Department of Neurology, Northwestern University, Chicago, IL 60611, USA.
J Neural Eng. 2013 Oct;10(5):056005. doi: 10.1088/1741-2560/10/5/056005. Epub 2013 Aug 5.
Brain machine interfaces (BMIs) have the potential to restore movement to people with paralysis. However, a clinically-viable BMI must enable consistently accurate control over time spans ranging from years to decades, which has not yet been demonstrated. Most BMIs that use single-unit spikes as inputs will experience degraded performance over time without frequent decoder re-training. Two other signals, local field potentials (LFPs) and multi-unit spikes (MSPs), may offer greater reliability over long periods and better performance stability than single-unit spikes. Here, we demonstrate that LFPs can be used in a biomimetic BMI to control a computer cursor.
We implanted two rhesus macaques with intracortical microelectrodes in primary motor cortex. We recorded LFP and MSP signals from the monkeys while they performed a continuous reaching task, moving a cursor to randomly-placed targets on a computer screen. We then used the LFP and MSP signals to construct biomimetic decoders for control of the cursor.
Both monkeys achieved high-performance, continuous control that remained stable or improved over nearly 12 months using an LFP decoder that was not retrained or adapted. In parallel, the monkeys used MSPs to control a BMI without retraining or adaptation and had similar or better performance, and that predominantly remained stable over more than six months. In contrast to their stable online control, both LFP and MSP signals showed substantial variability when used offline to predict hand movements.
Our results suggest that the monkeys were able to stabilize the relationship between neural activity and cursor movement during online BMI control, despite variability in the relationship between neural activity and hand movements.
脑机接口(BMI)有潜力恢复瘫痪患者的运动能力。然而,一个具有临床可行性的 BMI 必须能够在数年到数十年的时间跨度内实现持续准确的控制,而这一点尚未得到证明。大多数使用单单位尖峰作为输入的 BMI 随着时间的推移,未经频繁解码器重新训练,性能会逐渐下降。另外两种信号,局部场电位(LFPs)和多单位尖峰(MSPs),可能比单单位尖峰具有更长时间的可靠性和更好的性能稳定性。在这里,我们证明 LFP 可用于仿生 BMI 来控制计算机光标。
我们将两只恒河猴植入初级运动皮层中的颅内微电极。当猴子执行连续的伸手任务,将光标移动到计算机屏幕上随机放置的目标时,我们记录 LFP 和 MSP 信号。然后,我们使用 LFP 和 MSP 信号来构建仿生解码器以控制光标。
两只猴子都实现了高性能、连续控制,使用未重新训练或自适应的 LFP 解码器,在近 12 个月的时间内保持稳定或改善。与此同时,猴子使用 MSP 来控制 BMI,无需重新训练或适应,并且具有相似或更好的性能,并且在超过六个月的时间内主要保持稳定。与它们在线控制的稳定性形成对比的是,LFP 和 MSP 信号在离线用于预测手部运动时表现出很大的可变性。
我们的结果表明,尽管神经活动与手部运动之间的关系存在可变性,但猴子能够在在线 BMI 控制期间稳定神经活动和光标运动之间的关系。
