An Amperometric Sensor with Anti-Fouling Properties for Indicating Xylazine Adulterant in Beverages

An Amperometric Sensor with Anti-Fouling Properties for Indicating Xylazine Adulterant in Beverages

Amperometric electrochemical sensing schemes, which are easily fabricated and can directly relate measured current with analyte concentrations, remain a promising strategy for the development of the portable, in situ detection of commonly employed adulterants. Xylazine (XYL) is a non-narcotic compou...

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Bibliographic Details
Main Authors: Arielle Vinnikov, Charles W. Sheppard, Ann H. Wemple, Joyce E. Stern, Michael C. Leopold
Format: Article
Language:English
Published: MDPI AG 2024-10-01
Series:Micromachines
Subjects:
xylazine
beverages
amperometry
sensors
carbon nanotubes
date rape
Online Access:https://www.mdpi.com/2072-666X/15/11/1340
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Summary:Amperometric electrochemical sensing schemes, which are easily fabricated and can directly relate measured current with analyte concentrations, remain a promising strategy for the development of the portable, in situ detection of commonly employed adulterants. Xylazine (XYL) is a non-narcotic compound designed for veterinary use as a sedative known as Rompun<sup>®</sup>. XYL is increasingly being abused as a recreational drug, as an opioid adulterant and, because of its chemical properties, has found unfortunate prominence as a date rape drug spiked into beverages. In this study, a systematic exploration and development of fouling-resistant, amperometric XYL sensors is presented. The sensing strategy features layer-by-layer (LBL) modification of glassy carbon electrodes (GCEs) with carbon nanotubes (CNTs) for sensitivity and the engagement of cyclodextrin host–guest chemistry in conjunction with polyurethane (PU) semi-permeable membranes for selectivity. The optimization of different materials and parameters during development created a greater fundamental understanding of the interfacial electrochemistry, allowing for a more informed subsequent design of effective sensors exhibiting XYL selectivity, effective sensitivity, rapid response times (<20 s), and low estimated limits of detection (~1 ppm). Most importantly, the demonstrated XYL sensors are versatile and robust, easily fabricated from common materials, and can effectively detect XYL at <10 ppm in both common alcoholic and non-alcoholic beverages, requiring only minimal volume (20 µL) of the spiked beverage for a standard addition analysis.
ISSN:2072-666X

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