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Steering H2O2 lysis pathway for ROS generation in Prussian blue nanozymes via alkali cation doping

Guancheng Wang, Xiaoli Wei, Kaizheng Feng, Yunfei Wu, Haijiao Dong, Mingze Lu, Wei Du, Qianglong Fang, Ming‐Gang Ju, Jingyuan Ma, Yali Jiang, Haoan Wu, Ming Ma, Yu Zhang

2025Nature Communications15 citationsDOIOpen Access PDF

Abstract

Prussian blue nanoparticles (PBNPs) have emerged as versatile nanozymes with reactive oxygen species (ROS)-scavenging capabilities, predominantly applied in antioxidant therapies. In this work, we present a combined theoretical and experimental study demonstrating that modulating Fe coordination environments can fundamentally reconfigure PBNPs’ catalytic properties, enabling ROS generation and pro-oxidative functionality. Ab initio molecular dynamics revealed different H2O2 lysis mechanisms at Fe sites with varying coordination numbers: Low-coordinated center (FeN4) induced hydrogen atom transfer to form Fe=O species, while high-coordinated FeN5 generated ·OH radicals via H+-assisted homolysis under acidic conditions. Guided by calculations, Cs-doped PBNPs (Cs-PBs) with elevated coordination numbers were synthesized via alkali cation stoichiometric control, leveraging high distribution coefficient and low hydration energy of Cs+. Experimental results confirmed radical generation in Cs-PBs aligned with theoretical predictions. The size-optimized Cs-PBs demonstrated ultrahigh peroxidase-like activity (1182.26 U·mg-1) and outperformed ROS generating properties in both pollutant degradation and chemodynamic therapy. This work redefines PBNPs’ catalytic potential beyond conventional antioxidant roles, and lays the foundation for innovative environmental and therapeutic solutions. While Prussian blue (PB) nanozymes are typically employed as antioxidants, their reactive oxygen species-generating capability remains unexplored. Here, the authors predict by molecular dynamics and identify explicit hydroxyl radical generation in highly crystalline cesium-doped PBs.

Topics & Concepts

Prussian blueChemistryRadicalCatalysisAlkali metalReactive oxygen speciesNanoparticleHydroxyl radicalDegradation (telecommunications)Delocalized electronAntioxidantLysisCombinatorial chemistryPhotochemistryStoichiometryElectron transferNanotechnologyOxygenInorganic chemistryAb initioHydrogenHydrogen peroxideAtom (system on chip)DopingCoordination complexRedoxChemical engineeringMolecular oxygenMolecular switchPollutantHydrogen atomAdvanced Nanomaterials in CatalysisNanoplatforms for cancer theranosticsNanocluster Synthesis and Applications
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