Trimetallic nanocomposite as efficient nanosensors for the electrochemical detection of riboflavin.

A composite is a material in which more than one metal salt or polymer can be mixed to enhance the processed product's physical and chemical properties. Due to their high band gap and enhanced excitation energy, composites can be used in numerous areas, such as solar cells, fuel cells, catalysts, and energy storage. Over a large area of applications in different fields, few studies have examined the ability of composites to sense the efficiency of riboflavin/vitamin B2. The present work explores the utilisation of trimetallic-based nanocomposite nanoparticles (TMNCsNPs) as a sensing material, which is synthesised and characterised in detail. The TMNCsNPs were used to understand the exposure of riboflavin to glassy carbon electrodes (GCE). Several electrochemical parameters were selected for the electrochemical study of the processed sensor. Initially, a long-range concentration of riboflavin (0.976–125 μM in PBS) was selected to check the efficiency of the produced sensor (TMNCsNPs/GCE). Low-to high-potential windows (0.5–15 mV/s) were chosen to measure the effect on TMNCsNPs/GCE in PBS. The chronoamperometry (CA) responses were analysed at different time intervals (0–900 s). The cyclic response (CR) was analysed for TMNCsNPs/GCE sensor for up to one month. The interference of metal was examined, and real sample analysis was also conducted and discussed with possible mechanism. [Display omitted] [ABSTRACT FROM AUTHOR]