Biomimetic superoxide dismutase stabilized by photopolymerization for superoxide anions biosensing and cell monitoring

Photopolymerization strategy, as one of the immobilization methods, has attracted considerable interest because of some advantages, such as easy operation, harmlessness to the biomolecules, and long storage stability. (E)-4-(4-Formylstyryl) pyridine (formylstyrylpyridine) was prepared through Heck reaction and used as a photopolymer material to immobilize biomimetic superoxide dismutase under ultraviolet irradiation (UV) irradiation in a short time. The styrylpyridinium moiety of Formylstyrylpyridine was photoreactive and formed a dimer under UV irradiation. Mn₂P₂O₇ multilayer sheet, a novel superoxide dismutase mimic, was synthesized. The formed photopolymer can immobilize Mn₂P₂O₇ firmly under UV irradiation. On the basis of high catalytic activity of Mn ₂P₂O₇ biomimetic enzyme and long-term stability of Mn₂P₂O₇-formylstyrylpyridine film, after introducing multiwalled carbon nanotubes (MWCNTs), a novel electrochemical biosensing platform called MWCNTs/Mn₂P₂O ₇-formylstyrylpyridine for superoxide anion (O₂ ^•-) detection was constructed. The biosensor displayed good performance for O₂^•- detection and provided a reliable platform to adhere living cells directly on the modified electrode surface. Therefore, the biosensor was successfully applied to vitro determination of O₂^•- released from living cells, which had a promising prospect for living cells monitoring and diagnosis of reactive oxygen species-related diseases.