The Hippocampus Preorders Movements for Skilled Action Sequences.

IF 4.4 2区 医学 Q1 NEUROSCIENCES Journal of Neuroscience Pub Date : 2024-11-06 DOI:10.1523/JNEUROSCI.0832-24.2024
Rhys Yewbrey, Katja Kornysheva
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Abstract

Plasticity in the subcortical motor basal ganglia-thalamo-cerebellar network plays a key role in the acquisition and control of long-term memory for new procedural skills, from the formation of population trajectories controlling trained motor skills in the striatum to the adaptation of sensorimotor maps in the cerebellum. However, recent findings demonstrate the involvement of a wider cortical and subcortical brain network in the consolidation and control of well-trained actions, including a brain region traditionally associated with declarative memory-the hippocampus. Here, we probe which role these subcortical areas play in skilled motor sequence control, from sequence feature selection during planning to their integration during sequence execution. An fMRI dataset (N = 24; 14 females) collected after participants learnt to produce four finger press sequences entirely from memory with high movement and timing accuracy over several days was examined for both changes in BOLD activity and their informational content in subcortical regions of interest. Although there was a widespread activity increase in effector-related striatal, thalamic, and cerebellar regions, in particular during sequence execution, the associated activity did not contain information on the motor sequence identity. In contrast, hippocampal activity increased during planning and predicted the order of the upcoming sequence of movements. Our findings suggest that the hippocampus preorders movements for skilled action sequences, thus contributing to the higher-order control of skilled movements that require flexible retrieval. These findings challenge the traditional taxonomy of episodic and procedural memory and carry implications for the rehabilitation of individuals with neurodegenerative disorders.

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海马体为熟练动作序列预设动作顺序
皮层下运动基底节-丘脑-小脑网络的可塑性在获得和控制新程序性技能的长期记忆中起着关键作用,从纹状体中控制训练有素的运动技能的群体轨迹的形成到小脑中传感器运动图的适应。然而,最近的研究结果表明,在巩固和控制训练有素的动作过程中,有更广泛的皮层和皮层下大脑网络的参与,包括传统上与陈述性记忆相关的大脑区域--海马。在这里,我们探究了这些皮层下区域在熟练的运动序列控制中扮演的角色,包括从计划过程中的序列特征选择到序列执行过程中的整合。我们收集了参与者在数天内学会完全凭记忆制作四个手指按压序列后的 fMRI 数据集(24 人,14 名女性),这些数据集具有很高的运动和计时准确性,我们对这些数据集的 BOLD 活动变化及其在皮层下相关区域的信息含量进行了研究。虽然与效应相关的纹状体、丘脑和小脑区域的活动普遍增加,尤其是在序列执行过程中,但相关活动并不包含运动序列特征的信息。与此相反,海马区的活动在计划过程中有所增加,并能预测即将发生的运动序列的顺序。我们的研究结果表明,海马对熟练动作序列的运动进行了预先排序,从而有助于对需要灵活检索的熟练动作进行高阶控制。这些研究结果对传统的外显记忆和程序记忆分类法提出了挑战,并对神经退行性疾病患者的康复具有重要意义。这项 fMRI 研究表明,传统上与外显记忆和空间导航有关的海马体在执行训练有素的动作序列之前会预先排序。这些发现挑战了外显记忆和程序记忆系统之间的典型分离以及熟练运动行为的神经基础。
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来源期刊
Journal of Neuroscience
Journal of Neuroscience 医学-神经科学
CiteScore
9.30
自引率
3.80%
发文量
1164
审稿时长
12 months
期刊介绍: JNeurosci (ISSN 0270-6474) is an official journal of the Society for Neuroscience. It is published weekly by the Society, fifty weeks a year, one volume a year. JNeurosci publishes papers on a broad range of topics of general interest to those working on the nervous system. Authors now have an Open Choice option for their published articles
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