Magneto‐switchable Electrodes and Electrochemical Systems

Katz, Evgeny

doi:10.1002/elan.201500635

Cited by 22 publications

(16 citation statements)

References 98 publications

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“…Signal‐controlled (bio)electrochemical systems with switchable/tunable activity are essential for assembling bioelectronic, (particularly implantable bioelectronic) systems with adaptable behavior in biological environment. The majority of signal‐controlled electrochemical systems has been based on electrodes chemically modified with stimuli‐responsive materials (usually polymers) sharply changing their properties upon receiving external signals in the form of light irradiation, magnetic field application, temperature change, pH variation, etc. These changes result in activation/inhibition of electrochemical processes at the modified electrode surfaces, predominantly affecting electronic communication between biological molecules (usually enzymes, frequently involving electron‐transfer mediators) and the conducting support, thus switching bioelectrocatalytic processes ON and OFF.…”

Section: Figurementioning

confidence: 57%

Bioelectrocatalytic Electrodes Modified with PQQ‐Glucose Dehydrogenase‐Calmodulin Chimera Switchable by Peptide Signals: Pathway to Generic Bioelectronic Systems Controlled by Biomolecular Inputs

et al. 2019

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Construction of artificial allosteric protein switches is one of the central goals of synthetic biology that holds promise to transform the way we detect and quantify substances in vitro and in vivo. An artificial chimeric fusion protein of pyrroloquinoline quinone‐dependent glucose dehydrogenase with calmodulin (PQQ‐GDH‐CaM) was covalently attached to graphene nanosheets produced electrochemically on a carbon fiber electrode. The chimeric PQQ‐GDH‐CaM represents an artificial allosteric switch activated by association of a calmodulin‐binding peptide with the Ca2+‐bound calmodulin domain. The activity of the immobilized enzyme was switched between active and inactive states by adding/removing the activating peptide. The peptide‐signal switchable features originated from the enzyme 3D‐structural variations induced by the conformational (folding/unfolding) changes in the connected calmodulin unit upon formation/dissociation of its complex with the specific peptide. The peptide‐activated immobilized PQQ‐GDH‐CaM enzyme displayed direct (non‐mediated) electron transfer to the conducting electrode support upon glucose oxidation. On the contrary, in the absence of the peptide, the inactive form of the enzyme demonstrated very low bioelectrocatalytic activity for glucose oxidation. Since the conformational changes of the PQQ‐GDH‐CaM depend on the presence of Ca2+ cations and the calmodulin‐binding peptide, both of them were used as input signals to control the enzyme activity mimicking a Boolean AND logic gate. The switchable behavior of the enzyme‐modified electrode was studied electrochemically and used to assemble a signal‐switchable biofuel cell. The use of the peptide as the signaling messenger enables the design of generalizable bioelectronic systems controlled by native and synthetic biochemical signaling systems.

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Section: Figurementioning

confidence: 57%

Bioelectrocatalytic Electrodes Modified with PQQ‐Glucose Dehydrogenase‐Calmodulin Chimera Switchable by Peptide Signals: Pathway to Generic Bioelectronic Systems Controlled by Biomolecular Inputs

et al. 2019

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“…The present article overviews achievements in design of modified electrodes and electrochemical systems controlled by temperature changes and sharply switchable between active and inactive electrochemical states by temperature alteration. This review continuous a line of recently published review articles on electrodes and electrochemical systems controlled by magnetic signals [9] and pH changes [10], now extending discussion to thermo-sensitive systems.…”

Section: Introductionmentioning

confidence: 99%

Modified Electrodes and Electrochemical Systems Switchable by Temperature Changes

Katz

2016

Electroanalysis

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This article is an overview of extensive research efforts in the area of temperature‐controlled electrochemical systems. Electrochemical reactions, including electrocatalytic and bioelectrocatalytic processes, have been reversibly activated and inhibited by temperature changes. This was achieved by modification of electrode surfaces with thermo‐sensitive polymers (e.g., poly(N‐isopropylacrylamide), PNIPAM) which are reversibly switched by temperature changes between two different structures: swollen expanded coil conformation and shrunken collapsed globule state. While the swollen hydrophilic state allows penetration of redox species to the electrode conducting support and activates electrochemical reactions, the collapsed hydrophobic state isolates the electrode surface and inhibits electrochemical processes. Electrodes modified with the thermo‐switchable polymers have been additionally functionalized with photo‐switchable molecules (e.g., spiropyran derivatives) to achieve double‐controlled electrochemical reactions switchable by temperature changes and light signals. Incorporation of metallic nanoparticles or graphene species in the temperature‐sensitive polymer films resulted in sophisticated features and multi‐signal controlled behavior of the nano‐composite systems.

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“…Electrochemical reactions, including bioelectrocatalytic and electrocatalytic processes, have been reversibly activated and inhibited upon physical translocation and reorientation of different magnetic micro/nano‐species on the electrode surface, particularly using magnetic micro‐and nanoparticles . Recently, the magnetic‐field‐induced orientation of fructose dehydrogenase on iron oxide nanoparticles for enhanced direct electron transfer (DET) has been reported .…”

Section: Introductionmentioning

confidence: 99%

“…[15] Electrochemical reactions, including bioelectrocatalytic and electrocatalytic processes, have been reversibly activated and inhibited upon physical translocation and reorientation of different magnetic micro/nano-species on the electrode surface, particularly using magnetic micro-and nanoparticles. [16] Recently, the magnetic-field-induced orientation of fructose dehydrogenase on iron oxide nanoparticles for enhanced direct electron transfer (DET) has been reported. [18] In this study, the magnetic interactions between the paramagnetic heme groups of fructose dehydrogenase subunit II and superparamagnetic iron oxide nanoparticles enables a suitable orientation of the enzyme molecule and enhance the rate of DET.…”

Section: Introductionmentioning

confidence: 99%

Electrochemical Behavior of Cytochrome C Immobilized in a Magnetically Induced Mesoporous Framework

et al. 2019

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Protein immobilization on electrode surfaces remains a technological challenge and is decisive in enhancing biological properties with simplified operational steps. In view of proposing a new direction for protein immobilization, we report the development of a mesoporous framework resulting from the magnetically induced assembly of magnetite nanoparticles decorated with near‐monodisperse gold nanoparticles onto an indium‐tin‐oxide electrode. With an electrochemically active surface area of about 72 cm2 and pores with an average size of 31±1 nm, this magnetically induced mesoporous framework is suitable for the immobilization of small redox proteins. As a proof‐of‐concept, we show the electrochemical process of cytochrome c, where the mesoporous electrode provided a fourfold enhancement for the faradaic currents in comparison to standard polycrystalline gold electrodes.

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Magneto‐switchable Electrodes and Electrochemical Systems

Cited by 22 publications

References 98 publications

Bioelectrocatalytic Electrodes Modified with PQQ‐Glucose Dehydrogenase‐Calmodulin Chimera Switchable by Peptide Signals: Pathway to Generic Bioelectronic Systems Controlled by Biomolecular Inputs

Bioelectrocatalytic Electrodes Modified with PQQ‐Glucose Dehydrogenase‐Calmodulin Chimera Switchable by Peptide Signals: Pathway to Generic Bioelectronic Systems Controlled by Biomolecular Inputs

Modified Electrodes and Electrochemical Systems Switchable by Temperature Changes

Electrochemical Behavior of Cytochrome C Immobilized in a Magnetically Induced Mesoporous Framework

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