High power enzymatic biofuel cell based on naphthoquinone-mediated oxidation of glucose by glucose oxidase in a carbon nanotube 3D matrix

Reuillard, Bertrand; Goff, Alan Le; Agnès, Charles; Holzinger, Michael; Zebda, Abdelkader; Gondran, Chantal; Elouarzaki, Kamal; Cosnier, Serge

doi:10.1039/c3cp50767j

Cited by 158 publications

(146 citation statements)

References 16 publications

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“…Most of these substrates, such as sugars and linear alcohols (glucose, maltose, lactose, ethanol, methanol and fructose), are considered as alternative fuels with high energy densities. [1][2][3][4][5][6][7][8] During recent decades, an exhaustive list of EFCs can be found in the literature aiming to exploit these alternative sources or to develop self-powered electrochemical biosensors working in vitro or in vivo. 6 In EFCs, the fuels undergo bioelectrocatalytic oxidation at the anode operating commonly with flavin adenine dinucleotide-dependent (FAD) oxidases and dehydrogenases as well as nicotinamide adenine dinucleotidedependent (NAD) dehydrogenases.…”

mentioning

confidence: 99%

Cholesterol as a Promising Alternative Energy Source: Bioelectrocatalytic Oxidation Using NAD-Dependent Cholesterol Dehydrogenase in Human Serum

Quah

Abdellaoui

Milton

et al. 2016

J. Electrochem. Soc.

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Cholesterol is an essential structural component of mammalian cells, although elevated concentrations of cholesterol in the human body are linked to atherosclerotic disease. In this context, monitoring physiological cholesterol concentrations is of great interest in medical fields and the concept of producing electrical energy from cholesterol is interesting. In this work, we report the bioelectrocatalytic oxidation of cholesterol with the use of nicotinamide adenine dinucleotide-(NAD) dependent cholesterol dehydrogenase (ChDH) as an alternative enzyme to the commonly-used cholesterol oxidase (ChOx) in bioelectronic applications. To achieve bioelectrocatalytic cholesterol oxidation, ChDH was combined with diaphorase (DH) in a bilayer fashion, whereby DH acts as an intermediary enzyme to facilitate NADH oxidation at a ferrocene redox polymer. Characterization of the resulting bioanode identifies a linear cholesterol response range from 5 μM to 200 μM, with an associated sensitivity of 60.12 mA cm −2 M −1 . Furthermore, an O 2 -reducing biocathode incorporating bilirubin oxidase (BOx) was combined with the cholesterol bioanode into a complete cholesterol/O 2 membrane-less enzymatic fuel cell (EFC).

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mentioning

confidence: 99%

Cholesterol as a Promising Alternative Energy Source: Bioelectrocatalytic Oxidation Using NAD-Dependent Cholesterol Dehydrogenase in Human Serum

Quah

Abdellaoui

Milton

et al. 2016

J. Electrochem. Soc.

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“…[26][27][28] Since the current challenges for biofuel cell development lie in deeper oxidation and improved energy density, 29 recent reports have been mainly focused on disaccharides or polysaccharide based biofuel cells. 30,31 Hickey et al 32 reported an enzyme cascade system employing invertase, fructose dehydrogenase and glucose oxidase immobilized in ferrocene-modified linear poly(ethyleneimine) (Fc-C 6 -LPEI) hydrogel, which was then drop casted onto carbon electrode for catalyzing sucrose oxidation in a biofuel cell.…”

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confidence: 99%

Layer-by-Layer Assembly of Carbon Nanotubes Modified with Invertase/Glucose Dehydrogenase Cascade for Sucrose/O₂Biofuel Cell

Zhang

Arugula

Williams

et al. 2016

J. Electrochem. Soc.

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A layer-by-layer (LbL) assembly technique was employed to modify glassy carbon electrodes (GCEs) and screen printed electrodes (SPEs) utilizing multiwalled carbon nanotubes (MWCNTs)/polyelectrolyte binary composites and an enzyme cascade to facilitate efficient electron transfer in sucrose/O 2 biofuel cell. In this study, MWCNTs immobilized invertase (INV) and glucose dehydrogenase (GDH) were alternatively assembled upon polyethyleneimine (PEI) and DNA nanocomposites to construct a bioanode.[Ni(phendion)(phen)]Cl 2 complex and methylene green (MG) were investigated as redox mediators for electrocatalytic oxidation of NADH at reduced overpotentials. The LbL architecture showed advantages for sequential enzymatic reaction that favored the efficient penetration of substrate and products in a cascade system while MWCNTs facilitated the efficient electron transfer from sucrose oxidation and enhancement of the current density. With a GCE bioanode modified with a MG or Ni complex, the biofuel cell produced a higher power density (μW/cm 2 ) with 145.8% and 130.11% enhancement comparing to a SPE bioanode, respectively. Moreover, the Ni complex modified GCEs and SPEs produced power densities (μW/cm 2 ) 93.7% and 107.0% higher compared to MG modified bioanodes, respectively. The maximum current density of 1400 ± 46 μA/cm 2 was obtained with the Ni complex on GCE at an OCP of 604 ± 17 mV with a maximum power density of 405 ± 6 μW/cm 2 . The LbL assembly showed great feasibility as a simple and efficient way to construct controlled MWCNT-multi-enzyme modified electrodes for biofuel cell applications. Biofuel cells convert the chemical energy of biofuels into electric energy via the enzymatically catalyzed oxidation and reduction reactions. One of the most important factors affecting the performance of fuel cell is the fabrication of bioanode which has great influence in generation of electrical power outputs. Therefore developing effective bioanodes remains critical. Till date, several reports have been published on various approaches to assemble enzymes on the anodes in BFCs utilizing carbon based materials.1-4 Amongst those layerby-layer (LbL) assembly technique via electrostatic interactions of oppositely charged species has emerged as a very attractive way to construct multilayer films of polyelectrolytes, biomolecules, 5 and organic materials 6-8 offering advantages in various fields, such as surface functionalization, 9,10 drug delivery, 11,12 and biosensing. [13][14][15] Its application was considered plausible in the development of amperometric biosensors initiating vast research activities on biosensors comprised of LbL organized multilayers. LbL nanostructures decorated with multi-enzymes were proven to be one of the successful strategies to establish high electrical performance, long-term stability and long lifetime in bioelectronics devices.14,16-18 For example, LbL structures consisting of Au nanoparticles (AuNPs), thiol-functionalized polyaniline and glucose oxidase (GOx) were fabricated for glucose biosensing ...

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“…Currently, high performance glucose biofuel cells mostly employ Carbon Nanotubes (CNTs) as the electrode materials due to their high surface area mediated electron transfer. The development of these nanostructured electrode materials have been show to greatly improve the electroactive area for enzyme immobilization [18,65,66]. Several reports also demonstrated the transition from in vitro to in vivo characterization of enzymatic glucose biofuel cells [13,15,24,25,67,68].…”

Section: In Vivo Implantations Of Enzymatic Biofuel Cellmentioning

confidence: 99%

Enzymatic Glucose Biofuel Cell and its Application

Slaughter¹,

Kulkarni²

2015

J Biochip Tissue Chip

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High power enzymatic biofuel cell based on naphthoquinone-mediated oxidation of glucose by glucose oxidase in a carbon nanotube 3D matrix

Cited by 158 publications

References 16 publications

Cholesterol as a Promising Alternative Energy Source: Bioelectrocatalytic Oxidation Using NAD-Dependent Cholesterol Dehydrogenase in Human Serum

Cholesterol as a Promising Alternative Energy Source: Bioelectrocatalytic Oxidation Using NAD-Dependent Cholesterol Dehydrogenase in Human Serum

Layer-by-Layer Assembly of Carbon Nanotubes Modified with Invertase/Glucose Dehydrogenase Cascade for Sucrose/O₂Biofuel Cell

Enzymatic Glucose Biofuel Cell and its Application

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High power enzymatic biofuel cell based on naphthoquinone-mediated oxidation of glucose by glucose oxidase in a carbon nanotube 3D matrix

Cited by 158 publications

References 16 publications

Cholesterol as a Promising Alternative Energy Source: Bioelectrocatalytic Oxidation Using NAD-Dependent Cholesterol Dehydrogenase in Human Serum

Cholesterol as a Promising Alternative Energy Source: Bioelectrocatalytic Oxidation Using NAD-Dependent Cholesterol Dehydrogenase in Human Serum

Layer-by-Layer Assembly of Carbon Nanotubes Modified with Invertase/Glucose Dehydrogenase Cascade for Sucrose/O2Biofuel Cell

Enzymatic Glucose Biofuel Cell and its Application

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Product

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Layer-by-Layer Assembly of Carbon Nanotubes Modified with Invertase/Glucose Dehydrogenase Cascade for Sucrose/O₂Biofuel Cell