Electroanalytical properties of chlorophenol red at disposable carbon electrodes: Implications for Escherichia coli detection

Casimero, Charnete, Bigham, Teri, McGlynn, Ruairi J., Dooley, James S.G., Ternan, Nigel G., Snelling, William J., Critchley, Megan, Zinkel, Cameron Luke, Smith, Robert B orcid iconORCID: 0000-0002-2829-5360 et al (2019) Electroanalytical properties of chlorophenol red at disposable carbon electrodes: Implications for Escherichia coli detection. Bioelectrochemistry, 130 (107321). ISSN 1567-5394

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Official URL: https://doi.org/10.1016/j.bioelechem.2019.06.006

Abstract

The use of coliforms and Escherichia coli as indicator species for assessing the quality of water is well established and a large variety of methods based on β-galactosidase (B-GAL) activity, inherent to the microbes within this classification, have arisen to enable their detection and enumeration. Chlorophenol red (CPR) is widely used as a chromogenic label, but its capacity for translation to electroanalytical devices has yet to be fully explored. The CPR moiety is capable of undergoing oxidation at carbon substrates (+0.7 V) giving rise to a variety of phenolic intermediates. Electrochemical, XPS and enzymatic techniques were employed to characterise the underpinning chemistry and the intermediate identified as a 1,2-quinone derivative in which the chlorine substituent is retained. The latter was found to accumulate at the electrode and, in contrast to the parent CPR, was found to be detected at a significantly less positive potential (+0.3 V). Bacterial hydrolysis of a CPR labelled substrate was demonstrated with the 1,2-quinone oxidation product found to accumulate at the electrode and detected using square wave voltammetry. Proof of concept for the efficacy of the alternative electrode pathway was established through the detection of E.coli after an incubation time of 2.5 h with no interference from the labelled substrates.


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