Electronic control of H+ current in a bioprotonic device with Gramicidin A and Alamethicin

Hemmatian, Zahra; Keene, Scott T.; Josberger, Erik E.; Miyake, Takeo; Arboleda, Carina; Soto-Rodríguez, Jessica; Baneyx, François; Rolandi, Marco

doi:10.1038/ncomms12981

Cited by 51 publications

(77 citation statements)

References 73 publications

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“…Electrical response of eumelanin: amorphous semiconductor model, mixed ionic-electronic conduction, electrochemical interfacial processes, and energy storage Biologic materials, such as proteins, peptides, and melanin, occur naturally in hydrated environments, such that their electrical response includes an important contribution from waterassisted proton transport. [31][32][33][34] The electrical properties of eumelanin have fascinated scientists since the late 1960s. After the observation of a reversible resistive switching in eumelanin pellets reported in 1974 by McGinness et al, [35] the amorphous semiconductor model was adopted to explain the strong hydration dependence of the conductivity.…”

Section: Introductionmentioning

confidence: 99%

Natural melanin pigments and their interfaces with metal ions and oxides: emerging concepts and technologies

Mauro

Soliveri

et al. 2017

MRS Communications

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Melanin (from the Greek μέλας, mélas, black) is a biopigment ubiquitous in flora and fauna, featuring broadband optical absorption, hydration-dependent electrical response, ion-binding affinity as well as antioxidative and radical-scavenging properties. In the human body, photoprotection in the skin and ion flux regulation in the brain are some biofunctional roles played by melanin. Here we discuss the progress in melanin research that underpins emerging technologies in energy storage/conversion, ion separation/water treatment, sunscreens, and bioelectronics. The melanin research aims at developing approaches to explore natural materials, well beyond melanin, which might serve as a prototype benign material for sustainable technologies.

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Section: Introductionmentioning

confidence: 99%

Natural melanin pigments and their interfaces with metal ions and oxides: emerging concepts and technologies

Mauro

Soliveri

et al. 2017

MRS Communications

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“…Hydrogels are intrinsically ion‐conducting due to high water content that provides a good environment for ions to be mobile. This ionic conductivity is useful for translation between devices and tissue at the bioelectronic interface . Hydrogels can be used in devices such as protonic field‐effect transistors (FET) that use palladium (Pd) and palladium hydride (PdH x ) as a transducer between H + and e − ( Figure ) .…”

Section: Hydrogels and Hydrophilic Polymersmentioning

confidence: 99%

“…The FET channel is made of an H + conducting hydrogel, maleic‐chitosan (poly (β‐(1,4)‐ N ‐Maleoyl‐D‐glucosamine)), which is a polysaccharide chitin derivative with high proton conductivity . Protonic bioelectronic devices can modulate pH in electrolytes and monitor metabolic reactions, control bioluminescence with pH, and interface with ion channels . In Figure 3b, an ion channel integrated with a Pd/PdH x contact was used to regulate protons flow across a supported lipid layer (SLB) .…”

Section: Hydrogels and Hydrophilic Polymersmentioning

confidence: 99%

Soft and Ion‐Conducting Materials in Bioelectronics: From Conducting Polymers to Hydrogels

Jia

Rolandi

2020

Adv Healthcare Materials

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Bioelectronics devices that directly interface with cells and tissue have applications in neural and cardiac stimulation and recording, electroceuticals, and brain machine interfaces for prostheses. The interface between bioelectronic devices and biological tissue is inherently challenging due to the mismatch in both mechanical properties (hard vs soft) and charge carriers (electrons vs ions). In addition to conventional metals and silicon, new materials have bridged this interface, including conducting polymers, carbon‐based nanomaterials, as well as ion‐conducting polymers and hydrogels. This review provides an update on advances in soft bioelectronic materials for current and future therapeutic applications. Specifically, this review focuses on soft materials that can conduct both electrons and ions, and also deliver drugs and small molecules. The future opportunities and emerging challenges in the field are also highlighted.

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“…These capabilities led the continuum electrodiffusion models to be more favoured for modelling the interaction of ion channels in biological processes (53,58,59) and for describing ionic transport in ceramic and polymeric membranes as well as modelling the transport of charged particles in semiconductors. (53,58,59) Figure 7 depicts a schematic of an ion channel bioprotonic device (60) that could be considered for the general case of bioelectronic device architecture. A supported lipid bilayer (SLB) (orange spheres with tails) is sandwiched in an electrolytic layer (a polymeric membrane, graphene membrane, or a liquid electrolyte).…”

Section: Macroscale Analysis Of Bioelectronic Devicesmentioning

confidence: 99%

“…Schematic representation of common bioelectronic device architecture. (60) the chemical potential gradient is the driving force for transport as well as the electrostatic potential,…”

Section: Macroscale Analysis Of Bioelectronic Devicesmentioning

confidence: 99%

A Short Review of the Architecture and Computational Analysis in the Design of Graphene Based Bioelectronic Devices

2018

Sensors and Materials

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Graphene possesses a high surface-to-volume ratio, which enables biomolecules to attach to it for bioelectronic applications. In this article, first, the classification and applications of bioelectronic devices are briefly reviewed. Then, recent work on real fabricated graphenebased bioelectronic devices as well as the analysis of their architecture and design using a computational approach to their charge transport properties are presented and discussed. A comparison to nongraphitic bioelectronic devices is also given. On the macroscale level, the design of devices is elaborated on the basis of a finite element analysis (FEA) approach, and the impact of design on the performance of the devices is discussed. On the nanoscale level, transport phenomena and their mechanisms for different design categories are elaborated on the basis of the density functional theory (DFT) and other quantum chemistry calculations. The calculated and measured charge transport properties of graphene-based bioelectronic devices are also compared with those of other available bioelectronic devices.

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Electronic control of H+ current in a bioprotonic device with Gramicidin A and Alamethicin

Cited by 51 publications

References 73 publications

Natural melanin pigments and their interfaces with metal ions and oxides: emerging concepts and technologies

Natural melanin pigments and their interfaces with metal ions and oxides: emerging concepts and technologies

Soft and Ion‐Conducting Materials in Bioelectronics: From Conducting Polymers to Hydrogels

A Short Review of the Architecture and Computational Analysis in the Design of Graphene Based Bioelectronic Devices

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