材料科学
自愈水凝胶
伤口愈合
生物物理学
电场
生物医学工程
纳米技术
刺激
生物相容性
戊二醛
场效应晶体管
催化作用
离子
载流子
共轭体系
生物相容性材料
静电学
化学工程
硅酮
联轴节(管道)
聚赖氨酸
灭菌(经济)
作者
Guiyuan Zhang,Tianyu Gao,Junwu Wei,Peng Huan,Pan Wang,Mengxue Zhang,X X Li
标识
DOI:10.1002/adfm.202526061
摘要
ABSTRACT Thermal burns present significant challenges in infection control and tissue repair, with existing enzymatic and electrical therapies facing issues of unsustainability, invasiveness, and catalytic limitations. Herein, we propose innovative mechanical stretching‐powered ε‐polylysine hydrogels with conjugated Pt single‐atom‐anchored MXenes (Pt‐M). Pt anchoring on self‐reducing Ti‐vacancies of Ti 3 C 2 T x amplifies strain gradient and lattice distortion, enhancing the piezo‐flexoelectric (PFE) response of Pt‐M. Pt single‐atom enzyme (SAzyme)‐catalyzed generation of ∙OH initiates in situ crosslinking of methacrylated ε‐polylysine‐grafted Pt‐M to form wound‐adaptive Pt‐M@PL hydrogels, maximizing wound fitting and skin motion‐derived mechanical force to activate the PFE response. PFE field of Pt‐M dynamically switches the spin state and polarizes charge distribution of Pt SAzymes, altering the rate‐determining step and accelerating O─O bond cleavage and H + adsorption to generate ·OH for antibacterial effect. The high PFE field coupling endogenous ions breaks charge balance within the electrical double layers (EDL) on polylysine molecule chains. The formed directional electric field at the biological interface promotes free diffusion of intracellular ions to conserve adenosine 5'‐triphosphate and macrophage phenotype transition, remodeling the wound microenvironment to enhance tissue regeneration. Thus, these injectable hydrogels generate a self‐powered PFE field to enhance SAzyme catalysis for sterilization and EDL‐directed electric stimulation for the subsequent wound healing.
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