炎症
吞噬作用
促炎细胞因子
巨噬细胞
免疫系统
细胞生物学
化学
免疫学
微泡
趋化因子
药物输送
表型
功能(生物学)
潮湿
下调和上调
分泌物
传出细胞增多
川地163
生物
CD64
肿瘤坏死因子α
背景(考古学)
癌症研究
医学
作者
Donglin Cai,Zhelun Li,Wendong Gao,Jiaying Liu,Xiaying Qi,Jie Jin,Yufeng Zhang,Qing Zhang,Lan Xiao,Yin Xiao
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-11-11
标识
DOI:10.1021/acsnano.5c14201
摘要
Aging profoundly compromises immune homeostasis, leaving elderly individuals highly vulnerable to inflammatory diseases. Central to this process is macrophage dysfunction, as macrophages progressively shift toward a pro-inflammatory M1 phenotype with excessive inflammation and impaired phagocytosis. This diminished phagocytic capacity not only weakens host defense but also limits the therapeutic efficacy of nanoparticle (NP)-based antisenescence interventions due to the reduced cellular uptake. Therefore, reversing cellular inflammation and restoring the function of senescent macrophages are crucial in treating inflammatory diseases in the elderly. This article presents an M1-targeted NP to rejuvenate aged macrophages and restore their phagocytosis. Gold nanocages (AuNCs) were camouflaged with E. coli-derived outer membrane vesicles (OMVs) and loaded with dexmedetomidine (dex) to create AuNC-OM-dex. The OMV coating enhanced the uptake of NPs by M1-like aged macrophages through CD64 and CD14-mediated recognition of bacterial membrane components, significantly improving drug delivery efficiency. Once internalized, dex, an anti-inflammatory agent, not only reduced senescence-associated factors but also restored phagocytic function in vitro. Mechanistically, dex rescued phagocytosis in senescent macrophages by suppressing p38-MAPK signaling, a pathway which had not been implicated in age-related phagocytic decline in prior studies. Restoring macrophage phenotype and function enhanced their immunoregulatory capacity, thereby aiding in the control of inflammation in aged inflammatory diseases. Furthermore, AuNC-OM-dex effectively prevented lipopolysaccharide-induced inflammatory bone resorption in an aged mouse model, highlighting its therapeutic potential in vivo. These findings demonstrate a dual-action nanoplatform that both enhances delivery to and rejuvenates aged macrophages, offering a promising therapeutic approach for treating inflammatory diseases associated with aging.
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