Summary
To clarify the organization of motor representations in posterior
parietal cortex, we test how three motor variables (body side, body part,
cognitive strategy) are coded in the human anterior intraparietal cortex. All
tested movements were encoded, arguing against strict anatomical segregation of
effectors. Single units coded for diverse conjunctions of variables, with
different dimensions anatomically overlapping. Consistent with recent studies,
neurons encoding body parts exhibited mixed selectivity. This mixed selectivity
resulted in largely orthogonal coding of body parts, which “functionally
segregate” the effector responses despite the high degree of anatomical
overlap. Body side and strategy were not coded in a mixed manner as effector
determined their organization. Mixed-coding of some variables over others, what
we term “partially mixed coding”, argues that the type of
functional encoding depends on the compared dimensions. This structure is
advantageous for neuroprosthetics, allowing a single array to decode movements
of a large extent of the body.
Present day cortical brain machine interfaces (BMI) have made impressive advances using decoded brain signals to control extracorporeal devices. Although BMIs are used in a closed-loop fashion, sensory feedback typically is visual only. However medical case studies have shown that the loss of somesthesis in a limb greatly reduces the agility of the limb even when visual feedback is available (for review see Robles-De-La-Torre, 2006). To overcome this limitation, this study tested a closed-loop BMI that utilizes intracortical microstimulation (ICMS) to provide ‘tactile’ sensation to a non-human primate (NHP). Using stimulation electrodes in Brodmann area 1 of somatosensory cortex (BA1) and recording electrodes in the anterior intraparietal area (AIP), the parietal reach region (PRR) and dorsal area 5 (area 5d), it was found that this form of feedback can be used in BMI tasks.
Recent studies in posterior parietal cortex (PPC) have found multiple effectors and cognitive strategies represented within a shared neural substrate in a structure termed "partially mixed selectivity" (Zhang et al., 2017). In this study, we examine whether the structure of these representations is preserved across changes in task context and is thus a robust and generalizable property of the neural population. Specifically, we test whether the structure is conserved from an open-loop motor imagery task (training) to a closed-loop cortical control task (online), a change that has led to substantial changes in neural behavior in prior studies in motor cortex. Recording from a 4 ϫ 4 mm electrode array implanted in PPC of a human tetraplegic patient participating in a brain-machine interface (BMI) clinical trial, we studied the representations of imagined/attempted movements of the left/right hand and compare their individual BMI control performance using a one-dimensional cursor control task. We found that the structure of the representations is largely maintained between training and online control. Our results demonstrate for the first time that the structure observed in the context of an open-loop motor imagery task is maintained and accessible in the context of closed-loop BMI control. These results indicate that it is possible to decode the mixed variables found from a small patch of cortex in PPC and use them individually for BMI control. Furthermore, they show that the structure of the mixed representations is maintained and robust across changes in task context.
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