神经炎症
中枢神经系统
医学
疾病
神经科学
免疫系统
免疫学
神经系统
小胶质细胞
炎症
线粒体
生物信息学
作者
Shuya Wang,Min Liu,Xiaojing Shi,Tingli Xiong,Ruishi Li,Wenxuan Zheng,Qiong Huang,Yayun Nan,Kelong Ai
标识
DOI:10.1016/j.scib.2026.05.020
摘要
Neuroinflammation has emerged as an important pathogenic factor in central nervous system (CNS) disease, including various neurodegenerative diseases, brain injuries, and autoimmune conditions, affecting approximately 3 billion people worldwide. Mitochondrial dysfunction within neurovascular unit (NVU) cells not only initiates neuronal damage and blood-brain barrier (BBB) disruption but also critically reprograms immunometabolism, shifting microglia and infiltrating immune cells toward a pro-inflammatory, glycolysis-dominant state while impairing anti-inflammatory, oxidative phosphorylation-dependent functions. This metabolic rewiring fuels a vicious, self-amplifying cycle between mitochondrial impairment and sustained neuroinflammation. Consequently, targeting mitochondrial dysfunction has therefore emerged as a promising therapeutic strategy for controlling neuroinflammation. However, the double-membrane structure of mitochondria, coupled with the restrictive BBB, imposes formidable barriers to therapeutic delivery. Nanomedicine offers unprecedented opportunities. Advanced nanodrugs, engineered with mitochondrial-targeting ligands, stimuli-responsive materials, or biomimetic coatings, enable precise delivery of therapeutics directly to impaired mitochondria within the CNS. This review summarizes recent advances in mitochondrial dysfunction-induced neuroinflammation, highlights emerging nanotechnology-based mitochondrial targeting strategies in various CNS diseases, and discusses the existing challenges and future perspectives for translating these approaches into effective CNS therapies.
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