Pyroptosis induced by photodynamic therapy (PDT) is a promising field in both PDT and immunotherapy for tumors. However, effectively inducing tumor cell pyroptosis while triggering a strong immune response using current photosensitizers remains challenging. Herein, the developed positively charged carbon dots (PCDs) nanoPSs were utilized to modulate tumor cell pyroptosis for the first time through a simple spatiotemporal programming strategy. Briefly, PCDs enabled precisely time-dependent targeting of the cell membrane or lysosome. Upon light irradiation, in vitro studies revealed that lysosome-targeted PDT primarily induced apoptosis, while membrane-targeted PDT triggered pyroptosis, resulting in enhanced PDT efficacy and robust activation of the immune response. Conclusively, in vivo studies demonstrated that PCDs could serve as a novel pyroptosis nanotuner for enhanced photodynamic-immunotherapy, thereby simultaneously eliminating primary tumors and inhibiting distant tumor growth and metastases. This spatiotemporal programming strategy unprecedentedly offers a rejuvenation of aged PSs and expands the biomedical use of CDs in immunotherapy.
Keywords: carbon dots; photodynamic-immunotherapy; pyroptosis; spatiotemporal regulation.