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Bibliographic Details
Main Authors: Travaglini, Lorenzo, Lam, Nga T., Sawicki, Artur, Cha, Hee-Jeong, Xu, Dawei, Micolich, Adam P., Clark, Douglas S., Glover, Dominic J.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2310.10042
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author Travaglini, Lorenzo
Lam, Nga T.
Sawicki, Artur
Cha, Hee-Jeong
Xu, Dawei
Micolich, Adam P.
Clark, Douglas S.
Glover, Dominic J.
author_facet Travaglini, Lorenzo
Lam, Nga T.
Sawicki, Artur
Cha, Hee-Jeong
Xu, Dawei
Micolich, Adam P.
Clark, Douglas S.
Glover, Dominic J.
contents Electronically conductive protein-based materials could enable the creation of bioelectronic components and devices from sustainable and nontoxic materials, while also being well-suited to interface with biological systems, such as living cells, for biosensor applications. In addition, protein materials have other desirable properties such as inherent self-assembly and molecular recognition capabilities. However, as proteins are generally electrical insulators, the ability to render protein assemblies electronically conductive in a tailorable manner could usher in a plethora of useful materials. Here, we present an approach to fabricate electronically conductive protein nanowires by incorporating and aligning heme molecules in proximity along an ultrastable protein filament. The heme-incorporated protein nanowires demonstrated electron transfer over micrometer distances, with conductive atomic force microscopy showing individual nanowires having comparable conductance to naturally occurring bacterial nanowires. The heme-incorporated nanowires were also capable of harvesting energy from ambient humidity when deposited as multilayer films. Exposure of films to humidity produced electrical current, presumably through water molecules ionizing carboxy groups in the protein filament and creating an unbalanced total charge distribution that is enhanced by the presence of heme. A wide variety of other porphyrin molecules exist with varying electrochemical behaviors that could enable the electrical properties of protein assemblies to be tailored, paving the way to structurally- and electrically-defined protein-based bioelectronic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2310_10042
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Fabrication of electronically conductive protein-heme nanowires for power harvesting
Travaglini, Lorenzo
Lam, Nga T.
Sawicki, Artur
Cha, Hee-Jeong
Xu, Dawei
Micolich, Adam P.
Clark, Douglas S.
Glover, Dominic J.
Applied Physics
Materials Science
Biological Physics
00A79 (Primary), 92C75 (Secondary)
Electronically conductive protein-based materials could enable the creation of bioelectronic components and devices from sustainable and nontoxic materials, while also being well-suited to interface with biological systems, such as living cells, for biosensor applications. In addition, protein materials have other desirable properties such as inherent self-assembly and molecular recognition capabilities. However, as proteins are generally electrical insulators, the ability to render protein assemblies electronically conductive in a tailorable manner could usher in a plethora of useful materials. Here, we present an approach to fabricate electronically conductive protein nanowires by incorporating and aligning heme molecules in proximity along an ultrastable protein filament. The heme-incorporated protein nanowires demonstrated electron transfer over micrometer distances, with conductive atomic force microscopy showing individual nanowires having comparable conductance to naturally occurring bacterial nanowires. The heme-incorporated nanowires were also capable of harvesting energy from ambient humidity when deposited as multilayer films. Exposure of films to humidity produced electrical current, presumably through water molecules ionizing carboxy groups in the protein filament and creating an unbalanced total charge distribution that is enhanced by the presence of heme. A wide variety of other porphyrin molecules exist with varying electrochemical behaviors that could enable the electrical properties of protein assemblies to be tailored, paving the way to structurally- and electrically-defined protein-based bioelectronic devices.
title Fabrication of electronically conductive protein-heme nanowires for power harvesting
topic Applied Physics
Materials Science
Biological Physics
00A79 (Primary), 92C75 (Secondary)
url https://arxiv.org/abs/2310.10042