CATALYST; GENOME; INDUSTRIAL PRACTICE; MICROBIAL ACTIVITY; MUTAGENICITY; SURVIVAL;

BIOCATALYSIS; BIOCATALYST; BIOENGINEERING; BIOPROCESS; BIOTECHNOLOGY; BIOTRANSFORMATION; CELL FUNCTION; CHEMICAL ENGINEERING; CHEMICAL REACTION KINETICS; DRUG INDUSTRY; ECOLOGY; ECONOMIC ASPECT; FERMENTATION; GENETIC ASSOCIATION; MICHAELIS MENTEN KINETICS; MICROBIAL METABOLISM; NONHUMAN; PROCESS DEVELOPMENT; REACTION ANALYSIS; REVIEW; SYSTEMS BIOLOGY; WHOLE CELL;

EID: 77958523815     PISSN: 16180240     EISSN: 16182863     Source Type: Journal    
DOI: 10.1002/elsc.201000009     Document Type: Review

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