Decoding sensorimotor information from somatosensory cortex by flexible epicortical μECoG arrays in unrestrained behaving rats.

Journal of neural engineering Pub Date : 2024-11-18 DOI:10.1088/1741-2552/ad9405

Deniz Kılınç Bülbül, Steven T Walston, Fikret Taygun Duvan, Jose A Garrido, Burak Guclu

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Abstract

Objective: Brain-computer interfaces (BCI) are promising for severe neurological conditions and there are ongoing efforts to develop state-of-the-art neural interfaces, hardware, and software tools. We tested the potential of novel reduced graphene oxide (rGO) electrodes implanted epidurally over the hind limb representation of the primary somatosensory (S1) cortex of rats and compared them to commercial platinum-iridium (Pt-Ir) 16-channel electrodes (active site diameter: 25 μm).

Approach: Motor and somatosensory information was decoded offline from microelectrocorticography (μECoG) signals recorded while unrestrained rats performed a simple behavioral task: pressing a lever and the subsequent vibrotactile stimulation of the glabrous skin at three displacement amplitude levels and at two sinusoidal frequencies. μECoG data were initially analyzed by standard time-frequency methods. Next, signal powers of oscillatory bands recorded from multiple electrode channels were used as features for sensorimotor classification by a machine learning algorithm.

Main results: Both electrode types performed quite well and similar to each other for predicting the motor interval and the presence of the vibrotactile stimulus. Average accuracies were relatively lower for predicting 3-class vibrotactile frequency and 4-class amplitude level by both electrode types.

Significance: Given some confounding factors during the free movement of rats, the results show that both sensory and motor information can be recorded reliably from the hind limb area of S1 cortex by using μECoG arrays. The chronic use of novel rGO electrodes was demonstrated successfully. The hind limb area may be convenient for the future evaluation of new tools in neurotechnology, especially those for bidirectional BCIs.

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在行为不受约束的大鼠体内，通过灵活的皮质外膜 μECoG 阵列解码来自躯体感觉皮层的感觉运动信息。

目的：脑机接口（BCI）在治疗严重神经系统疾病方面大有可为，目前正在努力开发最先进的神经接口、硬件和软件工具。我们测试了将新型还原氧化石墨烯（rGO）电极从表皮植入大鼠初级躯体感觉（S1）皮层后肢代表部位的潜力，并将其与商用铂铱（Pt-Ir）16 通道电极（活性位点直径：25 μm）进行了比较：方法：在不受束缚的大鼠完成一项简单的行为任务（按下杠杆，随后以三种位移振幅水平和两种正弦频率对无毛皮肤进行振动触觉刺激）时，从记录的微皮层图（μECoG）信号中离线解码运动和体感信息。μECoG数据最初采用标准时频方法进行分析。然后，使用机器学习算法将多个电极通道记录的振荡波段的信号功率作为传感器运动分类的特征：主要结果：两种电极类型在预测运动间隔和振动触觉刺激的存在方面表现相当出色，而且彼此相似。两种电极类型在预测 3 级振动频率和 4 级振幅水平方面的平均准确度相对较低：意义：考虑到大鼠自由运动过程中的一些干扰因素，研究结果表明，使用μECoG阵列可以可靠地记录S1皮层后肢区域的感觉和运动信息。新型 rGO 电极的长期使用也得到了成功验证。后肢区域可能便于未来评估神经技术的新工具，特别是用于双向BCI的工具。

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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Journal of neural engineering

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