单线态氧
过氧化氢
活性氧
催化作用
铁质
细胞内
羟基自由基
激进的
癌细胞
细胞毒性
芬顿反应
氧气
癌症
化学
材料科学
癌症治疗
组合化学
过氧化物
生物物理学
限制
光化学
螯合作用
光动力疗法
细胞
细胞毒性T细胞
癌症治疗
作者
Chao Wang,Kongbrailatpam Shitaljit Sharma,Yoon Tae Goo,Vladislav Grigoriev,Constanze Raitmayr,Ana Paula Mesquita Souza,Manali Parag Phawde,Olena R. Taratula,Oleh Taratula
标识
DOI:10.1002/adfm.202529194
摘要
ABSTRACT Chemodynamic therapy (CDT) is an emerging cancer treatment that employs transition metal–based nanoagents to catalyze the conversion of elevated intracellular hydrogen peroxide in malignant cells into cytotoxic hydroxyl radicals (•OH) via Fenton‐like reactions. Recent developments have also introduced CDT agents that generate singlet oxygen ( 1 O 2 ) through the Russell mechanism. However, current nanoplatforms efficiently produce either •OH or 1 O 2 , but not both, and often exhibit suboptimal catalytic activity, thereby limiting the sufficient production of reactive oxygen species (ROS) required for cancer eradication. This report introduces a ferrous metal–organic framework, Fe(II)‐TCPP (tetrakis(4‐carboxyphenyl)porphyrin), as the first nanoagent capable of simultaneously and effectively generating •OH and 1 O 2 through dual catalytic pathways. Its nanoneedle‐like morphology increases the surface area and promotes enhanced ROS production. Cell studies demonstrated selective intracellular generation of •OH and 1 O 2 in cancer cells, resulting in targeted cytotoxicity while sparing non‐malignant cells. Systemic administration of Fe(II)‐TCPP in a breast cancer mouse model resulted in preferential tumor accumulation, robust intratumoral ROS generation, cancer eradication, and prevention of recurrence without systemic toxicity. These findings mark a foundational advance in CDT nanoagents by integrating Fenton and Russell mechanisms into a single platform, enabling the design of multifunctional catalysts with enhanced ROS output and therapeutic efficacy.
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