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DIFFUSION OF SUBSTANCES THROUGH THE BRAIN

物质通过大脑的扩散

基本信息

批准号：
2267063
负责人：
CHARLES NICHOLSON
金额：
$ 24.52万
依托单位：
NEW YORK UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
1990
资助国家：
美国
起止时间：
1990-08-01 至 1996-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/2267063
关键词：
brain cell cell interaction cerebral ischemia /hypoxia chemical kinetics developmental neurobiology diffusion dopamine extracellular fluorescent dye /probe image processing laboratory rat neural plasticity osmotic pressure tissue /cell culture

项目摘要

DESCRIPTION (Investigator's Abstract): The overall goal is to characterize how substances diffuse in the extracellular space of the brain. This will clarify the structure of extracellular space, demonstrate the potential for extracellular chemical communication. The study will help improve therapeutic intervention and aid targeting of drugs and bioactive substances in brain tissue. Appropriate solutions to the diffusion equation will be used to interpret experimental results. All experiments will be made on slices from various brain regions of Sprague-Dawley rats. The three Specific Aims are to: 1) improve optical methods for measuring diffusion 2) quantify the diffusion and uptake of dopamine 3) describe diffusion in the developing brain. Specific Aim 1 is further development of quantitative optical imaging and related theory for analyzing diffusion. New experimental and theoretical methods will use high-resolution imaging of molecules tagged with fluorescent dyes. The technique will be extended to fluorescent dextrans above 70 kDa in molecular weight and proteins. It will measure extracellular volume fraction as well as apparent tortuosity in homogeneous and heterogeneous regions of extracellular space and account for loss of the diffusing substance to the intracellular compartment and at the surfaces of slices. These methods will have wide applicability beyond this proposal. Specific Aim 2 is to study the relative roles of Michaelis-Menten kinetics and diffusion in the migration of dopamine in the extracellular space. Fast-scan cyclic voltametry and numerical solutions to the diffusion equation will describe the behavior of dopamine release by pressure ejection from a micropipette into the neostriatum, the nucleus accumbens and the substantia nigra. This work will help to decide the potential of dopamine as an agent for extra-synaptic volume transmission and will provide data for the modeling of dopamine replacement strategies to ameliorate Parkinson's Disease. Specific Aim 3 is to characterize the diffusion properties of the extracellular space in the normal developing brain and under hypoxia, ischemic and osmotic stress. Fluorescent dextrans and proteins will be used with quantitative optical imaging to determine how the changing structures of the extracellular space affect diffusion in slices of the neocortex, from post- natal day 1 to day 21 and in the adult brain. Slices will also be subjected to hypoxia with and without glucose (to simulate ischemia) and to hypo- and hyperosmotic stress to see how the developing brain structure reacts to these insults. A Monte Carlo simulation will be programmed to model data that cannot be described by analytical or numerical solutions to the diffusion equation. These experiments will aid discussions of the role of diffusion in the developmental process and how susceptible is the structure of extracellular space to various insults at different ages.

描述（研究者摘要）：总体目标是表征物质如何在细胞外空间扩散，个脑袋这将阐明细胞外空间的结构，证明了细胞外化学通讯的潜力。的这项研究将有助于改善治疗干预，药物和生物活性物质。适当的解决办法扩散方程将被用来解释实验结果所有的实验都将在各种大脑切片上进行 Sprague-Dawley大鼠。三个具体目标是：1） 2）量化扩散和多巴胺的摄取3）描述了在发育中的大脑中的扩散。具体目标1是进一步发展定量光学成像，扩散分析的相关理论。新的实验和理论这些方法将使用高分辨率的分子成像技术，荧光染料。该技术将扩展到荧光葡聚糖分子量和蛋白质超过70 kDa。它将测量细胞外容积分数以及表观迂曲度细胞外空间的同质和异质区域，扩散物质损失到细胞内区室，在切片的表面。这些方法具有广泛的适用性除了这个提议。具体目标2是研究Michaelis-Menten的相对作用多巴胺在细胞外迁移的动力学和扩散空间快速扫描循环伏安法及其数值解扩散方程将描述多巴胺释放的行为，压力从微管喷射到新纹状体，大脑和黑质。这项工作将有助于决定多巴胺作为突触外容量传递剂的潜力并将为多巴胺替代的建模提供数据改善帕金森病的策略。具体目标3是表征该化合物的扩散性质。在正常发育的大脑和缺氧情况下的细胞外空间，缺血和渗透压。荧光葡聚糖和蛋白质将被与定量光学成像一起使用，以确定细胞外间隙的结构影响了细胞外间隙切片中的扩散。新皮层，从纳塔尔后第1天到第21天以及在成年大脑中。切片还将经受有和没有葡萄糖的缺氧（以模拟缺血）和低渗和高渗应激，以观察发育中的大脑结构会对这些伤害做出反应蒙特卡罗模拟将被编程以模拟不能由扩散方程的解析解或数值解。这些实验将有助于讨论扩散在发展过程和如何敏感的是结构细胞外空间在不同年龄的各种侮辱。