PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics

PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics

Abstract Microbial electrochemical systems provide an environmentally-friendly means of energy conversion between chemical and electrical forms, with applications in wastewater treatment, bioelectronics, and biosensing. However, a major challenge to further development, miniaturization, and deployme...

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Main Authors: Tom J. Zajdel, Moshe Baruch, Gábor Méhes, Eleni Stavrinidou, Magnus Berggren, Michel M. Maharbiz, Daniel T. Simon, Caroline M. Ajo-Franklin
Format: Article
Language:English
Published: Nature Publishing Group 2018-10-01
Series:Scientific Reports
Subjects:
Microbial Electrochemical Systems (MESs)
Oneidensis
Electroactive Bacteria
Natural Biofilms
Carbon Fiber
Online Access:https://doi.org/10.1038/s41598-018-33521-9
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spelling doaj-f6602354c3104a48bbe0e15119be24e62020-12-08T05:45:48ZengNature Publishing GroupScientific Reports2045-23222018-10-018111210.1038/s41598-018-33521-9PEDOT:PSS-based Multilayer Bacterial-Composite Films for BioelectronicsTom J. Zajdel0Moshe Baruch1Gábor Méhes2Eleni Stavrinidou3Magnus Berggren4Michel M. Maharbiz5Daniel T. Simon6Caroline M. Ajo-Franklin7Department of Electrical Engineering and Computer Sciences, University of California, BerkeleyMolecular Foundry, Lawrence Berkeley National LaboratoryMolecular Foundry, Lawrence Berkeley National LaboratoryLaboratory of Organic Electronics, Linköping UniversityLaboratory of Organic Electronics, Linköping UniversityDepartment of Electrical Engineering and Computer Sciences, University of California, BerkeleyLaboratory of Organic Electronics, Linköping UniversityMolecular Foundry, Lawrence Berkeley National LaboratoryAbstract Microbial electrochemical systems provide an environmentally-friendly means of energy conversion between chemical and electrical forms, with applications in wastewater treatment, bioelectronics, and biosensing. However, a major challenge to further development, miniaturization, and deployment of bioelectronics and biosensors is the limited thickness of biofilms, necessitating large anodes to achieve sufficient signal-to-noise ratios. Here we demonstrate a method for embedding an electroactive bacterium, Shewanella oneidensis MR-1, inside a conductive three-dimensional poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) matrix electropolymerized on a carbon felt substrate, which we call a multilayer conductive bacterial-composite film (MCBF). By mixing the bacteria with the PEDOT:PSS precursor in a flow-through method, we maintain over 90% viability of S. oneidensis during encapsulation. Microscopic analysis of the MCBFs reveal a tightly interleaved structure of bacteria and conductive PEDOT:PSS up to 80 µm thick. Electrochemical experiments indicate S. oneidensis in MCBFs can perform both direct and riboflavin-mediated electron transfer to PEDOT:PSS. When used in bioelectrochemical reactors, the MCBFs produce 20 times more steady-state current than native biofilms grown on unmodified carbon felt. This versatile approach to control the thickness of bacterial composite films and increase their current output has immediate applications in microbial electrochemical systems, including field-deployable environmental sensing and direct integration of microorganisms into miniaturized organic electronics.https://doi.org/10.1038/s41598-018-33521-9Microbial Electrochemical Systems (MESs)OneidensisElectroactive BacteriaNatural BiofilmsCarbon Fiber
collection DOAJ
language English
format Article
sources DOAJ
author Tom J. Zajdel
Moshe Baruch
Gábor Méhes
Eleni Stavrinidou
Magnus Berggren
Michel M. Maharbiz
Daniel T. Simon
Caroline M. Ajo-Franklin
spellingShingle Tom J. Zajdel
Moshe Baruch
Gábor Méhes
Eleni Stavrinidou
Magnus Berggren
Michel M. Maharbiz
Daniel T. Simon
Caroline M. Ajo-Franklin
PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics
Scientific Reports
Microbial Electrochemical Systems (MESs)
Oneidensis
Electroactive Bacteria
Natural Biofilms
Carbon Fiber
author_facet Tom J. Zajdel
Moshe Baruch
Gábor Méhes
Eleni Stavrinidou
Magnus Berggren
Michel M. Maharbiz
Daniel T. Simon
Caroline M. Ajo-Franklin
author_sort Tom J. Zajdel
title PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics
title_short PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics
title_full PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics
title_fullStr PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics
title_full_unstemmed PEDOT:PSS-based Multilayer Bacterial-Composite Films for Bioelectronics
title_sort pedot:pss-based multilayer bacterial-composite films for bioelectronics
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2018-10-01
description Abstract Microbial electrochemical systems provide an environmentally-friendly means of energy conversion between chemical and electrical forms, with applications in wastewater treatment, bioelectronics, and biosensing. However, a major challenge to further development, miniaturization, and deployment of bioelectronics and biosensors is the limited thickness of biofilms, necessitating large anodes to achieve sufficient signal-to-noise ratios. Here we demonstrate a method for embedding an electroactive bacterium, Shewanella oneidensis MR-1, inside a conductive three-dimensional poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) matrix electropolymerized on a carbon felt substrate, which we call a multilayer conductive bacterial-composite film (MCBF). By mixing the bacteria with the PEDOT:PSS precursor in a flow-through method, we maintain over 90% viability of S. oneidensis during encapsulation. Microscopic analysis of the MCBFs reveal a tightly interleaved structure of bacteria and conductive PEDOT:PSS up to 80 µm thick. Electrochemical experiments indicate S. oneidensis in MCBFs can perform both direct and riboflavin-mediated electron transfer to PEDOT:PSS. When used in bioelectrochemical reactors, the MCBFs produce 20 times more steady-state current than native biofilms grown on unmodified carbon felt. This versatile approach to control the thickness of bacterial composite films and increase their current output has immediate applications in microbial electrochemical systems, including field-deployable environmental sensing and direct integration of microorganisms into miniaturized organic electronics.
topic Microbial Electrochemical Systems (MESs)
Oneidensis
Electroactive Bacteria
Natural Biofilms
Carbon Fiber
url https://doi.org/10.1038/s41598-018-33521-9
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