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CELLULAR BIOLOGY OF BRAIN MICROVESSELS

脑微血管的细胞生物学

基本信息

批准号：
3349633
负责人：
SAMI I HARIK
金额：
$ 18.24万
依托单位：
CASE WESTERN RESERVE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
1985
资助国家：
美国
起止时间：
1985-09-30 至 1988-09-29
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/3349633
关键词：
adenosine adenosinetriphosphatase angiotensin II arginine vasopressin basement membrane blood brain barrier brain circulation carbonate dehydratase cardiovascular pharmacology cell membrane endoplasmic reticulum gel electrophoresis histochemistry /cytochemistry immunochemistry microcirculation radiotracer vasoactive intestinal peptide

项目摘要

The goals of this proposal are to investigate the basic cellular mechanisms that underlie the complex functions of the brain microcirculation, and how this circulation is controlled to meet the fastidious requirements of the brain. The endothelial cells of brain microvessels stand at the interface between the systemic circulation and nervous tissue, and have a vital role in maintaining a stable environment for neuronal function. To accomplish this, the brain capillary endothelium is endowed with unique features, such as tight intercellular junctions, and a variety of transporters for essential lipid-insoluble molecules like glucose and amino acids. Many gaps remain in our knowledge of the basic cellular mechanisms underlying the complex functions of the brain's blood vessels. The proposed experiments will employ complementary biochemical, pharmacological, and ultrastructural techniques to study the brain microcirculation in intact tissue, and in preparations enriched with isolated microvessels. The experiments will address: (1) Cellular mechanisms by which adenosine and its analogues exert their affects on the cerebral circulation. Adenosine receptors and the adenosine transporter will be investigated in isolated cerebral microvessels by ligand binding techniques. (2) The presence of receptors for putative peptide neurotransmitters which may regulate the cerebral circulation: angiotensin II, vasopressin, cholecystokin, and vasoactive intestinal polypeptide. (3) Ultrastructural investigation of heterogeneities in the distribution of the glucose transporter and sodium, potassium-ATPase in different brain regions, and within the microvascular unit, by immunocytochemical methods. (4) Isolation and biochemical characterization of the basal lamina of brain microvessels. (5) Biochemical determination and possible ultrastructural localization of carbonic anhydrase in cerebral microvessels. A better understanding of how the brain microcirculation functions may be a prerequisite for appreciating the pathophysiology of the cerebral circulation. This research may provide scientific bases for rational therapy of cerebral vascular disorders, metabolic encephalopathies and blood-brain barrier dysfunction.

这项提议的目标是研究基本的细胞机制。这是大脑微循环复杂功能的基础，以及如何这种循环受到控制，以满足大脑。脑微血管内皮细胞站在界面上。在体循环和神经组织之间，起着至关重要的作用维持一个稳定的神经功能环境。要完成这，大脑毛细血管内皮细胞被赋予了独特的功能，如作为紧密的细胞间连接，以及各种转运蛋白必需的脂类不溶分子，如葡萄糖和氨基酸。许多我们对潜在的基本细胞机制的了解仍然存在差距大脑血管的复杂功能。建议数实验将采用互补的生化、药理学和用超微结构技术研究完全性脑微循环组织和富含分离微血管的制剂中。这些实验将解决：(1)腺苷通过哪些细胞机制它的类似物对大脑循环产生影响。腺苷受体和腺苷转运体将在用配基结合技术分离脑微血管。(2) 推定的多肽神经递质受体的存在可能调节脑循环：血管紧张素II、加压素、胆囊素和血管活性肠多肽。(3)超微结构葡萄糖分布的不均一性研究不同脑区的转运蛋白和钠，钾-三磷酸腺苷酶，以及在微血管单位内，通过免疫细胞化学方法。(4) 脑基底板的分离及其生化特性微血管。(5)生化测定和可能的超微结构碳酸酐酶在脑微血管中的定位。更好地了解大脑微循环的功能可能是了解大脑病理生理学的前提条件发行量。这一研究可为理性的治疗脑血管疾病、代谢性脑病和血脑屏障功能障碍。