Cerebral blood flow regulation during acute increases in blood pressure: Can cerebral sympathetic nervous activity act as a gatekeeper?

血压急性升高期间的脑血流调节：脑交感神经活动可以充当看门人吗？

• 批准号: RGPIN-2020-06206
• 负责人: Brassard, Patrice
• 金额: $ 2.4万
• 依托单位: Université Laval
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=757695
• 关键词: Cerebral; blood; flow; regulation; during

Research in sleeping lambs suggests that the sympathetic nervous activity (SNA) in the brain has the potential to act as a gatekeeper for the cerebral microcirculation during transient increases in arterial blood pressure. However, whether an elevation in cerebral SNA attenuates cerebral blood flow changes during transient increases in arterial blood pressure remains to be clearly determined in humans. In addition, arterial carbon dioxide and cerebral metabolism will often change in physiological conditions associated with transient increases in arterial blood pressure, which will in turn influence the sympathetic control of the brain circulation. These key cerebral blood flow determinants need to be taken into account to isolate the role of cerebral SNA on cerebral blood flow regulation when arterial blood pressure acutely increases. I propose to identify the role of cerebral SNA during transient increases in arterial blood pressure using a regional approach based on norepinephrine spillover. The overall aim of this research program is to examine the role of cerebral SNA in the regulation of cerebral blood flow during transient increases in arterial blood pressure. SPECIFIC AIM 1: To directly quantify the change in cerebral SNA without the influence of hypocapnia during transient increases in arterial blood pressure, we will measure brain norepinephrine spillover during unilateral isometric handgrip and double leg isometric extension, with end-tidal carbon dioxide partial pressure clamped at baseline value. Then, to examine whether cerebral SNA attenuates the change in cerebral blood flow during transient increases in arterial blood pressure, we will measure brain norepinephrine spillover while pharmacologically blocking sympathetic nerves activity during transient increases in arterial blood pressure using the above-mentioned models. SPECIFIC AIM 2: To examine whether cerebral metabolism attenuates the impact of cerebral SNA on the change in cerebral blood flow during transient increases in arterial blood pressure, we will measure brain norepinephrine spillover, cerebral blood flow and metabolism during infusion of alpha-1 adrenoceptor agonist phenylephrine at rest and during exercise of increasing intensity, with end-tidal carbon dioxide partial pressure clamped at baseline value. Although previous research suggested that global SNA has a gatekeeper role for the brain vessels during transient increases in arterial blood pressure, whether an elevation in cerebral SNA attenuates cerebral blood flow changes when arterial blood pressure acutely increases has not been clearly demonstrated in intact humans. This proposal is a key milestone towards the direct quantification and examination of the specific role of cerebral SNA on human brain blood flow during physiological conditions associated with transient elevations in arterial blood pressure.

对睡着的羔羊的研究表明，在动脉血压短暂上升期间，大脑中的交感神经活动(SNA)有可能成为大脑微循环的守门人。然而，在人类中，大脑SNA的升高是否会减弱动脉血压一过性升高期间的脑血流变化仍有待明确确定。此外，动脉二氧化碳和大脑代谢经常会在与动脉血压短暂升高相关的生理条件下发生变化，这反过来又会影响交感神经对大脑循环的控制。当动脉压急剧升高时，需要考虑这些关键的脑血流决定因素，以分离大脑SNA在脑血流调节中的作用。我建议使用一种基于去甲肾上腺素溢出的区域性方法来确定大脑SNA在动脉血压一过性升高中的作用。这项研究的总体目标是研究大脑SNA在动脉血压一过性升高时调节脑血流量中的作用。具体目的1：为了直接量化动脉血压一过性升高时不受低碳酸血症影响的脑SNA的变化，我们将测量单侧等长握力和双腿等长伸展时去甲肾上腺素的脑溢出，将呼气末二氧化碳分压夹在基线值。然后，为了检验大脑SNA是否能减弱动脉血压一过性升高时脑血流量的变化，我们将使用上述模型测量在动脉血压一过性升高期间用药物阻断交感神经活动的同时脑去甲肾上腺素的溢出。具体目的2：为了研究脑代谢是否能减弱脑SNA对动脉血压一过性升高时脑血流变化的影响，我们将测定静息和递增强度运动时，呼气末二氧化碳分压保持在基线水平的情况下，注射α-1肾上腺素受体激动剂苯肾上腺素时的脑去甲肾上腺素溢出、脑血流量和代谢。尽管先前的研究表明，在动脉血压短暂升高期间，全球SNA对脑血管具有把关作用，但在完好无损的人类中，大脑SNA的升高是否会减弱动脉压急剧上升时的脑血流量变化尚未得到明确证明。这一建议是直接量化和研究大脑SNA在与动脉血压一过性升高相关的生理条件下对人脑血流的特定作用的一个关键里程碑。