The impact of microvascular (dys)regulation on cerebral flow and oxygen heterogeneity

微血管（失调）调节对脑血流和氧异质性的影响

• 批准号: 10216370
• 负责人: David A Boas
• 金额: $ 62.69万
• 依托单位: BOSTON UNIVERSITY (CHARLES RIVER CAMPUS)
• 依托单位国家: 美国
• 财政年份: 2018
• 资助国家: 美国
• 起止时间: 2018-09-01 至 2023-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10216370
• 关键词: Alzheimer' s disease model; Amyloid beta-Protein; Blood Cell Count; Blood Vessels; Blood capillaries; Blood flow; Brain; Brain Diseases; Calcium Signaling; Cell Adhesion; Cell Adhesion Molecules; Cell physiology; Cerebral Ischemia; Cerebral cortex; Cerebrovascular Circulation; Cerebrum; Collaborations; Coupling; Disease; Disease model; Endothelium; Erythrocytes; Event; Exhibits; Frequencies; Goals; Heterogeneity; Hyperglycemia; Hypertension; Image; Imaging Device; Impaired cognition; Incidence; Individual; Inflammation; Interruption; Joints; Lead; Leukocytes; Maps; Measures; Metabolic; Metabolism; Microcirculation; Microscopic; Mus; Nature; Neurons; Nutrient; Obesity; Oxygen; Pathology; Pattern; Pharmacology; Physiological; Physiology; Predisposition; Prevalence; Property; Publications; Recording of previous events; Regulation; Resolution; Role; Secondary to; Speed; Structure; Techniques; Technology; Testing; Therapeutic; Time; Tissues; Work; base; brain cell; cerebral capillary; cognitive performance; constriction; exhaustion; hypoperfusion; improved; mutant; neurovascular coupling; optogenetics; overexpression; performance site; phenomenological models; pressure; spatiotemporal; tissue oxygenation; tool; vascular inflammation

ABSTRACT As the cerebral cortex has no energy reserve, it requires a tight coupling between the supply of nutrients and oxygen and the metabolic demand of the tissue. Small blood vessels, from which nutrients and oxygen are supplied, are hypothesized to be highly heterogeneous in structure and function. The nature and role of this heterogeneity under physiological conditions and how it may lead to pathologies is not fully understood. The size and complexity of the microcirculation and lack of technologies capable of measuring dynamics of the microcirculation have hindered progress. Sophisticated imaging tools with high spatiotemporal resolution are necessary to study the dynamic heterogeneity of the capillary network. This is particularly important for studying a new dynamic phenomenon within the microvasculature which we have recently observed and implicated in brain disease. Specifically, temporary interruptions of blood flow in individual cerebral capillaries (i.e. RBC stalls) are occurring due to the adhesion of cells to the endothelium while passing through the narrow capillary lumen, and the frequency of these stalls increases with high blood cell counts, enhanced inflammation, enhanced expression of amyloid- beta (modeling Alzheimer’s disease (AD)) and cerebral ischemia. These stalls are observed to occur repeatedly in certain capillaries for yet undetermined reasons. Capillary stalls likely introduce flow heterogeneity and pockets of decreased oxygen tension at a very local level, but also, cumulatively, they can have global consequences with or without decreasing the cerebral blood flow. Importantly, our team has shown that pharmacologically reducing the incidence of these stalls in an AD model immediately resulted in improved cognitive performance. This clearly indicates the importance of understanding the universal mechanisms and broader implications of these stalling events that likely result in cognitive decline in a variety of conditions. Our team has been developing a suite of tools that are uniquely suited to study the structural and functional heterogeneity of the microvascular network and the impact on tissue oxygen delivery and function. We are proposing to extend and optimize our techniques to elucidate the specific causes of capillary stalls in normal physiology, why they repeatedly occur in certain segments, if they have any role in capillary-level regulation of neurovascular coupling, and what consequences they have on cerebral metabolism and cell function.

摘要 由于大脑皮层没有能量储备，它需要一个紧密的耦合之间的供应， 营养和氧气以及组织的代谢需求。细小的血管， 营养物质和氧气的供应，假设是高度异质结构 和功能这种异质性在生理条件下的性质和作用，以及它是如何 可能导致的病理还没有完全了解。微循环的大小和复杂性 以及缺乏能够测量微循环动力学的技术阻碍了 中求进工作总需要具有高时空分辨率的复杂成像工具， 研究毛细管网络的动态非均匀性。这一点对于 研究微血管系统中一种新的动力学现象， 与脑部疾病有关具体来说，血液流动的暂时中断， 个别脑毛细血管（即红细胞失速）是由于细胞粘附到 内皮细胞，而通过狭窄的毛细血管腔，以及这些摊位的频率 随着血细胞计数增加，炎症增强，淀粉样蛋白表达增强， β（模拟阿尔茨海默病（AD））和脑缺血。据观察，这些摊位 在某些毛细血管中反复发生，原因不明。可能是毛细血管失速 在非常局部的水平上引入流动不均匀性和氧张力降低的口袋，但是 而且，累积起来，它们可以产生全球性的后果， 血流重要的是，我们的团队已经证明，减少糖尿病的发生率， AD模型中的这些停顿立即导致认知性能的改善。这 清楚地表明了理解普遍机制和更广泛的 这些拖延事件的影响可能导致各种认知能力下降， 条件我们的团队一直在开发一套工具，这些工具非常适合研究 微血管网络的结构和功能异质性及其对组织的影响 氧气输送和功能。我们建议扩展和优化我们的技术， 阐明正常生理中毛细血管失速的具体原因，为什么它们反复发生 在某些节段中，如果它们在神经血管偶联的毛细血管水平调节中有任何作用， 以及它们对大脑代谢和细胞功能的影响。