Fabrication of Praseodymium Vanadate Nanoparticles on Disposable Strip for Rapid and Real-Time Amperometric Sensing of Arsenic Drug Roxarsone

Nanomaterials have versatile properties owing to their high surface-to-volume ratio and can thus be used in a variety of applications. This work focused on applying a facile hydro -thermal strategy to prepare praseodymium vanadate nanoparticles due to the importance of nanoparticles in today's society and the fact that their synthesis might be a challenging endeavor. The structural and morphological characterizations were carried out to confirm the influence of the optimizations on the reaction's outcomes, which revealed praseodymium vanadate (PrVO4) with a tetragonal crystal system. In this regard, the proposed development of electrochemical sensors based on the PrVO4 nanocatalyst for the real-time detection of arsenic drug roxarsone (RXS) is a primary concern. The detection was measured by amperometric (i-t) signals where PrVO4/SPCE, as a new electrochemical sensing medium for RXS detection, increased the sensitivity of the sensor to about similar to 2.5 folds compared to the previously reported ones. In the concentration range of 0.001-551.78 mu M, the suggested PrVO4/ SPCE sensor has a high sensitivity for RXS, with a detection limit of 0.4 nM. Furthermore, the impact of several selected potential interferences, operational stability (2000 s), and reproducibility measurements have no discernible effect on RXS sensing, making it the ideal sensing device feasible for technical analysis. The real-time analysis reveals the excellent efficiency and reliability of the prosed sensor toward RXS detection with favorable recovery ranges between +/- 97.00-99.66% for chicken, egg, water, and urine samples.

Automated summary

This study focuses on the synthesis and application of praseodymium vanadate nanoparticles for the development of an electrochemical sensor for real-time detection of the arsenic drug roxarsone. The nanoparticles were prepared using a facile hydrothermal strategy and characterized for their structure and morphology. The proposed PrVO4/SPCE sensor showed high sensitivity and stability, making it an ideal sensing device for technical analysis.