Abstract

In cancer treatment, efficient delivery of active anticancer drugs into cancer cells is highly desirable for maximizing therapeutic effects and alleviating side effects. In this work, a nanocarrier consisting of an Fe₃O₄ core, a polyglycerol coating, and an octalysine functionality (SPION-PG-Lys₈) has been designed, synthesized and used to deliver a photosensitizer, chlorin e6 (Ce6), into cancer cells for photodynamic therapy (PDT) of cancer cells. SPION-PG-Lys₈ is colloidally stable in various aqueous solutions, showing a high positive zeta potential of 47.2 ± 6.9 mV in pure water. In vitro characterization reveals that SPION-PG-Lys₈ is efficiently taken up by SKOV3 ovarian cancer cells, exhibiting low cytotoxicity, and suppressed autophagy compared to bare SPIONs. Negatively charged Ce6 is thus loaded on the SPION-PG-Lys₈ through electrostatic attraction to yield a SPION-PG-Lys₈/Ce6 nanocomplex with a positive zeta potential of 22.4 ± 4.3 mV. SPION-PG-Lys₈/Ce6 is more easily taken up by the cells than free Ce6, and surprisingly, the internalized SPION-PG-Lys₈/Ce6 is found to be enriched in the mitochondria. SPION-PG-Lys₈/Ce6 exhibits almost no cytotoxicity under dark conditions, but strong photocytotoxicity due to the light-triggered production of reactive oxygen species (ROS) destroying the mitochondria. Taken together, our results highlight the great potential of SPION-PG-Lys₈ as an efficient carrier of Ce6 for photodynamic cancer therapy.