High Performance Glucose/O<sub>2</sub>Biofuel Cell: Effect of Utilizing Purified Laccase with Anthracene-Modified Multi-Walled Carbon Nanotubes

Minson, Michael; Meredith, Matthew T.; Shrier, Alexander; Giroud, Françoise; Hickey, David P.; Glatzhofer, Daniel T.; Minteer, Shelley D.

doi:10.1149/2.062212jes

Cited by 32 publications

(39 citation statements)

References 44 publications

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“…The first category can be further separated into two subcategories composed by enzymes [13], [14] and bacteria [12], [15] respectively. It was shown that the utilization of enzymes for the ORR such as bilirubin oxidase [16], [17], [18], [19], laccase [20], [21], [22] and ascorbate oxidase [22], [23], [24] enhances dramatically the reaction with low overpotentials (within 100 mV) and high reaction kinetics [25], [26], [27]. Unfortunately, due to the low number of active sites, limiting current occurs at relatively low current densities [19].…”

Section: Introductionmentioning

confidence: 99%

Bimetallic platinum group metal-free catalysts for high power generating microbial fuel cells

Kodali

Santoro

Herrera

et al. 2017

Journal of Power Sources

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M1-M2-N-C bimetallic catalysts with M1 as Fe and Co and M2 as Fe, Co, Ni and Mn were synthesized and investigated as cathode catalysts for oxygen reduction reaction (ORR). The catalysts were prepared by Sacrificial Support Method in which silica was the template and aminoantipyrine (AAPyr) was the organic precursor. The electro-catalytic properties of these catalysts were investigated by using rotating ring disk (RRDE) electrode setup in neutral electrolyte. Fe-Mn-AAPyr outperformed Fe-AAPyr that showed higher performances compared to Fe-Co-AAPyr and Fe-Ni-AAPyr in terms of half-wave potential. In parallel, Fe-Co-AAPyr, Co-Mn-AAPyr and Co-Ni-AAPyr outperformed Co-AAPyr. The presence of Co within the catalyst contributed to high peroxide production not desired for efficient ORR. The catalytic capability of the catalysts integrated in air-breathing cathode was also verified. It was found that Co-based catalysts showed an improvement in performance by the addition of second metal compared to simple Co- AAPyr. Fe-based bimetallic materials didn't show improvement compared to Fe-AAPyr with the exception of Fe-Mn-AAPyr catalyst that had the highest performance recorded in this study with maximum power density of 221.8 ± 6.6 μWcm−2. Activated carbon (AC) was used as control and had the lowest performances in RRDE and achieved only 95.6 ± 5.8 μWcm−2 when tested in MFC.

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Section: Introductionmentioning

confidence: 99%

Bimetallic platinum group metal-free catalysts for high power generating microbial fuel cells

Kodali

Santoro

Herrera

et al. 2017

Journal of Power Sources

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“…10,11 In addition the strategy of wiring enzymes has been utilized in developing electrochemical immunoassays, [12][13][14] DNA detection, 15 and enzymatic biofuel cells. [16][17][18][19] Another advantage of redox polymers is that they have demonstrated an ability to electrically communicate with a wide range of redox enzymes such as: amine oxidase, 4 bilirubin oxidase, 20 glucose oxidase, 21 glucose dehydrogenase, 22 lactate oxidase, 9 glycerol oxidase, 9 laccase, 23,24 pyruvate oxidase, 8 horseradish peroxidase, 25 and sulfite oxidase. 3 Given the widespread use of redox polymers it is surprising that there are only a handful reports of combining the enzyme fructose dehydrogenase (FDH) with redox polymers (Table I).…”

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confidence: 99%

Development of Fructose Dehydrogenase-Ferrocene Redox Polymer Films for Biofuel Cell Anodes

Chen

Bamper

Glatzhofer

et al. 2014

J. Electrochem. Soc.

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Novel amperometric fructose electrodes were built by immobilizing fructose dehydrogenase (FDH) in crosslinked films of ferrocenemodified linear poly(ethylenimine) (Fc-C 6 -LPEI). The results showed that the electrochemical and enzymatic response of the sensors was dependent upon the pH of both the enzyme solution and redox polymer solution used to form the crosslinked films. The optimized redox polymer-enzyme film was able to effectively shuttle the electron from the active sites of fructose dehydrogenase to the electrode surface producing current densities of 245 μA/cm 2 in response to saturating fructose concentrations. We also demonstrate that when crosslinked Fc-C 6 -LPEI/FDH films were formed on networks of single-walled carbon nanotubes the current response to fructose increased ∼4 fold reaching a current density of 1.0 mA/cm. 2 Finally we demonstrate that the films could be utilized as bioanodes in enzymatic biofuel cells and produce a power density of 29 μW/ cm 2 .The use of redox polymers to electrically "wire" redox enzymes to electrode supports has been an active area of research since Degani and Heller introduced the concept 25 years ago. 1 Due to the high current output produced by these redox polymer-enzyme hydrogels, a wide variety of bioelectronic devices have been developed such as biosensors for the monitoring of beverages, 2,3 food, 4,5 in vivo metabolites, 6-9 and neurotransmitters. 10,11 In addition the strategy of wiring enzymes has been utilized in developing electrochemical immunoassays, 12-14 DNA detection, 15 and enzymatic biofuel cells. [16][17][18][19] Another advantage of redox polymers is that they have demonstrated an ability to electrically communicate with a wide range of redox enzymes such as: amine oxidase, 4 bilirubin oxidase, 20 glucose oxidase, 21 glucose dehydrogenase, 22 lactate oxidase, 9 glycerol oxidase, 9 laccase, 23,24 pyruvate oxidase, 8 horseradish peroxidase, 25 and sulfite oxidase. 3 Given the widespread use of redox polymers it is surprising that there are only a handful reports of combining the enzyme fructose dehydrogenase (FDH) with redox polymers (Table I). Narvaez et al., first demonstrated the construction of a fructose biosensor by a layer-by-layer (LBL) electrostatic self-assembly of a cationic osmium redox polymer poly[(vinylpyridine)Os(bpy) 2 Cl] (PVP-Os) and FDH on gold electrodes. 26 Similarly, Dominguez et al., also employed the LBL technique to prepare fructose biosensors based on the PVP-Os redox polymer and FDH. 27 More recently, Antiochia et al., reported the preparation of an osmium redox polymer (poly(1-vinylimidiazole) 12 -[osmium(4,4 -dimethyl-2,2 -dipyridyl) 2 Cl 2 ] 2+/+ (PVI-Os) mediated fructose dehydrogenase biosensor by direct wiring of FDH into the PVI-Os hydrogel for the detection of fructose in fruit juices and soft drinks. 2 Finally, Hickey et al, immobilized FDH into a ferrocene-based redox polymer 3-(tetramethylferrocenyl)propyl-modified linear poly(ethylenimine) (FcMe 4 -C 3 -LPEI) to develop bioanodes for fructose as part of an e...

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“…Using controlled immobilization strategies, the onset potential for DET may be shifted higher, 39,40,53 but DET is not observed under the present, less controlled conditions. This may be further explained by the relatively small fraction of laccase that resides within electron Table III tunneling distance of the gold surface.…”

Section: Resultsmentioning

confidence: 61%

Characterization of Enzyme-Redox Hydrogel Thin-Film Electrodes for Improved Utilization

Chakraborty¹,

McClellan²,

Hasselbeck³

et al. 2014

J. Electrochem. Soc.

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Homogeneous, sub-micron thick bioactive films containing redox hydrogels and the enzyme laccase were prepared on gold-coated glass slides via convective self-assembly. Sub-micron film thickness (∼10-50 nm) allowed higher mediator and enzyme utilization by lowering transport limitations. This study demonstrates control of redox hydrogel film morphology by manipulating hydrophilicity, spreading and wetting properties of the hydrogel/electrode interface. Use of a non-ionic surfactant (Triton X-100) enabled spreading of enzyme containing precursor solutions with no negative impact on enzyme activity. Ellipsometry was used to measure filmswelling properties of these systems, square wave voltammetry was employed to estimate the amount of electroactive redox polymer, and cyclic voltammetry enabled estimation of apparent electron diffusivity. This study impacts the design of thin, catalytic films for bioelectronic applications.

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High Performance Glucose/O₂Biofuel Cell: Effect of Utilizing Purified Laccase with Anthracene-Modified Multi-Walled Carbon Nanotubes

Cited by 32 publications

References 44 publications

Bimetallic platinum group metal-free catalysts for high power generating microbial fuel cells

Bimetallic platinum group metal-free catalysts for high power generating microbial fuel cells

Development of Fructose Dehydrogenase-Ferrocene Redox Polymer Films for Biofuel Cell Anodes

Characterization of Enzyme-Redox Hydrogel Thin-Film Electrodes for Improved Utilization

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High Performance Glucose/O2Biofuel Cell: Effect of Utilizing Purified Laccase with Anthracene-Modified Multi-Walled Carbon Nanotubes

Cited by 32 publications

References 44 publications

Bimetallic platinum group metal-free catalysts for high power generating microbial fuel cells

Bimetallic platinum group metal-free catalysts for high power generating microbial fuel cells

Development of Fructose Dehydrogenase-Ferrocene Redox Polymer Films for Biofuel Cell Anodes

Characterization of Enzyme-Redox Hydrogel Thin-Film Electrodes for Improved Utilization

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High Performance Glucose/O₂Biofuel Cell: Effect of Utilizing Purified Laccase with Anthracene-Modified Multi-Walled Carbon Nanotubes