Microenvironment-Activated Fe-MOF Nanoplatform Enables Controlled Doxorubicin Release and Ferroptosis-Associated Oxidative Damage in MCF-7 Breast Cancer Cells.
Doxorubicin (DOX) is a cornerstone chemotherapeutic for breast cancer; however, its clinical efficacy is limited by inefficient intracellular delivery and dose-limiting off-target toxicity. Microenvironment-responsive nanoplatforms offer a promising strategy to enhance tumor selectivity and therapeutic performance.
A core-shell nanosystem (UTMD) was constructed by coating an NH2-MIL-88B(Fe) metal-organic framework (Fe-MOF) shell onto a UCNP@TiO2 scaffold. The Fe-MOF shell was designed as a dual pH- and glutathione (GSH)-responsive gatekeeper for controlled DOX release. The nanosystem was characterized for structural features, drug loading, and stimulus-responsive release behavior. Cellular uptake, intracellular trafficking, cytotoxicity, and redox-related biochemical changes were evaluated in MCF-7 breast cancer cells and HEK-293 normal cells.
UTMD achieved high encapsulation efficiency (86.5%) and maintained stability under physiological conditions, while enabling accelerated DOX release in acidic and reducing environments. The nanosystem enhanced cellular internalization and promoted nuclear accumulation of DOX in MCF-7 cells. In addition, UTMD induced significant intracellular redox imbalance, characterized by GSH depletion, increased reactive oxygen species levels, and elevated lipid peroxidation, accompanied by mitochondrial membrane potential depolarization. These changes are consistent with ferroptosis-associated oxidative damage. Compared with free DOX, UTMD exhibited improved cytocompatibility in HEK-293 cells.
The Fe-MOF shell functions as a microenvironment-responsive gatekeeper that coordinates controlled drug release with iron-mediated oxidative stress. This integrated design links chemotherapy with ferroptosis-associated mechanisms, improving therapeutic selectivity and mechanistic interpretability.
UTMD represents a microenvironment-activated nanoplatform that enables controlled DOX delivery and ferroptosis-associated oxidative damage. This strategy enhances antitumor efficacy while reducing off-target toxicity, offering potential for improved breast cancer therapy.
A core-shell nanosystem (UTMD) was constructed by coating an NH2-MIL-88B(Fe) metal-organic framework (Fe-MOF) shell onto a UCNP@TiO2 scaffold. The Fe-MOF shell was designed as a dual pH- and glutathione (GSH)-responsive gatekeeper for controlled DOX release. The nanosystem was characterized for structural features, drug loading, and stimulus-responsive release behavior. Cellular uptake, intracellular trafficking, cytotoxicity, and redox-related biochemical changes were evaluated in MCF-7 breast cancer cells and HEK-293 normal cells.
UTMD achieved high encapsulation efficiency (86.5%) and maintained stability under physiological conditions, while enabling accelerated DOX release in acidic and reducing environments. The nanosystem enhanced cellular internalization and promoted nuclear accumulation of DOX in MCF-7 cells. In addition, UTMD induced significant intracellular redox imbalance, characterized by GSH depletion, increased reactive oxygen species levels, and elevated lipid peroxidation, accompanied by mitochondrial membrane potential depolarization. These changes are consistent with ferroptosis-associated oxidative damage. Compared with free DOX, UTMD exhibited improved cytocompatibility in HEK-293 cells.
The Fe-MOF shell functions as a microenvironment-responsive gatekeeper that coordinates controlled drug release with iron-mediated oxidative stress. This integrated design links chemotherapy with ferroptosis-associated mechanisms, improving therapeutic selectivity and mechanistic interpretability.
UTMD represents a microenvironment-activated nanoplatform that enables controlled DOX delivery and ferroptosis-associated oxidative damage. This strategy enhances antitumor efficacy while reducing off-target toxicity, offering potential for improved breast cancer therapy.
Authors
Yuan Yuan, Wu Wu, Zheng Zheng, Wang Wang, Wang Wang, Zheng Zheng, Wang Wang, Wang Wang
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