Unlocking the gasotransmitter: hydrogen sulfide as a multitarget regulator in ischemia-reperfusion injury.

IF 2.9 Q2 MEDICINE, RESEARCH & EXPERIMENTAL

Medical Gas Research Pub Date : 2026-09-01 Epub Date: 2026-01-06 DOI:10.4103/mgr.MEDGASRES-D-25-00100

Ye Chen, Yulin Deng, Rong Tang, Shiqin Li, Zhigang Mei, Jinwen Ge

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Abstract

Ischemia-reperfusion injury, a critical pathophysiological phenomenon in multiple organ systems, remains a formidable therapeutic challenge in clinical practice. As the third endogenously produced gaseous signaling molecule, hydrogen sulfide (H2S) has emerged as a pivotal regulator of diverse physiological processes and pathological cascades. Accumulating evidence indicates that H2S exerts cytoprotective effects against cerebral, cardiac, hepatic, renal, and pulmonary ischemia-reperfusion injuries through multifaceted mechanisms involving mitigation of inflammatory responses, suppression of oxidative stress, modulation of autophagic processes, and inhibition of apoptotic pathways. This comprehensive review systematically examines the endogenous biosynthesis and metabolic regulation of H2S, while elucidating the molecular mechanisms underlying its organ protective effects during ischemia-reperfusion injury. Particular emphasis is placed on the therapeutic potential of H2S synthase isoforms and bioactive metabolites in ischemic pathophysiology. Notably, recent advances in H2S pharmacology have catalyzed the development of novel H2S donors and slow-releasing compounds, including HSDF-NH2, S-allyl cysteine, S-propargyl cysteine, and S-(4-fluorobenzyl)-N-(3,4,5-trimethoxybenzoyl)-L-cysteine. These pharmacological innovations demonstrate enhanced tissue specificity and controlled release kinetics, paving the way for clinical translation of H2S-based therapeutics in ischemia-reperfusion injury management. Future research directions should focus on optimizing drug delivery systems and elucidating the spatiotemporal dynamics of H2S signaling in organ-specific ischemia-reperfusion pathologies.

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释放气体递质：硫化氢在缺血再灌注损伤中的多靶点调节作用。

缺血再灌注损伤是多脏器系统的重要病理生理现象，是临床治疗的一大难题。作为第三种内源性气体信号分子，硫化氢（H2S）已成为多种生理过程和病理级联反应的关键调节因子。越来越多的证据表明，H2S通过多种机制对脑、心、肝、肾和肺缺血再灌注损伤发挥细胞保护作用，包括减轻炎症反应、抑制氧化应激、调节自噬过程和抑制凋亡途径。本文全面系统地研究了H2S的内源性生物合成和代谢调节，同时阐明了其在缺血-再灌注损伤中器官保护作用的分子机制。特别强调H2S合成酶异构体和生物活性代谢物在缺血性病理生理中的治疗潜力。值得注意的是，H2S药理学的最新进展促进了新型H2S供体和缓释化合物的开发，包括HSDF-NH2、S-烯丙基半胱氨酸、S-丙炔半胱氨酸和S-（4-氟苯基）- n -（3,4,5-三甲氧基苯甲酰）- l -半胱氨酸。这些药理学创新证明了增强的组织特异性和控制释放动力学，为h2s治疗在缺血再灌注损伤管理中的临床转化铺平了道路。未来的研究方向应集中在优化给药系统和阐明H2S信号在器官特异性缺血-再灌注病理中的时空动态。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Medical Gas Research MEDICINE, RESEARCH & EXPERIMENTAL-

CiteScore

5.10

自引率

13.80%

发文量

期刊介绍： Medical Gas Research is an open access journal which publishes basic, translational, and clinical research focusing on the neurobiology as well as multidisciplinary aspects of medical gas research and their applications to related disorders. The journal covers all areas of medical gas research, but also has several special sections. Authors can submit directly to these sections, whose peer-review process is overseen by our distinguished Section Editors: Inert gases - Edited by Xuejun Sun and Mark Coburn, Gasotransmitters - Edited by Atsunori Nakao and John Calvert, Oxygen and diving medicine - Edited by Daniel Rossignol and Ke Jian Liu, Anesthetic gases - Edited by Richard Applegate and Zhongcong Xie, Medical gas in other fields of biology - Edited by John Zhang. Medical gas is a large family including oxygen, hydrogen, carbon monoxide, carbon dioxide, nitrogen, xenon, hydrogen sulfide, nitrous oxide, carbon disulfide, argon, helium and other noble gases. These medical gases are used in multiple fields of clinical practice and basic science research including anesthesiology, hyperbaric oxygen medicine, diving medicine, internal medicine, emergency medicine, surgery, and many basic sciences disciplines such as physiology, pharmacology, biochemistry, microbiology and neurosciences. Due to the unique nature of medical gas practice, Medical Gas Research will serve as an information platform for educational and technological advances in the field of medical gas.