Deficient catalytic sensitivity to the tumor microenvironment
is
a major obstacle to nanozyme-mediated tumor therapy. Electron transfer
is the intrinsic essence for a nanozyme-catalyzed redox reaction.
Here, we developed a nanohole-array-induced metallic molybdenum selenide
(n-MoSe2) that is enriched with Se vacancies
and can serve as an electronic transfer station for cycling electrons
between H2O2 decomposition and glutathione (GSH)
depletion. In a MoSe2 nanohole array, the metallic phase
reaches up to 84.5%, which has been experimentally and theoretically
demonstrated to exhibit ultrasensitive H2O2 responses
and enhanced peroxidase (POD)-like activities for H2O2 thermodynamic heterolysis. More intriguingly, plenty of delocalized
electrons appear due to phase- and vacancy-facilitated band structure
reconstruction. Combined with the limited characteristic sizes of
nanoholes, the surface plasmon resonance effect can be excited, leading
to the broad absorption spectrum spanning of n-MoSe2 from the visible to near-infrared region (NIR) for photothermal
conversion. Under NIR laser irradiation, metallic MoSe2 is able to induce out-of-balance redox and metabolism homeostasis
in the tumor region, thus significantly improving therapeutic effects.
This study that takes advantage of phase and defect engineering offers
inspiring insights into the development of high-efficiency photothermal
nanozymes.