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Synaptic Transmissions in the Basal Ganglia

基底神经节的突触传递

基本信息

批准号：
8059578
负责人：
Hitoshi Kita
金额：
$ 25.04万
依托单位：
UNIVERSITY OF TENNESSEE HEALTH SCI CTR
依托单位国家：
美国
项目类别：
财政年份：
2008
资助国家：
美国
起止时间：
2008-04-01 至 2013-03-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8059578
关键词：
Affect Age-Years Anatomy Animal Model Animals Area Axon Basal Ganglia Brain Cell Nucleus Chronic Cognitive Corpus striatum structure Data Development Dopamine Drug Delivery Systems Electrodes Frequencies Globus Pallidus Health Investigation Laboratories Mediating Membrane Monkeys Motor Names Neurons Operative Surgical Procedures Paralysed Parkinson Disease Parkinsonian Disorders Pathway interactions Patients Pattern Pharmaceutical Preparations Physiologic pulse Physiological Primates Principal Investigator Property Published Comment Pyramidal Tracts Rattus Reading Rest Rodent Model Signal Transduction Site Stimulus Substantia nigra structure Synapses Synaptic Transmission Testing Time aging population base caudate nucleus cognitive control disability dopaminergic neuron implantation in vivo information processing membrane activity motor control pars compacta programs putamen research study response theories

项目摘要

DESCRIPTION (provided by applicant): Parkinson's disease (PD) is a condition in which degeneration of dopamine (DA) containing neurons in the substantia nigra pars compacta leads to motor and cognitive disability. The loss of DA-neurons and their afferents alters neuronal activity of basal ganglia, which are brain areas involved in motor and cognitive control, and impair their information processing mechanism and/or generate improper signals. The most widely accepted theory from the last 15 years is that parkinsonism is due to the imbalance of the two major neuronal pathways in the basal ganglia. The pathways are named as the direct and indirect pathways. The theory assumes that a DA-depletion in the basal ganglia results in a decrease of neuronal activity in the direct pathway and an increase in the indirect pathway. It has become increasingly apparent that when changes in the average firing activity are compared in animal models of PD, the results often do not support this assumption. However, our preliminary data and those of others have strongly suggested that synaptically induced neuronal responses in the direct and indirect pathways were indeed altered in animal models of PD, but the mean firing frequencies were not. However, details of the alterations are still unknown. We believe that the altered synaptic activity is the basis for the abnormal information processes that are associated with abnormal oscillations and synchronization of neuronal activity observed in parkinsonian patients and animals and that this abnormal activity leads to a development of PD. Thus, the proposed physiological and anatomical investigations in primate and rodent model of PD will test the main hypothesis that DA- depletion decreases the gain of the direct and increases the gain of indirect pathways and that the changes of the gains are due to altered synaptic responses, membrane properties, and anatomy of the basal ganglia nuclei the striatum and/or pallidum. The results of proposed investigations will provide new understanding of the flow of signals in the basal ganglia and how the loss of DA affects the neuronal activity patterns and information flow. This information is essential for developing drugs that target specific circuitry involved in the manifestation of parkinsonisms. PUBLIC HEALTH RELEVANCE A large number of people, up to 25% of aging population over 65 years of age, suffer from Parkinson's disease (PD). This study is to reveal the details of the altered synaptic activity and membrane properties in the basal ganglia and aid developing effective surgical treatments and drugs for PD that target specific circuitry of the basal ganglia, the brain areas involved in motor and cognitive control.

描述（由申请人提供）：帕金森病（PD）是一种黑质致密部含有多巴胺（DA）的神经元变性导致运动和认知障碍的疾病。da神经元及其传入神经的缺失改变了基底神经节的神经元活动，损害了基底神经节的信息处理机制或产生不正确的信号。基底神经节是大脑中参与运动和认知控制的区域。在过去的15年里，最被广泛接受的理论是帕金森症是由于基底神经节中两个主要神经通路的不平衡。这些途径分为直接途径和间接途径。该理论认为，基底神经节的da耗竭导致直接途径的神经元活动减少，间接途径的神经元活动增加。越来越明显的是，当在PD动物模型中比较平均放电活动的变化时，结果往往不支持这一假设。然而，我们和其他人的初步数据强烈表明，在PD动物模型中，突触诱导的直接和间接通路的神经元反应确实发生了改变，但平均放电频率没有改变。然而，这些改变的细节仍然未知。我们认为突触活动的改变是帕金森病患者和动物中观察到的与异常振荡和神经元活动同步相关的异常信息处理的基础，这种异常活动导致PD的发展。因此，在灵长类动物和啮齿类动物PD模型中提出的生理和解剖学研究将验证主要假设，即DA-耗损减少了直接通路的增益，增加了间接通路的增益，增益的变化是由于突触反应、膜特性和基底神经节核、纹状体和/或白脑的解剖结构的改变。本研究的结果将对基底神经节的信号流以及失联对神经元活动模式和信息流的影响提供新的认识。这一信息对于开发针对与帕金森病表现有关的特定回路的药物至关重要。65岁以上的老年人口中有多达25%的人患有帕金森病（PD）。本研究旨在揭示基底节区突触活动和膜特性改变的细节，并帮助开发针对基底节区特定回路的有效手术治疗和药物。基底节区是参与运动和认知控制的大脑区域。