Direct Bioelectrocatalysis of PQQ‐Dependent Glucose Dehydrogenase

Ivnitski, Dmitri; Atanassov, Plamen; Apblett, Christopher A.

doi:10.1002/elan.200703899

Cited by 87 publications

(61 citation statements)

References 49 publications

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“…[9,10] PQQ-GDH and laccase enzymes are known for their direct electron transfer with an electrode support composed of CNTs. [32] Characterization of the enzymemodified electrodes (cyclic voltammetry, enzyme content, etc.) has been described in detail elsewhere.…”

Section: Application Of Systems Controlled By Logical Biomolecular Simentioning

confidence: 99%

Starch‐Powered Biofuel Cell Activated by Logically Processed Biomolecular Signals

Mailloux¹,

MacVittie²,

Privman³

et al. 2014

ChemElectroChem

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An overview of the application of signal‐switchable electrodes in biofuel cells is provided, concentrating on sophisticated systems where logically processed biomolecular signals can activate power production by switchable biofuel cells. The discussion is directed to the formulation of a new concept of physiologically controlled biofuel cells with the power production on demand, particularly in the case of implantable biofuel cells operating in vivo under physiological conditions. The practical realization of the novel concept may be in separating the signal‐processing and power‐producing sub‐systems which communicate electronically. The general conceptual discussion is exemplified with a system where a biomolecular logic system represented by a single Boolean OR logic gate is used to activate enzyme‐release to produce glucose‐biofuel from starch to activate power generation by a biofuel cell. The presented example is aiming at the concept demonstration rather than immediate practical application. Further sophistication of the given example is possible based on the rapidly developing biocomputing approach and integration of signal‐processing systems with switchable materials, electrodes and biofuel cells.

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Section: Application Of Systems Controlled By Logical Biomolecular Simentioning

confidence: 99%

Starch‐Powered Biofuel Cell Activated by Logically Processed Biomolecular Signals

Mailloux¹,

MacVittie²,

Privman³

et al. 2014

ChemElectroChem

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show abstract

“…These include but are not limited to the development of various techniques for sufficient enzyme immobilization trough physical adsorption [8], covalent attachment [9], physical entrapment and tethering of enzymes [10]. Mediators have been used to enhance electron transfer rate [6,9,11] and carbon or mesoporous materials with diameters comparable to the size of the enzyme were explored for enhanced enzyme-electrode interactions [12]. The following approaches provide proper enzyme orientation: specific covalent attachment of enzymes to the electrode surface [13,14]; protein engineering …”

Section: Bottom Up Approach: Integration Of Biocatalysts With Differementioning

confidence: 99%

Untitled

2017

JNMR

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“…Another major advancement was described by Heller [10], where an osmium-based redox hydrogel was employed to immobilize both GOx and copper oxidase on the bioanode and biocathode, respectively. This enabled the communication between the enzyme and the current collector and resulted in a high open circuit voltage of 0.8 V. Moreover, the development of stable and continuous enzymatic biofuel cells designed to catalyze the oxidation of fuel continues to be limited by low power densities [10,29,45,46]. Ivnitski et al [45] employed SingleWalled Carbon Nanotube (SWCNT) anodic substrate modified with Pyroloquinoline Quinone Glucose Dehydrogenase (PQQ-GDH) in the implementation to enhance the power densities generated.…”

Section: Enzymatic Glucose Biofuel Cellsmentioning

confidence: 99%

“…This enabled the communication between the enzyme and the current collector and resulted in a high open circuit voltage of 0.8 V. Moreover, the development of stable and continuous enzymatic biofuel cells designed to catalyze the oxidation of fuel continues to be limited by low power densities [10,29,45,46]. Ivnitski et al [45] employed SingleWalled Carbon Nanotube (SWCNT) anodic substrate modified with Pyroloquinoline Quinone Glucose Dehydrogenase (PQQ-GDH) in the implementation to enhance the power densities generated. The use of SWCNT as the bioanode substrate material in half-cell electrochemistry, for the first time, demonstrated DET between the active sites of PQQ-GDH and SWNT as characterized by cyclic voltammetry.…”

Section: Enzymatic Glucose Biofuel Cellsmentioning

confidence: 99%