Department of Electrical Engineering, Stanford University, Stanford, CA, United States of America.
Department of Computer Science, Stanford University, Stanford, CA, United States of America.
PLoS Comput Biol. 2019 Feb 22;15(2):e1006808. doi: 10.1371/journal.pcbi.1006808. eCollection 2019 Feb.
Voluntary movements are widely considered to be planned before they are executed. Recent studies have hypothesized that neural activity in motor cortex during preparation acts as an 'initial condition' which seeds the proceeding neural dynamics. Here, we studied these initial conditions in detail by investigating 1) the organization of neural states for different reaches and 2) the variance of these neural states from trial to trial. We examined population-level responses in macaque premotor cortex (PMd) during the preparatory stage of an instructed-delay center-out reaching task with dense target configurations. We found that after target onset the neural activity on single trials converges to neural states that have a clear low-dimensional structure which is organized by both the reach endpoint and maximum speed of the following reach. Further, we found that variability of the neural states during preparation resembles the spatial variability of reaches made in the absence of visual feedback: there is less variability in direction than distance in neural state space. We also used offline decoding to understand the implications of this neural population structure for brain-machine interfaces (BMIs). We found that decoding of angle between reaches is dependent on reach distance, while decoding of arc-length is independent. Thus, it might be more appropriate to quantify decoding performance for discrete BMIs by using arc-length between reach end-points rather than the angle between them. Lastly, we show that in contrast to the common notion that direction can better be decoded than distance, their decoding capabilities are comparable. These results provide new insights into the dynamical neural processes that underline motor control and can inform the design of BMIs.
自愿运动被广泛认为是在执行之前就已经计划好的。最近的研究假设,运动皮层在准备阶段的神经活动充当了一个“初始条件”,为后续的神经动力学奠定基础。在这里,我们通过研究 1)不同到达的神经状态的组织和 2)这些神经状态在试验间的变异性,来详细研究这些初始条件。我们在猕猴前运动皮层(PMd)中研究了群体水平的反应,在有密集目标配置的指令延迟中心外到达任务的准备阶段。我们发现,在目标出现后,单个试验的神经活动收敛到具有明确低维结构的神经状态,这些状态由到达终点和随后到达的最大速度组织。此外,我们发现准备过程中神经状态的可变性类似于在没有视觉反馈的情况下进行的到达的空间可变性:在神经状态空间中,方向的可变性小于距离的可变性。我们还使用离线解码来理解这种神经群体结构对脑机接口(BMI)的影响。我们发现,对到达之间角度的解码取决于到达距离,而对弧长的解码则独立于距离。因此,通过使用到达终点之间的弧长而不是它们之间的角度来量化离散 BMI 的解码性能可能更为合适。最后,我们表明,与方向比距离更容易解码的常见观点相反,它们的解码能力相当。这些结果为理解运动控制背后的动态神经过程提供了新的见解,并为 BMI 的设计提供了信息。
