The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer

Data for a series of fully integrated glucose oxidase, osmium redox polyelectrolyte layers deposited on thiolated gold electrodes by layer-by-layer self assembly was analysed using the relaxation and simplex method described in our earlier work (Flexer et al., 2008) [12]. The layer-by-layer assembly...

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Detalles Bibliográficos
Publicado: 2010
Materias:
Enzyme electrode
Glucose oxidase
Kinetics
Layer-by-layer assembly
Osmium redox polymer
Electrodes
Enzymes
Film preparation
Glucose
Glucose sensors
Gold coatings
Multilayer films
Optimization
Osmium
Polymers
Rate constants
Analysis of data
Analytical expressions
Digital simulation
Enzyme loading
Enzyme molecules
Fully integrated
Glucose concentration
Gold electrodes
Kinetic data
Layer by layer self assembly
Layer-by-layer assemblies
Polyelectrolyte layers
Re-oxidation
Redox hydrogels
Redox polymers
Reproducibilities
Second orders
Simplex methods
Thickness dependence
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15726657_v646_n1-2_p24_Flexer
http://hdl.handle.net/20.500.12110/paper_15726657_v646_n1-2_p24_Flexer
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
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spelling paper:paper_15726657_v646_n1-2_p24_Flexer2023-06-08T16:24:47Z The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer Enzyme electrode Glucose oxidase Kinetics Layer-by-layer assembly Osmium redox polymer Electrodes Enzymes Film preparation Glucose Glucose sensors Gold coatings Multilayer films Optimization Osmium Polymers Rate constants Analysis of data Analytical expressions Digital simulation Enzyme electrode Enzyme loading Enzyme molecules Fully integrated Glucose concentration Gold electrodes Kinetic data Layer by layer self assembly Layer-by-layer assemblies Layer-by-layer assembly Polyelectrolyte layers Re-oxidation Redox hydrogels Redox polymers Reproducibilities Second orders Simplex methods Thickness dependence Glucose oxidase Data for a series of fully integrated glucose oxidase, osmium redox polyelectrolyte layers deposited on thiolated gold electrodes by layer-by-layer self assembly was analysed using the relaxation and simplex method described in our earlier work (Flexer et al., 2008) [12]. The layer-by-layer assembly method allows fine control over the film thickness, enzyme loading, osmium and glucose concentrations with good reproducibility from electrode to electrode. In the analysis we combine the use of approximate analytical expressions with digital simulation to fit the data from an extensive set of experiments. The analysis shows a thickness dependence of the fraction of "wired enzyme molecules" and second order enzyme re-oxidation rate constant for thin films (below 300 nm) following changes in the multilayer film structure. For films thicker than 300 nm the kinetic data approach that of a redox hydrogel. © 2010 Elsevier B.V. All rights reserved. 2010 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15726657_v646_n1-2_p24_Flexer http://hdl.handle.net/20.500.12110/paper_15726657_v646_n1-2_p24_Flexer
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Enzyme electrode
Glucose oxidase
Kinetics
Layer-by-layer assembly
Osmium redox polymer
Electrodes
Enzymes
Film preparation
Glucose
Glucose sensors
Gold coatings
Multilayer films
Optimization
Osmium
Polymers
Rate constants
Analysis of data
Analytical expressions
Digital simulation
Enzyme electrode
Enzyme loading
Enzyme molecules
Fully integrated
Glucose concentration
Gold electrodes
Kinetic data
Layer by layer self assembly
Layer-by-layer assemblies
Layer-by-layer assembly
Polyelectrolyte layers
Re-oxidation
Redox hydrogels
Redox polymers
Reproducibilities
Second orders
Simplex methods
Thickness dependence
Glucose oxidase
spellingShingle Enzyme electrode
Glucose oxidase
Kinetics
Layer-by-layer assembly
Osmium redox polymer
Electrodes
Enzymes
Film preparation
Glucose
Glucose sensors
Gold coatings
Multilayer films
Optimization
Osmium
Polymers
Rate constants
Analysis of data
Analytical expressions
Digital simulation
Enzyme electrode
Enzyme loading
Enzyme molecules
Fully integrated
Glucose concentration
Gold electrodes
Kinetic data
Layer by layer self assembly
Layer-by-layer assemblies
Layer-by-layer assembly
Polyelectrolyte layers
Re-oxidation
Redox hydrogels
Redox polymers
Reproducibilities
Second orders
Simplex methods
Thickness dependence
Glucose oxidase
The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
topic_facet Enzyme electrode
Glucose oxidase
Kinetics
Layer-by-layer assembly
Osmium redox polymer
Electrodes
Enzymes
Film preparation
Glucose
Glucose sensors
Gold coatings
Multilayer films
Optimization
Osmium
Polymers
Rate constants
Analysis of data
Analytical expressions
Digital simulation
Enzyme electrode
Enzyme loading
Enzyme molecules
Fully integrated
Glucose concentration
Gold electrodes
Kinetic data
Layer by layer self assembly
Layer-by-layer assemblies
Layer-by-layer assembly
Polyelectrolyte layers
Re-oxidation
Redox hydrogels
Redox polymers
Reproducibilities
Second orders
Simplex methods
Thickness dependence
Glucose oxidase
description Data for a series of fully integrated glucose oxidase, osmium redox polyelectrolyte layers deposited on thiolated gold electrodes by layer-by-layer self assembly was analysed using the relaxation and simplex method described in our earlier work (Flexer et al., 2008) [12]. The layer-by-layer assembly method allows fine control over the film thickness, enzyme loading, osmium and glucose concentrations with good reproducibility from electrode to electrode. In the analysis we combine the use of approximate analytical expressions with digital simulation to fit the data from an extensive set of experiments. The analysis shows a thickness dependence of the fraction of "wired enzyme molecules" and second order enzyme re-oxidation rate constant for thin films (below 300 nm) following changes in the multilayer film structure. For films thicker than 300 nm the kinetic data approach that of a redox hydrogel. © 2010 Elsevier B.V. All rights reserved.
title The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
title_short The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
title_full The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
title_fullStr The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
title_full_unstemmed The application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
title_sort application of the relaxation and simplex method to the analysis of data for glucose electrodes based on glucose oxidase immobilised in an osmium redox polymer
publishDate 2010
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15726657_v646_n1-2_p24_Flexer
http://hdl.handle.net/20.500.12110/paper_15726657_v646_n1-2_p24_Flexer
_version_ 1768546368722305024

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