Tumor microenvironment-activated self-charge-generable metallosupramolecular polymer nanocapsules for photoacoustic imaging-guided targeted synergistic photothermal-chemotherapy

An integrated nanosystem of target, visualization, high circulation stability, and multi-therapy effects represents the leading direction of next generation anti-cancer strategy. Nevertheless, this normally requires elegant multicomponent and hierarchical structure design of nanomaterials, or even a complicated post-treatment procedure, to combine different functions together. Herein, we show that hollow metallosupramolecular polymer nanoparticles (HMPNs) derived from a selective-etching approach based on Kirkendall effect have combined capabilities of (i) facile in-situ guest cargo encapsulation, (ii) reversible surface charge evolution, (iii) excellent photoacoustic property and (vi) highly synergistic photothermal-chemo therapeutic effect. Using DOX as a model drug, we can easily fabricate DOX-HMPNs because the etching process is accompanied with effective matter exchange between outer environment and inner particle, while significantly avoiding the premature drug leakage. Notably, synergistic effect between reversible phenolic hydroxyl ionization and dynamic catechol-Fe-III coordination endows DOX-HMPNs with dramatic self-charge generation ability, thus achieving weakly acidic tumor microenvironment-activated reversible surface charge evolution. We have found that DOX-HMPNs with this self-charge generation feature can effectively achieve prolonged circulation and tumor recognition. Moreover, the cleavage of amine bond can induce the dicassembly of hollow particles in strongly acidic lysosomes, and thus accelerate the release of DOX. This chemotherapy, in combination with the cascade-responsive behavior and photothermal/photoacoustic properties of HMPNs, makes our DOX-HMPNs exhibit synergistic antitumor efficiency and provide promising potential for cancer theranostic application.

Automated summary

The use of hollow metallosupramolecular polymer nanoparticles allows for easy in-situ cargo encapsulation, reversible surface charge evolution, and excellent photoacoustic properties, resulting in a powerful photothermal-chemo therapeutic effect. Additionally, the nanoparticles exhibit self-charge generation ability, prolonged circulation, and tumor recognition, while also accelerating drug release in acidic environments, ultimately showing synergistic antitumor efficiency for potential cancer theranostic application.