Simple voltammetric approach for characterization of two-step surface electrode mechanism in protein-film voltammetry

Simple voltammetric approach for characterization of two-step surface electrode mechanism in protein-film voltammetry

Many enzymes embedding multivalent metal ions or quinone moieties as redox-active centres undergo electrochemical transformation via two successive electron transfer steps. If electrochemical features of such redox enzymes are analyzed with “protein-film voltammetry”, one frequently meets a challeng...

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Bibliographic Details
Published in:Journal of solid state electrochemistry Vol. 24; no. 11-12; pp. 2723 - 2732
Main Authors: Gulaboski, Rubin, Mirceski, Valentin
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-11-2020
Springer Nature B.V
Subjects:
Analytical Chemistry
Characterization and Evaluation of Materials
Chemical reactions
Chemistry
Chemistry and Materials Science
Condensed Matter Physics
Electrochemistry
Electron transfer
Electrons
Energy Storage
Enzymes
Original Paper
Oxidation
Physical Chemistry
Proteins
Quinones
Redox reactions
Substrates
Voltammetry
Kinetics of electron transfer
Protein-film voltammetry
Two-step electrode mechanism
Square-wave voltammetry
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Summary:Many enzymes embedding multivalent metal ions or quinone moieties as redox-active centres undergo electrochemical transformation via two successive electron transfer steps. If electrochemical features of such redox enzymes are analyzed with “protein-film voltammetry”, one frequently meets a challenging reaction scenario where the two electron transfers take place at the same formal potential. Under such conditions, one observes voltammogram with a single oxidation-reduction pattern hiding voltammetric features of both redox reactions. By exploring some aspects of the two-step surface EECrev mechanism one can develop simple methodology under conditions of square-wave voltammetry to enable recognizing and characterizing each electron transfer step. The method relies on the voltammetric features of the second electron transfer, which is coupled to a follow-up chemical reaction. The response of the second electron transfer step shifts to more positive potentials by increasing the rate of the chemical reaction. The proposed methodology can be experimentally applied by modifying the concentration of an electrochemically inactive substrate, which affects the rate of the follow-up chemical reaction. The final voltammetric output is represented by two well-separated square-wave voltammetric peaks that can be further exploited for complete thermodynamic and kinetic analysis of the EECrev mechanism.
ISSN:1432-8488
1433-0768
DOI:10.1007/s10008-020-04563-9