Rev Neurol (Paris). 2012 Aug-Sep;168(8-9):569-75. doi: 10.1016/j.neurol.2012.06.015. Epub 2012 Aug 14.
The basal ganglia (BG) have been implicated in different processes that control action such as the control of movement parameters but also in processing cognitive and emotional information from the environment. Here, we review existing anatomical data on the interaction between the BG and the limbic system that support implication of the BG in limbic functions.
The BG form a system that is fairly different from the limbic system, but have strong ties, both anatomical and functional, to the latter. Different models have been proposed. In the parallel model, five segregated circuits from the frontal cortex are individualized and terminate in different regions of the BG and thalamus, before projecting back to their cortical area of origin. Based on the extrafrontal cortical projections, another model has been proposed. It subdivides the cortico-striatal projection into three functional territories: limbic, associative and sensorimotor. In a third spiral model, propagation is possible between limbic information processed by the most medial striatal neurons to motor information processed by the most lateral neurons.
Three main levels of interaction between the BG system and the limbic system are considered. (1) The BG receive direct afferences from several structures associated with the limbic system. Limbic cortical areas project to the striatum, of which the internal architecture is particularly complex, with significant cross-species differences: a compartmental striosome/matrix subdivision described mainly in primates, and a core/shell topographic subdivision of the nucleus accumbens more sharply marked in rodents. (2) Projections from the amygdala form a patchy dorso-ventral progressive gradient in the nucleus accumbens and ventral caudate. (3) Both shell and striosomes receive limbic information from cortical and subcortical limbic structures and project to the dopaminergic neurons of the substantia nigra pars compacta, which in turn modulates their activity. (4) There is a significant overlap between the ventral portions of the BG, nucleus accumbens and ventral pallidum, and the ventral subcortical structures of the limbic system, extended amygdala and nucleus basalis.
Important interactions exist between the limbic system and the BG system but questions remain about the role that this information plays in the functional organisation of this system. Is limbic information processed separately in the BG, or is it integrated to motor and cognitive information? Do pathological conditions such as obsessive-compulsive disorders or Tourette syndrome result from abnormal afferent limbic input to the BG or abnormal processing within the BG?
基底神经节(BG)参与控制运动参数等不同过程的活动,但也参与处理来自环境的认知和情绪信息。在这里,我们回顾了现有的关于 BG 与边缘系统相互作用的解剖学数据,这些数据支持 BG 参与边缘功能。
BG 形成了一个与边缘系统相当不同的系统,但与后者有很强的联系,无论是解剖学上还是功能上。已经提出了不同的模型。在平行模型中,来自额叶皮层的五个分离的回路被个体化,并终止于 BG 和丘脑的不同区域,然后再投射回它们的皮层起源区域。基于额外的皮质投射,提出了另一个模型。它将皮质纹状体投射分为三个功能区:边缘、联想和感觉运动。在第三个螺旋模型中,信息可以在由最内侧纹状体神经元处理的边缘信息与由最外侧神经元处理的运动信息之间传播。
考虑了 BG 系统与边缘系统之间相互作用的三个主要层次。(1)BG 从几个与边缘系统相关的结构中接收直接传入。边缘皮质区投射到纹状体,纹状体的内部结构特别复杂,在不同物种之间有显著差异:一个在灵长类动物中主要描述的隔区/基质分区分化,以及一个在啮齿动物中更为明显的核壳腹侧拓扑分区分化。(2)杏仁核的投射在伏隔核和腹侧尾状核中形成一个点状的背腹渐进梯度。(3)壳和纹状体都从皮质和皮质下边缘结构接收边缘信息,并投射到黑质致密部的多巴胺能神经元,多巴胺能神经元反过来调节它们的活动。(4)BG 的腹侧部分、伏隔核和腹侧苍白球与边缘系统的腹侧下结构、扩展的杏仁核和基底核之间有显著的重叠。
边缘系统和 BG 系统之间存在着重要的相互作用,但关于这个信息在这个系统的功能组织中扮演的角色,仍然存在问题。边缘信息是在 BG 中单独处理,还是与运动和认知信息整合?强迫症或妥瑞氏综合征等病理状况是否是由于边缘传入信息异常进入 BG 或 BG 内的异常处理引起的?
