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Abstract
The development of smart drug delivery systems to realize controlled drug release
for highly specific cancer treatment has attracted tremendous attention. Herein, nanoscale
coordination polymers (NCPs) constructed from hafnium ions and bis-(alkylthio) alkene
(BATA), a singlet-oxygen responsive linker, are fabricated and applied as nanocarriers
to realize light-controlled drug release under a rather low optical power density.
In this system, NCPs synthesized through a solvothermal method are sequentially loaded
with chlorin e6 (Ce6), a photosensitizer, and doxorubicin (DOX), a chemotherapeutic
drug, and then coated with lipid bilayer to allow modification with polyethylene glycol
(PEG) to acquire excellent colloidal stability. The singlet oxygen produced by such
NCP-Ce6-DOX-PEG nanocomposite can be used not only for photodynamic therapy, but also
to induce the break of BATA linker and thus the destruction of nanoparticle structures
under light exposure, thereby triggering effective drug release. Notably, with efficient
tumor accumulation after intravenous injection as revealed by CT imaging, those NCP-Ce6-DOX-PEG
nanoparticles could be utilized for combined chemo-photodynamic therapy with great
antitumor efficacy. Thus, this work presents a unique type of NCP-based drug delivery
system with biodegradability, sensitive responses to light, as well as highly efficient
tumor retention for effective cancer combinational treatment.