Tianle Jin, Maoxing Fei, Shiqiao Luo, Handong Wang
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引用次数: 0
Abstract
Intracranial hemorrhage (ICH) causes numerous neurological deficits and deaths worldwide each year, leaving a significant health burden on the public. The pathophysiology of ICH is complicated, and involves both primary and secondary injury. Hematoma, as the prime pathology of ICH, undergoes metabolism and triggers biochemical and biomechanical alterations in the brain, leading to secondary injury. Past endeavors mainly aimed at biochemical-initiated mechanisms for causing secondary injury have made limited progress in recent years, although ICH itself is also highly biomechanics-related. The discovery of the mechanical-activated cation channel Piezo1 provides a new avenue to further explore underlying mechanisms of secondary injury. The current article reviews the structure and gating mechanisms of Piezo1, its roles in the physiology/pathophysiology of neurons, astrocytes, microglia, and bone-marrow-derived macrophages, and especially its roles in erythrocytic turnover and iron metabolism, revealing a potential interplay between the biomechanics and biochemistry of hematoma in ICH. Collectively, these advances provide deeper insights into the secondary injury of ICH and lay the foundations for future research.
颅内出血(ICH)每年在全球范围内造成大量神经功能缺损和死亡,给公众健康带来沉重负担。ICH 的病理生理学非常复杂,涉及原发性和继发性损伤。血肿作为 ICH 的主要病理变化,会发生新陈代谢,引发脑部生化和生物力学改变,导致继发性损伤。尽管 ICH 本身也与生物力学高度相关,但过去主要针对引起继发性损伤的生化机制的研究近年来进展有限。机械激活阳离子通道 Piezo1 的发现为进一步探索继发性损伤的潜在机制提供了新的途径。本文回顾了 Piezo1 的结构和门控机制,它在神经元、星形胶质细胞、小胶质细胞和骨髓衍生巨噬细胞的生理/病理生理学中的作用,特别是它在红细胞周转和铁代谢中的作用,揭示了 ICH 血肿的生物力学和生物化学之间的潜在相互作用。总之,这些进展为深入了解 ICH 的继发性损伤提供了思路,并为未来的研究奠定了基础。
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