线粒体
缺血
医学
血小板
药理学
髓鞘
冲程(发动机)
白质
细胞内
活性氧
灌注
脑缺血
血管平滑肌
中枢神经系统
氧化应激
神经科学
内科学
体育锻炼
内分泌学
神经保护
梗塞
细胞外
再灌注损伤
血管疾病
体外
心脏病学
生物
星形胶质细胞
心肌细胞
化学
细胞生物学
麻醉
离体脑
作者
Toshiki Inaba,Nobukazu Miyamoto,Kenichiro Hira,Chikage Kijima,Yoshifumi Miyauchi,Haibin Xu,Kazo Kanazawa,Yuji UENO,N. Hattori
出处
期刊:MedComm
[Wiley]
日期:2026-01-15
卷期号:7 (2): e70590-e70590
摘要
While thrombolytic therapy can be effective for stroke, many patients are unable to benefit due to time restrictions. In an aging society, sarcopenia, a condition marked by reduced muscle volume, often worsens recovery after stroke. Our study explored how mitochondria, which are abundant in muscle, could aid in stroke recovery through exercise-induced migration. Using mouse models of chronic hypoperfusion and ischemia, alongside in vitro studies with rat primary cells under oxygen-glucose deprivation and CoCl2 exposure, we found that treadmill exercise protected against white matter injury, myelin loss, astroglial formation, and memory deficits observed 28 days post-hypoperfusion. In acute ischemia models, training reduced glial activation and post-stroke complications. Exercise increased mitochondrial levels in muscle and blood, facilitating their migration between tissues via platelets. In vitro, the addition of muscle-derived mitochondria enhanced the survival of neurons, astrocytes, and oligodendrocytes. Notably, platelets carrying mitochondria from treadmill-trained mice significantly improved ischemic white matter injury and mitigated post-stroke complications. This study highlights mitochondria as a critical part of the secretome, suggesting that muscle-derived mitochondria might play a role in the protective effects of remote ischemic preconditioning. Cell-cell mitochondrial migration, therefore, could offer a promising new approach to reducing post-stroke complications and vascular dementia.
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