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关键运动在预测人类和非生物运动轨迹中的作用

Critical Motor Involvement in Prediction of Human and Non-biological Motion Trajectories.

作者信息

de Wit Matthieu M, Buxbaum Laurel J

机构信息

Moss Rehabilitation Research Institute,Elkins Park,Pennsylvania.

出版信息

J Int Neuropsychol Soc. 2017 Feb;23(2):171-184. doi: 10.1017/S1355617716001144.

DOI:10.1017/S1355617716001144
PMID:28205497
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5360459/
Abstract

OBJECTIVES

Adaptive interaction with the environment requires the ability to predict both human and non-biological motion trajectories. Prior accounts of the neurocognitive basis for prediction of these two motion classes may generally be divided into those that posit that non-biological motion trajectories are predicted using the same motor planning and/or simulation mechanisms used for human actions, and those that posit distinct mechanisms for each. Using brain lesion patients and healthy controls, this study examined critical neural substrates and behavioral correlates of human and non-biological motion prediction.

METHODS

Twenty-seven left hemisphere stroke patients and 13 neurologically intact controls performed a visual occlusion task requiring prediction of pantomimed tool use, real tool use, and non-biological motion videos. Patients were also assessed with measures of motor strength and speed, praxis, and action recognition.

RESULTS

Prediction impairment for both human and non-biological motion was associated with limb apraxia and, weakly, with the severity of motor production deficits, but not with action recognition ability. Furthermore, impairment for human and non-biological motion prediction was equivalently associated with lesions in the left inferior parietal cortex, left dorsal frontal cortex, and the left insula.

CONCLUSIONS

These data suggest that motor planning mechanisms associated with specific loci in the sensorimotor network are critical for prediction of spatiotemporal trajectory information characteristic of both human and non-biological motions. (JINS, 2017, 23, 171-184).

摘要

目的

与环境的适应性互动需要预测人类和非生物运动轨迹的能力。先前关于这两类运动预测的神经认知基础的描述大致可分为两类:一类认为非生物运动轨迹是使用与人类动作相同的运动规划和/或模拟机制进行预测的;另一类则认为针对每一类运动有不同的机制。本研究通过脑损伤患者和健康对照,检验了人类和非生物运动预测的关键神经基质及行为相关性。

方法

27名左半球中风患者和13名神经功能正常的对照者进行了一项视觉遮挡任务,该任务要求预测模拟工具使用、实际工具使用和非生物运动视频。还对患者进行了运动强度和速度、实践能力及动作识别的测量。

结果

人类和非生物运动的预测损伤均与肢体失用症相关,且与运动产生缺陷的严重程度有较弱的相关性,但与动作识别能力无关。此外,人类和非生物运动预测的损伤与左顶下叶皮质、左背侧额叶皮质和左脑岛的病变同等相关。

结论

这些数据表明,与感觉运动网络中特定位点相关的运动规划机制对于预测人类和非生物运动特有的时空轨迹信息至关重要。(《神经心理学杂志》,2017年,第23卷,第171 - 184页)

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