Department of Clinical Experimental Research, Glostrup Research Institute, Rigshospitalet Glostrup, Nordstjernevej 42, DK-2600 Glostrup, Denmark.
Department of Drug Design and Pharmacology, Faculty of Health and Medical Sciences, University of Copenhagen, Universitetsparken 2, DK-2100 Copenhagen Oe, Denmark.
Eur J Pharmacol. 2019 Mar 5;846:109-118. doi: 10.1016/j.ejphar.2019.01.007. Epub 2019 Jan 14.
Subarachnoid hemorrhage (SAH) is associated with increased cerebral artery sensitivity to vasoconstrictors and release of the perivascular sensory vasodilator CGRP. In the current study the constrictive phenotype and the vasodilatory effects of exogenous and endogenous perivascular CGRP were characterized in detail applying myograph technology to cerebral artery segments isolated from experimental SAH and sham-operated rats. Following experimental SAH, cerebral arteries exhibited increased vasoconstriction to endothelin-1, 5-hydroxytryptamine and U46419. In addition, depolarization-induced vasoconstriction (60 mM potassium) was significantly increased, supporting a general SAH-associated vasoconstrictive phenotype. Using exogenous CGRP, we demonstrated that sensitivity of the arteries to CGRP-induced vasodilation was unchanged after SAH. However, vasodilation in response to capsaicin (100 nM), a sensory nerve activator used to release perivascular CGRP, was significantly reduced by SAH (P = 0.0079). Because CGRP-mediated dilation is an important counterbalance to increased arterial contractility, a reduction in CGRP release after SAH would exacerbate the vasospasms that occur after SAH. A similar finding was obtained with artery culture (24 h), an in vitro model of SAH-induced vascular dysfunction. The arterial segments maintained sensitivity to exogenous CGRP but showed reduced capsaicin-induced vasodilation. To test whether a metabolically stable CGRP analogue could be used to supplement the loss of perivascular CGRP release in SAH, SAX was systemically administered in our in vivo SAH model. SAX treatment, however, induced CGRP-desensitization and did not prevent the development of vasoconstriction in cerebral arteries after SAH.
蛛网膜下腔出血 (SAH) 与增加脑动脉对血管收缩剂的敏感性和释放血管周围感觉血管扩张剂 CGRP 有关。在当前的研究中,通过应用肌动描记术技术对从实验性 SAH 和假手术大鼠分离的脑动脉段,详细描述了脑动脉的收缩表型和外源性和内源性血管周围 CGRP 的血管舒张作用。在实验性 SAH 后,脑动脉对内皮素-1、5-羟色胺和 U46419 的血管收缩作用增强。此外,去极化诱导的血管收缩(60mM 钾)显著增加,支持一般的 SAH 相关血管收缩表型。使用外源性 CGRP,我们证明 SAH 后动脉对 CGRP 诱导的血管舒张的敏感性没有改变。然而,对辣椒素(100nM)的血管舒张反应,一种用于释放血管周围 CGRP 的感觉神经激活剂,在 SAH 后显著减少(P=0.0079)。由于 CGRP 介导的舒张是增加动脉收缩性的重要平衡,因此 SAH 后 CGRP 释放减少会加剧 SAH 后发生的血管痉挛。在动脉培养(24 小时)中也得到了类似的发现,这是一种模拟 SAH 诱导的血管功能障碍的体外模型。动脉段保持对外源性 CGRP 的敏感性,但显示出辣椒素诱导的血管舒张减少。为了测试代谢稳定的 CGRP 类似物是否可用于补充 SAH 中血管周围 CGRP 释放的损失,在我们的体内 SAH 模型中系统给予 SAX。然而,SAX 治疗诱导了 CGRP 脱敏,并且不能防止 SAH 后脑动脉的血管收缩发展。
