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Prussian Blue‐Derived Nanocomposite Synergized with Calcium Overload for Three‐Mode ROS Outbreak Generation to Enhance Oncotherapy

Wenting Xu, Hongmei Zhou, Bang-li Hu, Xinqiang Liang, Yanping Tang, Shufang Ning, He Ding, Piaoping Yang, Chen Wang

2024Advanced Healthcare Materials20 citationsDOI

Abstract

Abstract Calcium overload can lead to tumor cell death. However, because of the powerful calcium channel excretory system within tumor cells, simplistic calcium overloads do not allow for an effective antitumor therapy. Hence, the nanoparticles are created with polyethylene glycol (PEG) donor‐modified calcium phosphate (CaP)‐coated, manganese‐doped hollow mesopores Prussian blue (MMPB) encapsulating glucose oxidase (GOx), called GOx@MMPB@CaP‐PEG (GMCP). GMCP with a three‐mode enhancement of intratumor reactive oxygen species (ROS) levels is designed to increase the efficiency of the intracellular calcium overload in tumor cells to enhance its anticancer efficacy. The released exogenous Ca 2+ and the production of cytotoxic ROS resulting from the perfect circulation of the three‐mode ROS outbreak generation that Fenton/Fenton‐like reaction and consumption of glutathione from Fe 2+ /Fe 3+ and Mn 2+ /Mn 3+ circle, and amelioration of hypoxia from MMPB‐guided and GOx‐mediated starvation therapy. Photothermal efficacy‐induced heat generation owing to MMPB accelerates the above reactions. Furthermore, abundant ROS contribute to damage to mitochondria, and the calcium channels of efflux Ca 2+ are inhibited, resulting in a calcium overload. Calcium overload further increases ROS levels and promotes apoptosis of tumor cells to achieve excellent therapy.

Topics & Concepts

CalciumReactive oxygen speciesChemistryCalcium in biologyApoptosisBiophysicsMitochondrionProgrammed cell deathMode of actionBiochemistryCancer researchBiologyOrganic chemistryNanoplatforms for cancer theranosticsAdvanced Nanomaterials in CatalysisSulfur Compounds in Biology