Photodynamic therapy
(PDT) is a promising noninvasive therapeutic
technique and has attracted increasing interests in preclinical trials.
However, the translation from laboratory to clinic often encounters
the problem of undesired dark cytotoxicity of photosensitizers (PSs).
Now, this challenge can be addressed by cascaded substitution activated
phototheranostics using the host–guest strategy. Through electrostatical
complexation of pyridinium-functionalized tetraphenylethylene, namely,
TPE-PHO, and water-soluble calixarene, the dark cytotoxicity of TPE-PHO
is dramatically inhibited. The nanoassemblies of the complex show
enhanced biocompatibility and selectively locate at the cytoplasm
in vitro. When TPE-PHO is competitively displaced from the cavity
of calixarene by 4,4′-benzidine dihydrochloride at the tumor
site, its dark cytotoxicity and photoactivity in tumor tissue are
restored to give efficient PDT efficacy under light irradiation. The
result from cell imaging reveals that TPE-PHO undergoes translocation
from cytoplasm to mitochondria to kill the cancer cells during the
cascaded supramolecular substitution process. In vivo tumor imaging
and therapy are successfully implemented to evaluate the curative
effect. Such a supramolecular strategy avoids tedious molecular synthesis
and opens a new venue to readily tune the PS behaviors.
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