Abstract

Abstract The hypoxia of the tumor microenvironment (TME) seriously restricts the photodynamic therapy (PDT) effect of conventional type‐II photosensitizers, which are highly dependent on O 2 . In this work, a new type‐I photosensitizer (TPE‐TeV‐PPh 3 ) consisting of a tetraphenylethylene group (TPE) as a bioimaging moiety, triphenyl‐phosphine (PPh 3 ) as a mitochondria‐targeting group, and telluroviologen (TeV 2+ ) as a reactive oxygen species (O 2 •− , •OH) generating moiety is developed. The luminescence intensity of TPE‐TeV‐PPh 3 increased significantly after specific oxidation by excess H 2 O 2 in the TME without responding to normal tissues via the formation of Te═O bond, which can be used for monitoring abnormal H 2 O 2 , positioning, and imaging of tumors. TPE‐TeV‐PPh 3 with highly reactive radicals generation and stronger hypoxia tolerance realizes efficient cancer cell killing under hypoxic conditions, achieving 88% tumor growth inhibition. Therefore, TPE‐TeV‐PPh 3 with low phototoxicity in normal tissue achieves tumor imaging and effective PDT toward solid tumors in response to high concentrations of H 2 O 2 in the TME, which provides a new strategy for the development of type‐I photosensitizers.