Miniaturizing Biocatalysis: Enzyme-Catalyzed Reactions in an Aqueous/Organic Segmented Flow Capillary Microreactor

A segmented flow capillary microreactor was used to perform the enzyme‐catalyzed conversion of 1‐heptaldehyde to 1‐heptanol in a two liquid‐liquid phase system. These reactor formats are established for chemical reactions but so far data describing the relevant system parameters for enzymatic cataly...

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Bibliographic Details
Published in:Advanced synthesis & catalysis 2011-09, Vol.353 (13), p.2511-2521
Main Authors: Karande, Rohan, Schmid, Andreas, Buehler, Katja
Format: Article
Language:English
Subjects:
alcohol dehydrogenase
Applied sciences
Assessments
Bioconversions. Hemisynthesis
Biological and medical sciences
Biotechnology
Capillarity
Catalysis
Chemical engineering
enzyme catalysis
Enzymes
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
Mass transfer
Methods. Procedures. Technologies
Microreactors
Phase ratio
Reactors
segmented flow
two-phase system
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Summary:A segmented flow capillary microreactor was used to perform the enzyme‐catalyzed conversion of 1‐heptaldehyde to 1‐heptanol in a two liquid‐liquid phase system. These reactor formats are established for chemical reactions but so far data describing the relevant system parameters for enzymatic catalysis are lacking. This work now addresses the impact of important parameters such as capillary diameter, flow velocity, phase ratio, and enzyme as well as substrate concentration on the performance of the enzymatic reaction under segmented flow conditions. All key parameters governing reaction performance have been correlated in a novel operational window for an easy assessment of the various system constraints. Such systems are characterized by high productivities and easy phase separation facilitating downstream processing. This work underscores the importance of segmented flow systems as a promising tool to perform multiphasic enzymatic catalysis. Abbreviations/Nomenclature: Da: Damköhler number; kcat: turnover number (s−1); eo: enzyme concentration (mM); φ: phase ratio; kL: mass transfer coefficient (m s−1); a: interfacial area per volume (m−1); CAe: equilibrium substrate concentration in the aqueous phase (mM); CAL: substrate concentration in the bulk aqueous phase (mM); rA: rate of reaction in the aqueous phase; mA: substrate mass transfer into the aqueous phase; STY: space time yield.
ISSN:1615-4150
1615-4169
1615-4169
DOI:10.1002/adsc.201100394