Probing biological redox chemistry with large amplitude Fourier transformed ac voltammetry

Hope Adamson; Alan M. Bond; Alison Parkin

doi:10.1039/c7cc03870d

Probing biological redox chemistry with large amplitude Fourier transformed ac voltammetry

Hope Adamson
, Alan M. Bond
, Alison Parkin

School of Chemistry

Research output: Contribution to journal › Article › Research › peer-review

52 Citations (Scopus)

Abstract

Biological electron-exchange reactions are fundamental to life on earth. Redox reactions underpin respiration, photosynthesis, molecular biosynthesis, cell signalling and protein folding. Chemical, biomedical and future energy technology developments are also inspired by these natural electron transfer processes. Further developments in techniques and data analysis are required to gain a deeper understanding of the redox biochemistry processes that power Nature. This review outlines the new insights gained from developing Fourier transformed ac voltammetry as a tool for protein film electrochemistry.

Original language	English
Pages (from-to)	9519-9533
Number of pages	15
Journal	Chemical Communications
Volume	53
Issue number	69
DOIs	https://doi.org/10.1039/c7cc03870d
Publication status	Published - 2017

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10.1039/c7cc03870d

71312290-oaFinal published version, 4 MB

Cite this

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abstract = "Biological electron-exchange reactions are fundamental to life on earth. Redox reactions underpin respiration, photosynthesis, molecular biosynthesis, cell signalling and protein folding. Chemical, biomedical and future energy technology developments are also inspired by these natural electron transfer processes. Further developments in techniques and data analysis are required to gain a deeper understanding of the redox biochemistry processes that power Nature. This review outlines the new insights gained from developing Fourier transformed ac voltammetry as a tool for protein film electrochemistry.",

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AB - Biological electron-exchange reactions are fundamental to life on earth. Redox reactions underpin respiration, photosynthesis, molecular biosynthesis, cell signalling and protein folding. Chemical, biomedical and future energy technology developments are also inspired by these natural electron transfer processes. Further developments in techniques and data analysis are required to gain a deeper understanding of the redox biochemistry processes that power Nature. This review outlines the new insights gained from developing Fourier transformed ac voltammetry as a tool for protein film electrochemistry.

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Probing biological redox chemistry with large amplitude Fourier transformed ac voltammetry

Abstract

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Advanced dynamic electrochemistry with Bayesian inference

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Probing biological redox chemistry with large amplitude Fourier transformed ac voltammetry

Abstract

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Advanced dynamic electrochemistry with Bayesian inference

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