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Entrapping cross-linked glucose oxidase aggregates within a graphitized mesoporous carbon network for enzymatic biofuel cells

Authors
Perez, Tsai GarciaHong, Sung-GilKim, JungbaeHa, Su
Issue Date
8월-2016
Publisher
ELSEVIER SCIENCE INC
Keywords
Glucose oxidase; Graphitized mesoporous carbons; Efficient electron transfer; Enzymatic biofuel cells; Cross-linked glucose oxidase aggregates
Citation
ENZYME AND MICROBIAL TECHNOLOGY, v.90, pp.26 - 34
Indexed
SCIE
SCOPUS
Journal Title
ENZYME AND MICROBIAL TECHNOLOGY
Volume
90
Start Page
26
End Page
34
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/87988
DOI
10.1016/j.enzmictec.2016.04.010
ISSN
0141-0229
Abstract
This paper reports a novel method for producing glucose oxidase-nanocomposites by entrapping cross linked glucose oxidase (GOx) aggregates within a graphitized mesoporous carbon (GMC) network. Entrapment was achieved by utilizing the strong self-aggregation tendency of GMC in aqueous buffer solution to form carbon networks. Using confocal microscopy and TEM, GOx-GMC nanocomposites were visualized. The electrochemical properties of GOx-GMC nanocomposites were studied by means of cyclic voltammograms, chronoamperometric and potentiostatic tests. Results therefrom suggested that the GOx-GMC nanocomposites offer a high electrical conductivity with the maximum electron transfer rate constant estimated at 5.16 +/- 0.61 s(-1). Furthermore, thermally treating the GOx-GMC nanocomposite and GOx aggregates at 60 degrees C for four hours, both samples maintained 99% of their initial activity, while the free GOx were completely deactivated. These performances suggested that our nanocomposite structure offered both improved electrochemical performance and stability by combining the high electrical conductivity offered by the GMC network with the high enzyme loading and stability offered by the cross-linked GOx aggregates. The GOx-GMC nanocomposite's electrochemical activity towards glucose oxidation was also investigated by using an enzymatic biofuel cell without artificial mediators, producing a power density of up to 22.4 mu W cm(-2) at 0.24V. (C) 2016 Elsevier Inc. All rights reserved.
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공과대학 (화공생명공학과)
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