活性氧
化学
细胞毒性
谷胱甘肽
紫杉醇
体内
多重耐药
肿瘤微环境
药理学
癌细胞
癌症研究
药物输送
细胞内
药品
体外
癌症
阿霉素
抗药性
细胞毒性T细胞
毒性
平衡
氧化应激
氧化还原
化疗
分布(数学)
毒品携带者
化疗增敏剂
丁硫胺
癌症治疗
靶向给药
癌症治疗
细胞
细胞生物学
作者
Lingli Zeng,Ni Ding,Zhiyang Chen,Xin Zheng,Xi Liu,Hao Zhang,Xing Lv,Yining Wang,Youpeng Chen,Mei Hu,Yang Kang
摘要
Conventional chemotherapy is significantly hampered by the inherent hydrophobicity of chemotherapeutic agents, limited tumor-specific targeting, and inadequate intratumoral accumulation, all of which undermine its clinical efficacy. Nonselective distribution of cytotoxic agents leads to suboptimal drug concentrations within tumor tissues, causing systemic toxicity in healthy organs. Tumor microenvironment-responsive nanoplatforms offer a promising strategy for enhancing specificity and efficacy. This study demonstrates the successful development of a nanodrug delivery system, CASS@PTX nanoparticles, where CASS is a cinnamaldehyde-based, disulfide-containing polymer engineered with dual-stimulus responsiveness to glutathione (GSH) depletion and reactive oxygen species (ROS) amplification. This system disrupts intracellular redox homeostasis in tumor cells, triggering the release of encapsulated paclitaxel (PTX) while enhancing chemotherapeutic efficacy through redox-dependent sensitization. GSH consumption and ROS overproduction create a prooxidative microenvironment that enhances PTX-induced apoptosis. Preclinical validation using in vitro cytotoxicity assays and in vivo tumor models demonstrates potent synergistic anti-tumor effects with minimal systemic toxicity. This cascading ROS self-generation strategy represents a promising approach for overcoming multidrug resistance and improving the therapeutic outcomes of cancer chemotherapy.
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