运动扰动期间联合皮层和海马体的作用。

The Role of Associative Cortices and Hippocampus during Movement Perturbations.

作者信息

Kerr Matthew S D, Sacré Pierre, Kahn Kevin, Park Hyun-Joo, Johnson Mathew, Lee James, Thompson Susan, Bulacio Juan, Jones Jaes, González-Martínez Jorge, Liégeois-Chauvel Catherine, Sarma Sridevi V, Gale John T

机构信息

Department of Biomedical Engineering, Johns Hopkins UniversityBaltimore, MD, USA.

Center for Neurological Restoration, Cleveland ClinicCleveland, OH, USA.

出版信息

Front Neural Circuits. 2017 Apr 19;11:26. doi: 10.3389/fncir.2017.00026. eCollection 2017.

DOI:10.3389/fncir.2017.00026

PMID:28469563

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5395558/

Abstract

Although motor control has been extensively studied, most research involving neural recordings has focused on primary motor cortex, pre-motor cortex, supplementary motor area, and cerebellum. These regions are involved during normal movements, however, associative cortices and hippocampus are also likely involved during perturbed movements as one must detect the unexpected disturbance, inhibit the previous motor plan, and create a new plan to compensate. Minimal data is available on these brain regions during such "robust" movements. Here, epileptic patients implanted with intracerebral electrodes performed reaching movements while experiencing occasional unexpected force perturbations allowing study of the fronto-parietal, limbic and hippocampal network at unprecedented high spatial, and temporal scales. Areas including orbitofrontal cortex (OFC) and hippocampus showed increased activation during perturbed trials. These results, coupled with a visual novelty control task, suggest the hippocampal MTL-P300 novelty response is modality independent, and that the OFC is involved in modifying motor plans during robust movement.

摘要

尽管运动控制已经得到了广泛研究，但大多数涉及神经记录的研究都集中在初级运动皮层、运动前区皮层、辅助运动区和小脑。这些区域在正常运动中发挥作用，然而，在受到干扰的运动中，联合皮层和海马体也可能参与其中，因为人们必须检测到意外干扰，抑制先前的运动计划，并制定新的计划来进行补偿。在这种“剧烈”运动过程中，关于这些脑区的数据非常有限。在这里，植入脑内电极的癫痫患者在进行伸手动作时偶尔会受到意外的力干扰，从而能够以前所未有的高空间和时间尺度研究额顶叶、边缘系统和海马网络。包括眶额皮层（OFC）和海马体在内的区域在受干扰试验中显示出激活增加。这些结果，再加上视觉新奇性控制任务，表明海马体MTL - P300新奇性反应与模态无关，并且OFC参与在剧烈运动期间修改运动计划。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cb1c/5395558/d4c428b68685/fncir-11-00026-g0001.jpg

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运动扰动期间联合皮层和海马体的作用。

The Role of Associative Cortices and Hippocampus during Movement Perturbations.

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