Engineered nanostructures of mixed transition metal sulfides have emerged as promising nanomaterials (NMs) for various electrochemical sensors and biosensors applications, including glucose sensors (GS) and lactic acid sensors (LAS) in clinical aspects. Electrochemical sensors based on nanostructured materials, such as transition metal sulfides and their nanocomposites, including graphene, carbon nanotubes, molecularly imprinted polymers, and metal-organic frameworks, have emerged as potent tools for the monitoring and quantification of biomolecules. Highly sensitive and selective electrochemical detection systems have generally been established credibly by providing new functional surfaces, miniaturization processes, and different nanostructured materials with exceptional characteristics. This review provides an overview of glucose and lactic acid sensors based on transition metal nanomaterials and their nanocomposites with a detailed discussion about the advantages and challenges. The merits of nanoscale transition metal sulphide-based electrochemical sensors and biosensor systems include cost-effectiveness, ease of miniaturization process, energy- and time-efficient, simple preparation, etc. Moreover, online sensing competence is the dynamic strength for sustained progress of electrochemical detection systems, thus fascinating interdisciplinary research. In particular, we discuss the synthesis, characteristics, electrode construction strategies, and uses in electrochemical sensing of glucose and lactic acid primarily based on our most recent research and other reports. In addition, the challenges and future perspectives of the nanostructured transition metal sulfides-based electrochemical sensing and biosensing systems toward the detection of glucose and lactic acid are described.
Keywords: Clinical applications; Electrochemical sensors; Glucose sensors; Lactic acid sensors; Nanostructures; Transition metal sulfides.
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