The World Health
Organization (WHO) model “List of Essential
Medicines” includes among indispensable medicines antibacterials
and pain and migraine relievers. Monitoring their concentration in
the environment, while challenging, is important in the context of
antibiotic resistance as well as their production of highly toxic
compounds via hydrolysis. Traditional detection methods such as high-performance
liquid chromatography (HPLC) or LC combined with tandem mass spectrometry
or UV–vis spectroscopy are time-consuming, have a high cost,
require skilled operators and are difficult to adapt for field operations.
In contrast, (electrochemical) sensors have elicited interest because
of their rapid response, high selectivity, and sensitivity as well
as potential for on-site detection. Previously, we reported a novel
sensor system based on a type II photosensitizer, which combines the
advantages of enzymatic sensors (high sensitivity) and photoelectrochemical
sensors (easy baseline subtraction). Under red-light illumination,
the photosensitizer produces singlet oxygen which oxidizes phenolic
compounds present in the sample. The subsequent reduction of the oxidized
phenolic compounds at the electrode surface gives rise to a quantifiable
photocurrent and leads to the generation of a redox cycle. Herein
we report the optimization in terms of pH and applied potential of
the photoelectrochemical detection of the hydrolysis product of paracetamol,
i.e., 4-aminophenol (4-AP), and two antibacterials, namely, cefadroxil
(CFD, β-lactam antibiotic) and doxycycline (DXC, tetracycline
antibiotic). The optimized conditions resulted in a detection limit
of 0.2 μmol L–1 for DXC, but in a 10 times
higher sensitivity, 20 nmol L–1, for CFD. An even
higher sensitivity, 7 nmol L–1, was noted for 4-AP.
This article describes the development of an electrochemical screening strategy for 3,4‐methylenedioxymethamphetamine (MDMA), the regular psychoactive compound in ecstasy (XTC) pills. We have investigated the specific electrochemical profile of MDMA and its electro‐oxidation mechanisms at disposable graphite screen‐printed electrodes. We have proved that the formation of a radical cation and subsequent reactions are indeed responsible for the electrode surface passivation, as evidenced by using electron paramagnetic resonance spectroscopy and electrochemistry. Thereafter, pure cutting agents and MDMA as well as simulated binary mixtures of compounds with MDMA were subjected to square wave voltammetry at pH 7 to understand the characteristic electrochemical profile. An additional measurement at pH 12 was able to resolve false positives and negatives occurring at pH 7. Finally, validation of the screening strategy was done by measuring a set of ecstasy street samples. Overall, our proposed electrochemical screening strategy has been demonstrated for the rapid, sensitive, and selective detection of MDMA, resolving most of the false positives and negatives given by the traditional Marquis color tests, thus exhibiting remarkable promises for the on‐site screening of MDMA.
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