Modeling of Process Operation Principles for the Immobilized Enzyme Candida Antarctica under Activity Decay

Matthias Feigel; Olaf Hinrichsen

doi:10.1002/cite.202100187

Modeling of Process Operation Principles for the Immobilized Enzyme Candida Antarctica under Activity Decay

Matthias Feigel, Olaf Hinrichsen

Chair of Chemical Technology I

Technical University of Munich

Research output: Contribution to journal › Article › peer-review

Abstract

Environmentally friendly processes that use enzymatic catalysts are often affected by faster deactivation than their conventional catalyst competitors. An intelligent process design that increases the lifetime of the enzyme Candida Antarctica Lipase B in an epoxidation reaction is described. Employing this strategy could result in an advancement of the competitiveness of the cost-intensive biological catalyst. With parallel fixed bed reactors operating in staggered mode and extended by an activity-dependent volume flow control, the lifetime and productivity of the enzyme were significantly increased. The process strategy presented is not limited to the underlying reaction system but can be applied to similar processes facing a fast activity decay.

Original language	English
Pages (from-to)	652-662
Number of pages	11
Journal	Chemie-Ingenieur-Technik
Volume	94
Issue number	5
DOIs	https://doi.org/10.1002/cite.202100187
State	Published - May 2022

Keywords

Deactivation
Fixed bed reactor
Immobilized enzymes
Process simulation
Process strategies

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10.1002/cite.202100187

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title = "Modeling of Process Operation Principles for the Immobilized Enzyme Candida Antarctica under Activity Decay",

abstract = "Environmentally friendly processes that use enzymatic catalysts are often affected by faster deactivation than their conventional catalyst competitors. An intelligent process design that increases the lifetime of the enzyme Candida Antarctica Lipase B in an epoxidation reaction is described. Employing this strategy could result in an advancement of the competitiveness of the cost-intensive biological catalyst. With parallel fixed bed reactors operating in staggered mode and extended by an activity-dependent volume flow control, the lifetime and productivity of the enzyme were significantly increased. The process strategy presented is not limited to the underlying reaction system but can be applied to similar processes facing a fast activity decay.",

keywords = "Deactivation, Fixed bed reactor, Immobilized enzymes, Process simulation, Process strategies",

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N2 - Environmentally friendly processes that use enzymatic catalysts are often affected by faster deactivation than their conventional catalyst competitors. An intelligent process design that increases the lifetime of the enzyme Candida Antarctica Lipase B in an epoxidation reaction is described. Employing this strategy could result in an advancement of the competitiveness of the cost-intensive biological catalyst. With parallel fixed bed reactors operating in staggered mode and extended by an activity-dependent volume flow control, the lifetime and productivity of the enzyme were significantly increased. The process strategy presented is not limited to the underlying reaction system but can be applied to similar processes facing a fast activity decay.

AB - Environmentally friendly processes that use enzymatic catalysts are often affected by faster deactivation than their conventional catalyst competitors. An intelligent process design that increases the lifetime of the enzyme Candida Antarctica Lipase B in an epoxidation reaction is described. Employing this strategy could result in an advancement of the competitiveness of the cost-intensive biological catalyst. With parallel fixed bed reactors operating in staggered mode and extended by an activity-dependent volume flow control, the lifetime and productivity of the enzyme were significantly increased. The process strategy presented is not limited to the underlying reaction system but can be applied to similar processes facing a fast activity decay.

KW - Deactivation

KW - Fixed bed reactor

KW - Immobilized enzymes

KW - Process simulation

KW - Process strategies

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Modeling of Process Operation Principles for the Immobilized Enzyme Candida Antarctica under Activity Decay

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