Abstract Reactive oxygen species (ROS) have become an effective tool for tumor treatment. The combination of photodynamic therapy (PDT) and chemodynamic therapy (CDT) takes advantage of various ROS and enhances therapeutic effects. However, the activation of CDT usually occurs before PDT, which hinders the sustained maintenance of hydroxyl radicals (⋅OH) and reduces the treatment efficiency. Herein, we present a light‐triggered nano‐system based on molecular aggregation regulation for converting cancer therapy from PDT/photothermal therapy (PTT) to a long‐lasting CDT. The ordered J‐aggregation enhances the photodynamic properties of the cyanine moiety while simultaneously suppressing the chemodynamic capabilities of the copper‐porphyrin moiety. Upon light irradiation, Cu‐PCy JNPs demonstrate strong photodynamic and photothermal effects. Meanwhile, light triggers a rapid degradation of the cyanine backbone, leading to the destruction of the J‐aggregation. As a result, a long‐lasting CDT is sequentially activated, and the sustained generation of ⋅OH is observed for up to 48 hours, causing potent cellular oxidative stress and apoptosis. Due to their excellent tumor accumulation, Cu‐PCy JNPs exhibit effective in vivo tumor ablation through the converting therapy. This work provides a new approach for effectively prolonging the chemodynamic activity in ROS‐based cancer therapy.
Abstract Reactive oxygen species (ROS) have become an effective tool for tumor treatment. The combination of photodynamic therapy (PDT) and chemodynamic therapy (CDT) takes advantage of various ROS and enhances therapeutic effects. However, the activation of CDT usually occurs before PDT, which hinders the sustained maintenance of hydroxyl radicals (⋅OH) and reduces the treatment efficiency. Herein, we present a light‐triggered nano‐system based on molecular aggregation regulation for converting cancer therapy from PDT/photothermal therapy (PTT) to a long‐lasting CDT. The ordered J‐aggregation enhances the photodynamic properties of the cyanine moiety while simultaneously suppressing the chemodynamic capabilities of the copper‐porphyrin moiety. Upon light irradiation, Cu‐PCy JNPs demonstrate strong photodynamic and photothermal effects. Meanwhile, light triggers a rapid degradation of the cyanine backbone, leading to the destruction of the J‐aggregation. As a result, a long‐lasting CDT is sequentially activated, and the sustained generation of ⋅OH is observed for up to 48 hours, causing potent cellular oxidative stress and apoptosis. Due to their excellent tumor accumulation, Cu‐PCy JNPs exhibit effective in vivo tumor ablation through the converting therapy. This work provides a new approach for effectively prolonging the chemodynamic activity in ROS‐based cancer therapy.
Photothermal therapy has been developed as one of the most attractive strategies for tumour therapy. However, most of the reported photothermal probes still suffer from poor selectivity or specificity for the tumour region during treatment. Herein, a tumour acidic microenvironment activated heptamethine cyanine-based nanoprobe (Cy-TPA NPs) is constructed for fluorescence imaging-guided photothermal therapy with enhanced tumour specificity. Taking advantage of the pH-dependent molecular rearrangement, Cy-TPA NPs under weak acidic conditions exhibit enhanced near-infrared absorption and "turn on" fluorescence and photothermal performance. The "turn on" fluorescence signal in tumour tissues can improve the signal-to-background ratio, providing precise in vivo fluorescence imaging. Moreover, tumour-specific PTT can effectively ablate tumours with reduced damage to the surrounding tissue. Thus, our work presents a promising strategy for significantly improving the precision and specificity of tumour imaging and therapy.
Abstract Organic dyes hold great promise for application in photodynamic therapy (PDT). However, they currently face challenges such as inadequate photodynamic activity, limited tumor penetration, and constraints imposed by tumor hypoxia. Here, a facile and efficient strategy is presented for multi‐enhanced PDT through the fluorination of a squarylium indocyanine dye‐based photosensitizer (FCy). The amphiphilic FCy features perfluorooctane and PEG‐biotin moieties conjugated to a squarylium indocyanine core. In aqueous environments, FCy spontaneously self‐assembles into stable nano‐sized photosensitizers (FCy NPs), demonstrating a high oxygen loading ability attributable to the presence of perfluoroalkyl groups. Consequently, the aggregation of squarylium indocyanine dyes remarkably boosts the photodynamic effect, yielding a 15‐fold improvement in singlet oxygen quantum yield. Owing to the perfluoroalkyl group, FCy NPs exhibit increased endoplasmic reticulum (ER)‐ accumulating abilities, which further induce ER stress upon laser irradiation and enhance the PDT effect. Furthermore, the superior deep tumor penetration ability of FCy NPs is confirmed through both in vitro and in vivo studies. With efficient oxygen supply to the deep tumor regions, FCy NPs demonstrate potent imaging‐guided PDT against hypoxia tumors. The study substantiates the enhanced ER‐accumulating ability of the perfluoroalkyl group and presents a facile fluorination strategy for the multi‐enhancement of photosensitizers.
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