骨溶解
破骨细胞
化学
骨吸收
癌症研究
细胞生物学
吸收
巨噬细胞
骨重建
免疫系统
多核
下调和上调
生物物理学
细胞凋亡
纳米技术
医学
作者
Minghao Jin,Muge Gu,Keyu Kong,Wenxuan Fan,Sonu Ng,Yuehao Hu,Zhe Wang,Jun Su,Wei-En Yuan,Huiwu Li,Zanjing Zhai
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-01-02
卷期号:20 (2): 1826-1843
被引量:4
标识
DOI:10.1021/acsnano.5c09438
摘要
Prosthesis-associated osteolysis (PAO), driven by a self-perpetuating inflammatory-osteoclastogenic cycle, remains a critical challenge following arthroplasty. Current single-target therapies inadequately address the spatiotemporal heterogeneity of pathological microenvironments: ROS overload during the early immune activation phase and low pH in the osteoclastic resorption phase. This study develops bovine serum albumin (BSA)-coated copper–manganese carbonate nanocomposites (CuMnCO 3 @BSA, CMC) that dynamically coordinate immunosuppressive intervention with osteoclast-specific cuproptosis induction through microenvironment-guided functional switching. In vitro studies demonstrate that at neutral pH, Mn 2+ -mediated SOD/CAT-like nanozyme activity effectively scavenges ROS and reprograms macrophage metabolism to oxidative phosphorylation, thereby suppressing M1 polarization. During late osteoclast differentiation, acid-triggered carbonate decomposition releases Cu 2+, selectively eliminating mature osteoclasts via cuproptosis-mediated mitochondrial lipoylated protein aggregation and TCA cycle collapse. In titanium particle-induced osteolysis models, this dual-functional CMC strategy demonstrates superior therapeutic efficacy to bisphosphonates. This study pioneers a microenvironment-adaptive nanotherapeutic approach, innovatively coupling cuproptosis with immune-metabolic regulation, thereby establishing a novel paradigm for osteolytic disease management.
科研通智能强力驱动
Strongly Powered by AbleSci AI