Small-Molecule Probe-Induced In Situ-Sensitized Photoelectrochemical Biosensor for Monitoring & alpha;-Glucosidase Activity

Semiconductor-based photoelectrochemical (PEC) biosensors have garnered significant attention in the field of disease diagnosis and treatment. However, the recognition units of these biosensors are mainly limited to bioactive macromolecules, which hinder the photoelectric response due to their insulating characteristics. In this study, we develop an in situ-sensitized strategy that utilizes a small-molecule probe at the interface of the photoelectrode to accurately detect a-glucosidase (a-Glu) activity. Silane, a prototype small-molecule probe, was surface-modified on graphitic carbon nitride to generate Si nanoparticles upon reacting with hydroquinone, the enzymatic product of a-Glu. The in situ formed heterojunction enhances the light-harvesting property and photoexcited carrier separation efficiency. As a result, the in situ-sensitized PEC biosensor demonstrates excellent accuracy, a low detection limit, and outstanding anti-interference ability, showing good applicability in evaluating a-Glu activity and its inhibitors in human serum samples. This novel in situ sensitization approach using small-molecule probes opens up new avenues for developing simple and efficient PEC biosensing platforms by replacing conventional biorecognition elements.

Automated summary

In this study, an in situ-sensitized photoelectrochemical biosensor using a small-molecule probe was developed for accurate detection of a-glucosidase activity. The in situ sensitization approach enhanced the light-harvesting property and photoexcited carrier separation efficiency, resulting in excellent accuracy, a low detection limit, and outstanding anti-interference ability.