Efficient sonodynamic ablation of deep-seated tumors via cancer-cell-membrane camouflaged biocompatible nanosonosensitizers.

Ultrasound (US)-triggered therapies are promising in cancer treatments, and their effectiveness can be enhanced through the proper camouflage of sonosensitizers. Herein, we have constructed cancer cell membrane (CCM)-camouflaged sonosensitizers for homotypic tumor-targeted sonodynamic therapy (SDT). The camouflaged sonosensitizers have been prepared by encapsulating hemoporfin molecules in poly(lactic acid) polymers (H@PLA) and extruding with CCM from Colon Tumor 26 (CT26) cells, forming the H@PLA@CCM. Under excitation with US, the hemoporfin encapsulated in H@PLA@CCM can convert O into cytotoxic O, which exerts an efficient sonodynamic effect. The H@PLA@CCM nanoparticles show enhanced cellular internalization to CT26 cells compared to H@PLA, and they also can be more efficiently engulfed by CT26 cells than by mouse breast cancer cells, due to the homologous targeting ability of CT26 CCM. After the intravenous injection, the blood circulation half-life of H@PLA@CCM is determined to be 3.23 h which is 4.3-time that of H@PLA. With high biosafety, homogeneous targeting ability, and sonodynamic effect, the combination of H@PLA@CCM and US irradiation has induced significant apoptosis and necrosis of tumor cells through the efficient SDT, achieving the strongest inhibition rate of tumors among other groups. This study provides insights into designing efficient and targeted cancer therapies using CCM-camouflaged sonosensitizers.