Electrochemical biosensor based on singlet oxygen generated by molecular photosensitizers

Here a sensing strategy with the integration of photosensitizer and electrochemical analysis was present. The photosensitizer, Zinc(II) tetraphenylporphyrin (ZnTCPP), was functionalized graphene oxide (GO) to form complex (ZnTCPP/GO) as the electrode material and generated singlet-oxygen (O-1(2)) in the presence of air under light illumination. Due to the special electronic structure of O-1(2), hydroquinone (HQ) could react with O-1(2) to produce electrochemically-detectable products, benzoquinone (BQ). Meanwhile, the formed BQ could be reduced on the electrode, completing the redox cycling. The ZnTCPP/GO modified ITO electrode produces a stable and enhanced photocurrent signal under 420 nm irradiation in air saturated buffer, compared with in N-2-saturated buffer. On the other hand, L-glutathione (GSH) as a signalling molecule plays important role in physiological process, which was employed as model to investigated the sensing performance. Coupling with HQ oxidized by O-1(2), a GSH sensor was constructed on the basis the redox cycling of HQ. A sensitive reduction of photocurrent is observed with the addition of GSH, due to the GSH could be oxidized by the generated O-1(2) to form GSSG. The biosensor displayed good performance in a broad concentration range of 0-150 mM, with a lower detection limit of 1.3 mM at an S/N ratio of 3, and could be used in practical application. This work affords a platform for constructing the biosensor with O-1(2) instead of enzyme via on/off light switching. (C) 2021 Elsevier B.V. All rights reserved.