Nanoelectronic Investigation Reveals the Electrochemical Basis of Electrical Conductivity in <i>Shewanella</i> and <i>Geobacter</i>

Ding, Mengning; Shiu, Hui-Ying; Li, Shiue-Lin; Lee, Calvin K.; Wang, Gongming; Wu, Hao Bin; Weiss, Nathan O.; Young, Thomas D.; Weiss, Paul S.; Wong, Gerard C. L.; Nealson, Kenneth H.; Huang, Yu; Duan, Xiangfeng

doi:10.1021/acsnano.6b03655

Cited by 51 publications

(34 citation statements)

References 42 publications

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“…Understanding, and subsequently maximizing the interfacial charge transfer rate in semi-artificial photoanodes, will be key towards boosting photocurrent densities towards practical levels. Here, a host of techniques that have been established on simpler platforms (confocal fluorescence microscopy 54 , electrochemical impedance spectroscopy 55 , surface-enhanced Raman/infrared spectroscopy 56,57 , and nano-electrodes 58,59 ) can provide a wealth of mechanistic information for this set of systems. For example, spectroscopically detecting the secretion of diffusional mediators or redox changes in membranebound cytochromes can implicate their role in the microorganisms' charge transfer mechanism to an electrode.…”

Section: Semi-artificial Water Oxidationmentioning

confidence: 99%

Interfacing nature’s catalytic machinery with synthetic materials for semi-artificial photosynthesis

et al. 2018

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Semi-artificial photosynthetic systems aim to overcome the limitations of natural and artificial photosynthesis while providing an opportunity to investigate their respective functionality. The progress and studies of these hybrid systems is the focus of this forward-looking perspective. In this review, we discuss how enzymes have been interfaced with synthetic materials and employed for semiartificial fuel production. In parallel, we examine how more complex living cellular systems can be recruited for in vivo fuel production in an approach where inorganic nanostructures are hybridized with photosynthetic and non-photosynthetic microorganisms. Side-by-side comparisons reveal strengths and limitations of enzyme-and microorganism-based hybrid systems, and lessons extracted from studying enzyme-hybrids can be applied to investigations of microorganism-hybrid devices. We conclude by putting semi-artificial photosynthesis in the context of its own ambitions and discuss how it can help address the grand challenges facing artificial systems for the efficient generation of solar fuels and chemicals.

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Section: Semi-artificial Water Oxidationmentioning

confidence: 99%

Interfacing nature’s catalytic machinery with synthetic materials for semi-artificial photosynthesis

et al. 2018

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“…417 A very recent report argues, based on experimental evidence, that the mechanisms for all longrange transport reports are electrochemical nature. 418 Flickering resonance (FR), mentioned in sections 2.2 and 2.2, and in the discussions of 5 and 7). 110 The FR model accounts for both exponential distance dependence and partial excess charge location on the bridge.…”

Section: Electronic and Structural Properties Of Immobilized Proteinsmentioning

confidence: 99%

Protein bioelectronics: a review of what we do and do not know

et al. 2018

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We review the status of protein-based molecular electronics. First, we define and discuss fundamental concepts of electron transfer and transport in and across proteins and proposed mechanisms for these processes. We then describe the immobilization of proteins to solid-state surfaces in both nanoscale and macroscopic approaches, and highlight how different methodologies can alter protein electronic properties. Because immobilizing proteins while retaining biological activity is crucial to the successful development of bioelectronic devices, we discuss this process at length. We briefly discuss computational predictions and their connection to experimental results. We then summarize how the biological activity of immobilized proteins is beneficial for bioelectronic devices, and how conductance measurements can shed light on protein properties. Finally, we consider how the research to date could influence the development of future bioelectronic devices.

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“…Moreover, another study reported that the mechanism of charge transport in live biofilms of G. sulfurreducens was entirely mediated by redox reactions between the cells and the electrode, with charge neutrality provided by the movement of ions in solution. [98] The complex chemical composition and, therefore, electronic properties of biofilms make the comparison of experiments on biofilm to those on purified proteins-as some researchers have done-potentially misleading. [31,34,99] Moreover, individual protein nanowires are already challenging for electronic characterization.…”

Section: Impact Of Ions On Protein Materials Electronic Propertiesmentioning

confidence: 99%

“…[123] Even electrode area has been reported to change current-voltage responses in G. sulfurreducens biofilms. [98] For all these reasons, electrode design requires careful consideration; differing geometries may lead to different observed conduction mechanisms and complicate comparison between various conductive protein materials.…”

Section: The Importance Of Measurement Setupmentioning

confidence: 99%

Challenges in engineering conductive protein fibres: Disentangling the knowledge

2020

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Conductive protein materials are promising candidates for next‐generation bioelectronics due to their genetically‐customizable functionalities, biocompatibility, and bioactivity. We envision that they could be used in a variety of bio‐friendly functional devices, including bio‐electronic interfaces, bio‐energy devices, and sensors. However, their practical uses are limited by gaps in our understanding of charge transport in proteins, and by challenges in establishing reliable data collection methods. Moreover, characterization protocols are not always designed with applications in mind, which hinders engineering developments. Here, we review the effects of sample preparation, environmental conditions (ie, hydration level, pH, temperature), measurement scale (nano, micro, and macro), and geometrical considerations, on the measured electrical properties of proteins. We emphasize the need for standardized methods and collaborations across fields for the design of conductive protein materials, keeping in mind their end goal applications. Our objective for this review is to disentangle the knowledge on protein conductivity, and to clarify the current challenges, limitations, and future possibilities for these biological conductors.

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Nanoelectronic Investigation Reveals the Electrochemical Basis of Electrical Conductivity in Shewanella and Geobacter

Cited by 51 publications

References 42 publications

Interfacing nature’s catalytic machinery with synthetic materials for semi-artificial photosynthesis

Interfacing nature’s catalytic machinery with synthetic materials for semi-artificial photosynthesis

Protein bioelectronics: a review of what we do and do not know

Challenges in engineering conductive protein fibres: Disentangling the knowledge

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