The primate motor thalamus.

G Percheron, C François, B Talbi, J Yelnik, G Fénelon
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Abstract

The functional parcellation of the motor thalamus of primates has suffered from serious historical and technical drawbacks, which have led to extreme confusion. This is a problem when thalamic stereotaxy is again being use clinically. The cause usually imputed is the historical conflict between two main schools, the Vogt and the 'Anglo-American' (Michigan), which used different nomenclatures. In fact, the reasons are more profound and serious. A combination of them led to: an archaic, rigid conception of the 'thalamic nucleus'; overexploitation of cytoarchitectonic technique, comparative anatomy and cortical connections; underexploitation of subcortical afferent territories; recent misuse of these territories; hesitations in the use of the VA-VL system; and opposition between ventral ('relay') and dorsal ('associative') 'nuclei'. Previous and current parcellations and nomenclatures for the lateral region finally appeared inappropriate. Before presenting a new parcellation and nomenclature for the lateral region, we explain why we did not adopt one of most common or of recently proposed nomenclatures, and were led to make our own. This is established according to rational and historically grounded rules. Precise definition of thalamic elements is provided. A thalamic 'region' is a gross topographic division corresponding to the former nuclei. A 'territory' is defined as the cerebral space filled by afferent endings from one source. When having a distinct topography in a region, a given territory makes a 'subregion'. For each of the studied 'motor' territories a review was made of its known cortical projections. The thalamic space where neurons project to a given cortical target constitutes a 'source space'. Topographical comparison of the sources spaces with territories reveals that there is often no coincidence between different (afferent or efferent) neuronal set spaces. It appears that source spaces are coincident in the pallidal and nigral territories but not in the cerebellar territory where two topographically distinct source spaces could be distinguished. A 'thalamic nucleus' is defined as the intersection of a thalamocortical source space with one territory. A rapid review of the general anatomy of the diencephalon is made. The ('dorsal') thalamus is divided into 'allo-' and 'isothalamus', the latter with 'bushy' and 'microneurons'. The lateral region is isothalamic. The 'motor thalamus' makes the anterior part of the lateral region. The present work aims to analyse the functional anatomy of the 'motor thalamus' by using precise topography and three-dimensional analyses of the subcortical territories receiving from the cerebellar nuclei (part II), the medial nucleus of the pallidum (part III) and the pars reticulata and mixta of the substantia nigra (part IV). Large injections were used to obtain the maximal extent of each territory. A major deficiency of previous studies was inadequate catography. Reliance on ventricular (CA-CP) landmarks observed by use of orthogonal teleradiography is mandatory. A study was made of intra- and interspecific variations and their effect on stereotactic and cartographic precision in macaques. All three subcortical motor afferent territories to the motor thalamus of macaques are examined in precise cartography with three dimensional reconstructions, rotations and 'reslicing'. The motor thalamus is made up of three topographically distinct and separate territories: cerebellar, pallidal territory and nigral. They cover the entire anterior part of the lateral region. There is no polar subdivision without lower afferents in front of the pallidal and nigral territories and thus no reason for isolating a nucleus lateralis polaris or a polar VA. The cerebellar territory is continuous and dense, in front of the somesthetic nucleus and everywhere separate from it. It has a complex three-dimensional shape, strongly convex anteriorly. Its caudal portion is dorsal to the somesthetic nucleus.(ABSTRACT

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灵长类动物的运动丘脑。
灵长类动物运动丘脑的功能分割存在严重的历史和技术缺陷,这导致了极端的混乱。这是一个问题当丘脑立体定位再次在临床上使用时。原因通常归咎于两大学派之间的历史冲突,沃格特学派和盎格鲁-美国学派(密歇根),它们使用了不同的命名法。事实上,原因更为深刻和严重。它们的结合导致了:“丘脑核”这一古老而僵化的概念;过度利用细胞结构技术、比较解剖学和皮层连接;皮层下传入区域开发不足;最近对这些领土的滥用;在使用VA-VL系统时犹豫;腹侧(“接力”)和背侧(“联想”)之间的对立“核”。以前和现在的横向区域的划分和命名最终显得不合适。在提出新的分区和命名法之前,我们解释了为什么我们没有采用最常见的或最近提出的命名法之一,而是被引导制作我们自己的命名法。这是根据理性和历史基础的规则建立起来的。给出了丘脑元素的精确定义。丘脑“区域”是与前核相对应的大体地形划分。一个“区域”被定义为由来自一个来源的传入末梢填充的大脑空间。当一个地区有独特的地形时,一个给定的领土构成一个“次区域”。对于每一个被研究的“运动”区域,我们都对其已知的皮层投影进行了回顾。神经元投射到特定皮层目标的丘脑空间构成了“源空间”。源空间与区域的地形比较表明,不同(传入或传出)神经元集合空间之间通常不存在重合。似乎源空间在苍白部和黑神经区域是一致的,但在小脑区域却不是,在那里可以区分出两个地形不同的源空间。“丘脑核”被定义为丘脑皮质源空间与一个区域的交集。对间脑的一般解剖作一个快速的回顾。(“背侧”)丘脑分为“同侧”和“等丘脑”,后者有“浓密”和“微神经元”。外侧区域是等丘脑区。“运动丘脑”负责外侧区域的前部。本研究旨在通过对小脑核(第二部分)、苍白球内侧核(第三部分)、网状部和黑质混合区(第四部分)接收的皮质下区域进行精确的地形和三维分析,来分析“运动丘脑”的功能解剖。大量注射用于获得每个区域的最大范围。以往研究的一个主要缺陷是编目不足。依靠心室(CA-CP)地标观察使用正交远程放射成像是强制性的。研究了猕猴的种内和种间变异及其对立体定向和制图精度的影响。所有三个皮层下运动传入区域的运动丘脑的猕猴被检查在精确的地图三维重建,旋转和“重切”。运动丘脑由三个地理上截然不同的区域组成:小脑区、白脑区和黑神经区。它们覆盖外侧区域的整个前部。在白脑区和黑神经区前,如果没有较低的传入神经,就没有极区细分,因此没有理由分离出极外侧核或极区区。小脑区是连续而致密的,在体感核前,并在任何地方与之分离。它具有复杂的三维形状,前凸强烈。它的尾端背对着感觉核。(抽象
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Nociception in vertebrates. Proceedings of a symposium at the Society for Experimental Biology. April 1-2, 2004. Gap junctions in the nervous system. Proceedings of a workshop. Rio de Janeiro, Brazil, 6-11 June 1998. Institute of Biophysics "Carlos Chagas Filho" (IBCCF). Space Neuroscience Research. Proceedings of a workshop. Paris, France, April 22-24, 1997. Towards an understanding of integrative brain functions. Analysis at multiple levels. Proceedings of the Nobel Symposium 103. Stockholm, Sweden, 4-6 June 1997.
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