Issue 1, 2019

Enzymatic self-wiring in nanopores and its application in direct electron transfer biofuel cells

Abstract

A synthetic enzymatic activity in nanopores leading to the direct fabrication of modified electrodes applicable as biosensors and/or biofuel cell elements is reported. We demonstrate the heterogeneous enzymatic implanting of platinum nanoclusters, PtNCs, in glucose oxidase, GOx, immobilized on mesoporous carbon nanoparticles, MPCNP-modified surface. As the pores confine the growth of the clusters, the PtNC@GOx/MPCNP assembly becomes electrically wired to the matrix, demonstrating direct electron transfer, DET, bioelectrocatalytic properties that correlate with the applied duration of synthesis and cluster size. This inside-out nanocluster growth from the cofactor to the matrix is investigated and further compared to a reversed outside-in strategy which follows the electrochemical deposition of the Pt clusters inside the pores and their electrically induced expansion towards the FAD center of the enzyme. While the inside-out and outside-in methodologies provide, for the first time, synthetic bidirectional direct wiring routes of an enzyme to a surface, we highlight an asymmetry in the wiring efficiency associated with the different assemblies. The results indicate the existence of a shorter gap between the FAD cofactor and the PtNCs in the enzymatically implanted assembly, resulting in elevated bioelectrocatalytic currents, lower overpotential, and a higher turnover rate, 2580 e s−1. The implanted assembly is then coupled to a bilirubin oxidase-adsorbed MPCNP cathode to yield an all-DET biofuel cell. Due to the superior electrical contact of the inside-out-synthesized anode, this cell demonstrates enhanced discharge potential and power outputs as compared to similar systems employing electrochemically synthesized outside-in-grown PtNC-GOx/MPCNPs or even GOx-modified MPCNPs diffusionally mediated by ferrocenemethanol.

Graphical abstract: Enzymatic self-wiring in nanopores and its application in direct electron transfer biofuel cells

Supplementary files

Article information

Article type
Paper
Submitted
28 Pha 2018
Accepted
05 Leo 2018
First published
06 Leo 2018
This article is Open Access
Creative Commons BY-NC license

Nanoscale Adv., 2019,1, 347-356

Enzymatic self-wiring in nanopores and its application in direct electron transfer biofuel cells

A. Trifonov, A. Stemmer and R. Tel-Vered, Nanoscale Adv., 2019, 1, 347 DOI: 10.1039/C8NA00177D

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