NITROXIDERGIC CEREBROVASCULAR TONE DURING ANESTHESIA

麻醉期间的硝基氧脑血管张力

• 批准号: 6635758
• 负责人: SHAILENDRA JOSHI
• 金额: $ 12.37万
• 依托单位: COLUMBIA UNIVERSITY HEALTH SCIENCES
• 依托单位国家: 美国
• 财政年份: 2001
• 资助国家: 美国
• 起止时间: 2001-03-01 至 2006-02-28
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6635758
• 关键词: anesthesia; baboons; brain circulation; carbachol; cardiovascular pharmacology; cerebroangiography; clinical research; cyclic GMP; drug adverse effect; drug resistance; enzyme inhibitors; human subject; injection /infusion; molecular dynamics; neuroanatomy; neurons; neuroprotectants; neuroregulation; nitric oxide; nitric oxide synthase; nitroferricyanide; postmortem; rest; tissue /cell culture; vascular endothelium

Manipulation of cerebrovascular tone, either directly or indirectly, is an important component of anesthetic and peri-operative care in patients at risk for neurologic injury. This project has the general aim to better characterize the control mechanisms for maintenance of human cerebrovascular tone in health and disease. Such knowledge would greatly facilitate strategies aimed at protecting the brain from permanent damage. In addition to answering mechanistic questions, the proposed studies will also be useful in the development of protocols for acute pharmacologic manipulation of cerebrovascular resistance during anesthesia and surgery in cases where cerebral arterial access is available. This is timely because there is an increasingly frequent use of endovascular surgery for a wide variety of cerebrovascular diseases. It is believed that cerebral blood flow (CBF) is regulated by three main mechanisms: nitric oxide (NO) (predominantly via cGMP), prostaglandins (predominantly via cAMP) and ATP-sensitive K+ channels. This project addresses two specific questions: (1) To what extend does NO influence resting human cerebrovascular tone? (2) What is the relative importance of neuronal versus endothelial nitric oxide synthase (NOS) in influencing resting vascular tone? Our primary hypothesis is that in humans, enothelially-generated NO is a major regulatory influence. Parallel in-vivo (in humans and non-human primates) and in-vitro experiments will be done. In-vivo studies will employ intracarotid infusion of drugs. Intracarotid infusion enables assessment of cerebrovascular effects of a drug in relative isolation from its systemic side-effects. The clinical research will be conducted during cerebral angiography of functionally and angiographically normal cerebral hemispheres. Animal experiments, in baboons, will be conducted in parallel with the clinical research. In vitro studies will be undertaken on intracranial vessels harvested at autopsy from baboons. This parallel model of human and primate is a unique and powerful approach for exploring he full dose-response range of various agonists and antagonists as well as allowing design of optimal protocols utilizing a limited supply of clinical subjects. In addition, in-vitro studies will provide the insight into molecular and cellular mechanisms that regulate cerebrovascular tone. If endothelial-NO is a major determinant of human cerebrovascular tone, neuroprotection using neuronal NOS inhibitors should not compromise tissue perfusion, and intra-arterial NO donors may be useful in manipulation of cerebral perfusion in ischemic brain injury.

直接或间接地控制脑血管紧张度是神经损伤风险患者麻醉和围手术期护理的重要组成部分。 该项目的总体目标是更好地表征在健康和疾病中维持人类脑血管张力的控制机制。 这些知识将极大地促进旨在保护大脑免受永久性损伤的策略。 除了回答机制问题，拟议的研究也将是有用的，在脑动脉通路可用的情况下，在麻醉和手术期间的脑血管阻力的急性药理学操作的协议的发展。 这是及时的，因为血管内手术越来越频繁地用于各种脑血管疾病。据信，脑血流量（CBF）由三种主要机制调节：一氧化氮（NO）（主要通过cGMP）、野牡丹素（主要通过cAMP）和ATP敏感性K+通道。 本项目解决了两个具体问题：（1）NO在多大程度上影响人静息脑血管张力？ (2)在影响静息血管张力方面，神经元与内皮型一氧化氮合酶（NOS）的相对重要性是什么？我们的主要假设是，在人类中，内皮产生的NO是一个主要的监管影响。将进行平行的体内（人类和非人类灵长类动物）和体外实验。 体内研究将采用颈动脉内输注药物。颈动脉内输注使得能够相对独立于其全身副作用来评估药物的脑血管效应。 临床研究将在功能和血管造影正常的大脑半球的脑血管造影期间进行。 在狒狒中进行的动物实验将与临床研究同时进行。 将对狒狒尸检时采集的颅内血管进行体外研究。这种人类和灵长类动物的平行模型是一种独特而强大的方法，用于探索各种激动剂和拮抗剂的全剂量-反应范围，并允许利用有限的临床受试者设计最佳方案。 此外，体外研究将提供对调节脑血管张力的分子和细胞机制的深入了解。 如果内皮-NO是人脑血管紧张度的主要决定因素，则使用神经元NOS抑制剂的神经保护不应损害组织灌注，并且动脉内NO供体可能在缺血性脑损伤的脑灌注操纵中有用。