Hemoproteins in Design of Biofuel Cells

Direct electron transfer (DET) is a unique feature of some enzymes. The possibility of DET between enzymes and the electrode surface could pave the way for superior reagentless, noncompartmentised, mediator‐free biofuel cells, as it obviates the need for mediators and allows an efficient transductio...

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Bibliographic Details
Published in:Fuel cells (Weinheim an der Bergstrasse, Germany) Germany), 2009-02, Vol.9 (1), p.25-36
Main Authors: Ramanavicius, A., Ramanaviciene, A.
Format: Article
Language:English
Subjects:
Alcohol Dehydrogenase
Alcohol Dehydrogenase, Biofuel Cell, Biosensor, Conducting Polymer
Biofuel Cell
Biosensor
Conducting Polymer
Cytochrome c
Direct Electron Transfer
Gold Electrode
Graphite Electrode
Heme-c
Horseradish Peroxidase
Laccase
Microbial Fuel Cell
Peroxidase
Polyaniline
Polypyrrole
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Summary:Direct electron transfer (DET) is a unique feature of some enzymes. The possibility of DET between enzymes and the electrode surface could pave the way for superior reagentless, noncompartmentised, mediator‐free biofuel cells, as it obviates the need for mediators and allows an efficient transduction of the electrical current. DET is highly beneficial in the development of enzymatic and microbial biofuel cells. In this review article, hemoproteins, which are able to directly transfer electrons to the surfaces of conducting supports, are briefly overviewed and characterised. The main focus is laid on the application of heme‐c containing enzymes in biofuel cell design. Some historical steps and recent developments in biofuel cell design are presented in this article. Various designs of biofuel cells are overviewed. Possible applications of biofuel cells are presented and/or predicted and discussed. Problems and challenges in biofuel cell design and application are identified while possible directions to solve recent problems in biofuel cell development are discussed. The application of enzymatic biofuel cells as model systems and tools for advanced study of bioelectronics' properties of enzymes is predicted.
ISSN:1615-6846
1615-6854
DOI:10.1002/fuce.200800052