Pisani Didier F, Blondeau Nicolas
Université Côte d'Azur, CNRS, LP2M, Nice, France.
Laboratories of Excellence Ion Channel Science and Therapeutics, Nice, France.
J Cereb Blood Flow Metab. 2025 May 29:271678X251346277. doi: 10.1177/0271678X251346277.
Stroke is the leading cause of physical disability and death among adults in most Western countries. Consecutive to a vascular occlusion, cells face a brutal reduction in supply of oxygen and glucose and thus an energy failure, which in turn triggers cell death mechanisms. Among brain cells, neurons are the most susceptible to ischemia because of their high metabolic demand and low reservoir of energy substrates. In neurons, glycolysis uses glucose coming from blood or from glycogen stored in astrocytes, underlying the deep astrocyte-neuron metabolic cooperation. During ischemia, both the aerobic and anaerobic pathways and thus energy production are compromised, which disrupts proper cell functioning, notably Na/K ATPase and mitochondria. This results in altered Ca homeostasis and overproduction of ROS, the latter being further exacerbated during the reperfusion phase. Consequently, glucose metabolism in the different brain cell populations plays a central role in injury and recovery after stroke, and has recently emerged as a promising target for therapeutic intervention. In this context, the overall objective of this article is to review the interconnections between stroke and brain glucose metabolism and to explore how its targeting may offer new therapeutic opportunities in addressing the global stroke epidemic.
在大多数西方国家,中风是成年人身体残疾和死亡的主要原因。血管闭塞后,细胞面临氧气和葡萄糖供应的急剧减少,进而导致能量衰竭,这反过来又触发细胞死亡机制。在脑细胞中,神经元因其高代谢需求和低能量底物储备而最易受到缺血影响。在神经元中,糖酵解利用来自血液或星形胶质细胞储存的糖原中的葡萄糖,这体现了星形胶质细胞与神经元之间深层次的代谢合作。缺血期间,有氧和无氧途径以及能量产生均受到损害,这会扰乱细胞的正常功能,尤其是钠/钾ATP酶和线粒体。这会导致钙稳态改变和活性氧(ROS)过度产生,后者在再灌注阶段会进一步加剧。因此,不同脑细胞群体中的葡萄糖代谢在中风后的损伤和恢复中起着核心作用,并且最近已成为治疗干预的一个有前景的靶点。在此背景下,本文的总体目标是综述中风与脑葡萄糖代谢之间的相互联系,并探讨针对脑葡萄糖代谢如何为应对全球中风流行提供新的治疗机会。