Decoding the features of important biochemical multistep electron-transfer pathways through the signatures of two-step double-regenerative electrochemical mechanism in square-wave voltammetry

Authors

DOI:

https://doi.org/10.20450/mjcce.2026.3433

Keywords:

EC’ reaction mechanism, enzyme-substrate kinetics, multistep redox mechanisms, electrochemical-catalytic loops, EC’EC” electrochemical mechanism

Abstract

Results from theoretical analyses of a two-step double-regenerative electrochemical mechanism (schematically designated as EC’EC” mechanism), examined for the first time under conditions of square-wave voltammetry, are presented. The primary emphasis is on the relevance of this complex mechanism for getting a more comprehensive understanding of analogous mechanistic pathways that frequently operate under physiological conditions. Such complex mechanistic schemes are typical of many biologically important pathways in which coupled electron-transfer steps are linked to homogeneous regenerative reactions mediated by catalytic substrates, enzymes, stable radical species, or some redox cofactors. Through systematic analysis of the forward and backward square-wave current components, the role of regenerative loops associated with both electron-transfer steps in affecting the voltammetric response and generating distinct electrochemical–catalytic signatures is elucidated. The proposed framework encompasses for the first time the interplay between electron-transfer kinetics, chemical regeneration rates, and mass transport within the time scale imposed by square-wave excitation signal. The results establish a useful framework for a unified mechanistic interpretation of complex bioelectrochemical systems, while offering a robust theoretical basis for kinetic analyses of multistep redox pathways relevant to metabolic processes, enzymatic catalysis, and redox signaling in living organisms.

Author Biography

Rubin Gulaboski, Faculty of Medical Sciences, Goce Delcev University, Stip

Department of Physical Chemistry and Bioelectrochemistry

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Published

2026-05-16

How to Cite

Gulaboski, R. (2026). Decoding the features of important biochemical multistep electron-transfer pathways through the signatures of two-step double-regenerative electrochemical mechanism in square-wave voltammetry . Macedonian Journal of Chemistry and Chemical Engineering, 45(1). https://doi.org/10.20450/mjcce.2026.3433

Issue

Vol. 45 No. 1 (2026)

Section

Electrochemistry

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Copyright (c) 2026 Rubin Gulaboski

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