This work demonstrates a simple, cost effective and ultrasensitive detection of ethyl parathion, an organophosphorus (OPs) pesticide, using enzyme based fluorometric sensing strategy by employing bimetallic BSA@AuAg nanoclusters (NC). The sensing assay is based on the "quenched off" state of bimetallic NC with the addition of Cu(2+) ions that can be "switched on" due to generation of thiocholine (TCh), a catalytic product of enzymatic reaction of acetylthiocholine (ATCh) using acetylcholinesterase (AChE) enzyme. The generated TCh preferably seize Cu(2+) ions from BSA@AuAg NC-Cu(2+) ensemble and recovered the fluorescence of BSA@AuAg NC. The presence of ethyl parathion can be monitored optically due to its inhibitory action towards AChE enzyme leading to suppression of thiocholine (TCh) formation and subsequently decreases TCh-Cu(2+) interaction that ultimately retrieved quenched off state of bimetallic NC. The synthesized biosensor is appropriate for the ultrasensitive sensing of ethyl parathion in pM range, exhibiting 2.40 pM as lowest limit of detection (LOD) which is the least known so far. Further, the real sample analysis adds on for the appropriateness of the synthesized nanoprobe by depicting excellent reproducibility and robustness. The designed assay proved its specificity towards pesticides in general and ethyl parathion in particular when employed with other commonly used non-OPs pesticides.
        
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Sharma D, Wangoo N, Sharma RK (2021) Sensing platform for pico-molar level detection of ethyl parathion using Au-Ag nanoclusters based enzymatic strategy Talanta221: 121267
Sharma D, Wangoo N, Sharma RK (2021) Talanta221: 121267