小胶质细胞
脊髓损伤
过氧化物酶体增殖物激活受体γ
脊髓
脂质代谢
髓鞘
化学
巨噬细胞
细胞生物学
吞噬作用
免疫系统
中枢神经系统
下调和上调
神经保护
信号转导
脂滴
神经炎症
脂质过氧化
医学
新陈代谢
渗透(HVAC)
泡沫电池
免疫学
脂质积聚
内科学
内分泌学
生物
炎症
作者
Mingran Luo,Jiayun Liu,Yang Su,Tao Jiang,Xiajia Wu,Peng Gao,Tao Qin,Mengyuan Wu,Qingqing Li,Shujun Zhang,Baorong He,Yongxiang Wang,Xiaodong Guo,Wei Zhou,Shujie Zhao,Jin Fan,Jian Chen,Guoyong Yin
标识
DOI:10.1002/advs.202506313
摘要
Spinal cord injury (SCI) substantially affects functional capacity and the immune system plays a crucial role in recovery. Examining alterations in microglia metabolism can lead to improved repair mechanisms; however, the molecular subtyping of microglia lacks consensus. In this study, the effects of SCI on macrophages and microglia in mice are investigated to identify tailored therapeutic targets and interventions for patients with SCI. Macrophages infiltrate the spinal cord shortly after injury; however, infiltration decreases over time. Microglial phagocytosis of myelin debris is associated with increased lipid accumulation. Macrophage deletion improves outcomes, whereas microglial deletion worsens them. The PLIN2+ microglia subtype in lipid droplet formation shows abnormal activation of the Pparg signaling pathway compared with that with other subtypes. PPARG promotes lipid metabolism and recovery, and atorvastatin (a PPARG agonist) reverses altered metabolic processes. Macrophages and microglia play complex roles in SCI. Targeting PPARG and its agonists is a promising therapeutic approach for SCI.
科研通智能强力驱动
Strongly Powered by AbleSci AI