Predominance of Movement Speed Over Direction in Neuronal Population Signals of Motor Cortex: Intracranial EEG Data and A Simple Explanatory Model

J. Hammer, T. Pistohl, J. Fischer, P. Krsek, M. Tomášek, P. Marusic, A. Schulze-Bonhage, A. Aertsen, T. Ball
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引用次数: 43

Abstract

How neuronal activity of motor cortex is related to movement is a central topic in motor neuroscience. Motor-cortical single neurons are more closely related to hand movement velocity than speed, that is, the magnitude of the (directional) velocity vector. Recently, there is also increasing interest in the representation of movement parameters in neuronal population activity, such as reflected in the intracranial EEG (iEEG). We show that in iEEG, contrasting to what has been previously found on the single neuron level, speed predominates over velocity. The predominant speed representation was present in nearly all iEEG signal features, up to the 600–1000 Hz range. Using a model of motor-cortical signals arising from neuronal populations with realistic single neuron tuning properties, we show how this reversal can be understood as a consequence of increasing population size. Our findings demonstrate that the information profile in large population signals may systematically differ from the single neuron level, a principle that may be helpful in the interpretation of neuronal population signals in general, including, for example, EEG and functional magnetic resonance imaging. Taking advantage of the robust speed population signal may help in developing brain–machine interfaces exploiting population signals.
运动皮层神经元群信号中运动速度优于运动方向:颅内脑电图数据和一个简单的解释模型
运动皮层的神经元活动与运动的关系是运动神经科学研究的中心课题。运动皮层单个神经元与手部运动速度的关系比与速度的关系更密切,即(方向)速度矢量的大小。最近,人们对神经元群活动中运动参数的表征也越来越感兴趣,例如在颅内脑电图(iEEG)中反映出来的运动参数。我们发现,与之前在单个神经元水平上发现的结果相比,在脑电图中,速度比速度更重要。在600 - 1000hz范围内,几乎所有的脑电图信号特征中都存在主要的速度表示。利用具有现实的单个神经元调谐特性的神经元群体产生的运动-皮层信号模型,我们展示了这种逆转如何被理解为群体规模增加的结果。我们的研究结果表明,大群体信号中的信息剖面可能与单个神经元水平有系统的不同,这一原则可能有助于解释一般的神经元群体信号,例如脑电图和功能磁共振成像。利用鲁棒速度种群信号可能有助于开发利用种群信号的脑机接口。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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