Photodynamic therapy promotes hypoxia‐activated nitrogen mustard drug release

Ran Wang, Maomao He, Zongwei Zhang, Tian Qiu, Yue Xi, Xiaolong Zeng, Jiangli Fan, Wen Sun, Xiaojun Peng
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Abstract

Photodynamic therapy (PDT) has become a promising method for tumor treatment due to its non‐invasive and high spatiotemporal selectivity. However, PDT is still hindered by reactive oxygen species deficiency, because solid tumors feature a hypoxic microenvironment. PDT combined with hypoxia‐activated chemotherapy drugs can effectively induce tumor death, overcoming the limitations of the sole PDT for the fight against hypoxia. Herein, we designed a nanosystem (PCe6AZOM) that enhances the release of hypoxia‐activated drugs (AZOM) by PDT. Under hypoxic conditions, the azo bond of AZOM is cleaved by azo reductase, releasing highly cytotoxic AZOM and resulting in a significant increase in intratumor drug concentration. Meanwhile, the commercial photosensitizer Ce6 can aggravate the oxygen‐poor state during the PDT process and further cause more AZOM release. Moreover, the cascade reactions in the nanosystem could activate singlet oxygen and enhance drug release through 660 nm light laser irradiation, contributing to more effective induction of tumor apoptosis and tumor growth retardation in vitro and in vivo.

Abstract Image

光动力疗法促进缺氧激活的氮芥药物释放
光动力疗法(PDT)因其无创性和高时空选择性,已成为一种前景广阔的肿瘤治疗方法。然而,由于实体瘤具有缺氧微环境的特点,光动力疗法仍然受到活性氧缺乏的阻碍。光动力疗法与缺氧激活化疗药物相结合,能有效诱导肿瘤死亡,克服了单纯光动力疗法在抗缺氧方面的局限性。在此,我们设计了一种纳米系统(PCe6AZOM),它能通过PDT增强缺氧激活药物(AZOM)的释放。在缺氧条件下,AZOM 的偶氮键会被偶氮还原酶裂解,释放出高细胞毒性的 AZOM,从而显著提高肿瘤内的药物浓度。与此同时,商业光敏剂 Ce6 会加剧光透析过程中的缺氧状态,进一步导致更多的 AZOM 释放。此外,纳米系统中的级联反应可激活单线态氧,并通过 660 纳米光激光照射增强药物释放,从而更有效地诱导体外和体内肿瘤凋亡和延缓肿瘤生长。
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