Mitochondria-targeted ROS- and GSH-responsive diselenide-crosslinked polymer dots for programmable paclitaxel release

Enhancing therapeutic efficacy of drugs from reactive oxygen species (ROS) and glutathione (GSH)-responsive matrix and minimizing toxic effects on normal cells remains a challenge in programmable anticancer drug delivery. Herein, ROS- and GSH-responsive paclitaxel (PTX)-loaded polymer dot (PD) with mitochondria-targeting capability was designed by constructing diselenide linkage and triphenylphosphonium (TPP) for tunable PTX release and fluorescence for cancer theranostics. PD-TPP nanocarrier could improve the PTX stability after loading (PD-TPP(PTX)), and the cleavage of diselenide bond in the presence of H₂O₂ and GSH triggered the controllable PTX release, providing higher fluorescence intensity. As the levels of H₂O₂ and GSH are higher in cancer cells compared to normal cells, PTX was selectively released from PD-TPP in cancer cells, reducing cell viability (∼25%) and causing enhanced apoptosis of cancer cells compared to normal cells. The PD-TPP(PTX) selectivity was also reflected by distinct fluorescence intensity in HeLa and PC-3 cells (cancer) compared to CHO-K1 cells (normal). Furthermore, conjugated TPP promoted the PD-TPP(PTX) accumulation in mitochondria due to specific targeting of TPP towards mitochondria, allowing PTX release in mitochondria of cancer cells. Hence, this approach could be a potential strategy to enhance therapeutic efficacy of cancer drugs and minimize the side effects on normal cells.