Jiayu Xiao scite author profile

Nanozyme‐based chemodynamic therapy (CDT) for fighting bacterial infections faces several major obstacles including low hydrogen peroxide (H2O2) level, over‐expressed glutathione (GSH) in infected sites, and inevitable damage to healthy tissue with abundant nonlocalized nanozymes. Herein, a smart ultrasmall Fe3O4‐decorated polydopamine (PDA/Fe3O4) hybrid nanozyme is demonstrated that continuously converts oxygen into highly toxic hydroxyl radical (•OH) via GSH‐depleted cascade redox reactions for CDT‐mediated bacterial elimination and intensive wound disinfection. In this system, photonic hyperthermia of PDA/Fe3O4 nanozymes can not only directly damage bacteria, but also improve the horseradish peroxidase‐like activity of Fe3O4 decorated for CDT. Surprisingly, through photothermal‐enhanced cascade catalytic reactions, PDA/Fe3O4 nanozymes can consume endogenous GSH for disrupting cellular redox homeostasis and simultaneously provide abundant H2O2 for improving •OH generation, ultimately enhancing the antibacterial performance of CDT. Such PDA/Fe3O4 can bind with bacterial cells, and reveals excellent antibacterial property against both Staphylococcus aureus and Escherichia coli. Most interestingly, PDA/Fe3O4 nanozymes can be strongly retained in infected sites by an external magnet for localized long‐term in vivo CDT and show minimal toxicity to healthy tissues and organs. This work presents an effective strategy to magnetically retain the therapeutic nanozymes in infected sites for highly efficient CDT with good biosafety.

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Delivery of anticancer drug using pH-sensitive micelles from triblock copolymer MPEG-b-PBAE-b-PLA

Yang

Xue

Liu

et al. 2018

Materials Science and Engineering: C

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Magnetically retained and glucose-fueled hydroxyl radical nanogenerators for H2O2-self-supplying chemodynamic therapy of wound infections

Gong

Xiao

et al. 2021

Materials Science and Engineering: C

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Fabrication of PDEAEMA-based pH-responsive mixed micelles for application in controlled doxorubicin release

Yang

Xiao

et al. 2017

RSC Adv.

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Jiayu Xiao

Photothermally activated multifunctional MoS2 bactericidal nanoplatform for combined chemo/photothermal/photodynamic triple-mode therapy of bacterial and biofilm infections

An Ultrasmall Fe₃O₄‐Decorated Polydopamine Hybrid Nanozyme Enables Continuous Conversion of Oxygen into Toxic Hydroxyl Radical via GSH‐Depleted Cascade Redox Reactions for Intensive Wound Disinfection

Delivery of anticancer drug using pH-sensitive micelles from triblock copolymer MPEG-b-PBAE-b-PLA

Magnetically retained and glucose-fueled hydroxyl radical nanogenerators for H2O2-self-supplying chemodynamic therapy of wound infections

Fabrication of PDEAEMA-based pH-responsive mixed micelles for application in controlled doxorubicin release

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Jiayu Xiao

Photothermally activated multifunctional MoS2 bactericidal nanoplatform for combined chemo/photothermal/photodynamic triple-mode therapy of bacterial and biofilm infections

An Ultrasmall Fe3O4‐Decorated Polydopamine Hybrid Nanozyme Enables Continuous Conversion of Oxygen into Toxic Hydroxyl Radical via GSH‐Depleted Cascade Redox Reactions for Intensive Wound Disinfection

Delivery of anticancer drug using pH-sensitive micelles from triblock copolymer MPEG-b-PBAE-b-PLA

Magnetically retained and glucose-fueled hydroxyl radical nanogenerators for H2O2-self-supplying chemodynamic therapy of wound infections

Fabrication of PDEAEMA-based pH-responsive mixed micelles for application in controlled doxorubicin release

Contact Info

Product

Resources

About

An Ultrasmall Fe₃O₄‐Decorated Polydopamine Hybrid Nanozyme Enables Continuous Conversion of Oxygen into Toxic Hydroxyl Radical via GSH‐Depleted Cascade Redox Reactions for Intensive Wound Disinfection