单体电生理学记录和计算建模可预测章鱼的手臂运动

Nitish Satya Sai Gedela, Sachin Salim, Ryan D Radawiec, Julianna Marie Richie, Cynthia A Chestek, Anne Draelos, Galit Pelled
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引用次数: 0

摘要

章鱼简化神经系统有可能揭示运动电路的原理,并通过机器学习和统计分析建立计算模型来改进脑机接口设备。在这里,我们将提供单机电生理学记录的碳电极阵列植入章鱼前神经索。我们记录了沿手臂不同位置的尖峰数量和手臂运动对刺激的反应。我们观察到,刺激后头 100 毫秒内出现的尖峰数量可预测由此产生的运动反应。计算模型显示,时间电生理特征可用于预测是否发生手臂运动,置信度为 88.64%,而预测是侧臂运动还是抓握运动,置信度为 75.45%。为了获得章鱼手臂运动的流式测量数据,以及章鱼的运动电路如何实时产生丰富的运动类型,我们采用了有监督和无监督两种方法。深度学习模型和无监督降维确定了一组一致的特征,可用于区分不同类型的手臂运动。这些模型可预测如何在单个运动电路的协调序列中唤起特定的复杂运动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Single unit electrophysiology recordings and computational modeling can predict octopus arm movement
The octopus simplified nervous system holds the potential to reveal principles of motor circuits and improve brain-machine interface devices through computational modeling with machine learning and statistical analysis. Here, an array of carbon electrodes providing single-unit electrophysiology recordings were implanted into the octopus anterior nerve cord. The number of spikes and arm movements in response to stimulation at different locations along the arm were recorded. We observed that the number of spikes occurring within the first 100ms after stimulation were predictive of the resultant movement response. Computational models showed that temporal electrophysiological features could be used to predict whether an arm movement occurred with 88.64% confidence, and if it was a lateral arm movement or a grasping motion with 75.45% confidence. Both supervised and unsupervised methods were applied to gain streaming measurements of octopus arm movements and how their motor circuitry produces rich movement types in real time. Deep learning models and unsupervised dimension reduction identified a consistent set of features that could be used to distinguish different types of arm movements. These models generated predictions for how to evoke a particular, complex movement in an orchestrated sequence for an individual motor circuit.
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