O2-generating multifunctional polymeric micelles for highly efficient and selective photodynamic-photothermal therapy in melanoma.

Abstract

Photothermal therapy (PTT) and photodynamic therapy (PDT) have received tremendous attention owing to their great potential for tumor treatment. However, two main issues hamper the antitumor performance of PDT: overexpression of glutathione (GSH) in tumors, which consumes PDT-induced reactive oxygen species (ROS), and hypoxia within the tumor microenvironment. The drawbacks of PTT include uneven temperature distribution and the upregulation of the heat-shock proteins in tumors, both of which result in ineffective treatment. To address these issues, a MnO2 doped nano-delivery system (HTIM-PMs) was synthesized by one-step self-assembly of disulfide bond bridged copolymers for indocyanine green (ICG) and MnO2 loading. The surface of polymeric micelles was layered with hyaluronan (HA) and transactivator (TAT) peptides to improve active targeting and increase cell penetration. After internalization, HTIM-PMs showed responsiveness to the tumor microenvironment (acid pH, high glutathione, high H2O2). Breaking the disulfide bond reduced the intratumoral GSH level and simultaneously released the MnO2 and ICG. The released MnO2 further reduced the GSH level and promoted O2 generation, thus enhancing the PDT effect. The PTT-mediated hyperthermia accelerated blood flow, which is beneficial for O2 distribution, and promotes ROS diffusion. These PTT-mediated adjuvant effects further overcame the limitations of PDT and the robust PDT effect in turn compensated for the deficiency of PTT. This promising platform exhibited a significant improvement in the PTT-PDT cancer treatment strategy compared to previously reported nanostructures.