A mosaic of whole-body representations on the human precentral gyrus

Main

Nearly a century ago, Penfield and colleagues pioneered the motor homunculus, a topographical map of the human PCG, by electrically stimulating the cortical surface and observing which body parts moved in response 17 , 18 . Since that time, the motor cortex has been mapped extensively in non-human primate models using single-neuron recordings 6 , 7 , 8 , microstimulation of both short and long durations 1 , 2 , 3 , 4 , 5 and lesion and inactivation studies 4 , 9 , 10 . This body of work has provided strong evidence that the motor cortex is more fractionated and intermixed than originally implied by the motor homunculus, with related body parts overlapping in the primary motor cortex 2 , 22 , 23 (for example, wrist and fingers) and whole-body regions overlapping in the premotor cortex 6 , 7 , 24 (for example, arm and face). Long stimulation durations have more recently revealed that the motor cortex is also organized by behaviour in ethological ‘action maps’ as opposed to a pure body part organization 3 , 4 , 21 , 25 .

In humans, however, exploration of the motor cortex has largely been limited to lower-resolution recording techniques—such as electrocorticography 11 , 12 , 13 and functional magnetic resonance imaging (fMRI) 14 , 15 , 16 , 26 —as well as gross stimulation mapping in the operating room 17 , 18 , 19 , 20 . Studies reporting the effects of lesions 27 , 28 and stimulation 17 , 18 , 19 , 20 have found results that suggest a separation of leg, arm and face movement regions in the human PCG (that is, stimulation at any single location does not typically cause simultaneous arm, leg and face movement, with some exceptions 19 , 29 ). On the other hand, fMRI and electrophysiological studies have emphasized a greater degree of intermixing 13 , 14 , 15 , 16 , including beta power modulation and blood-oxygenation-level-dependent deactivation spreading far from the somatotopic hotspot 16 , 30 , overlapping receptive fields 14 and intereffector regions with whole-body intermixing 15 , 31 . However, these experiments cannot resolve detailed representations at the single-neuron level, and thus the representation of the body in the human motor cortex remains relatively unknown at a single-neuron scale. The crown (exposed surface) of the human PCG is thought to be anatomically composed largely of Brodmann area 6 (a premotor area), with the primary motor cortex lying within the central sulcus 32 , 33 , 34 . If the crown of the human PCG is functionally homologous to the macaque premotor cortex, we might expect to find dense intermixing of arm and leg movements dorsally 3 , 7 , 24 , 35 , and arm and orofacial movements ventrally 3 , 6 , 24 .

In previous work using microelectrode arrays capable of recording brain activity at single-neuron resolution, we have shown that a small, anatomically distinct area of the cortex in the dorsal PCG (referred to as the ‘hand knob’ 36 ) contained intermixed representations of the entire body 37 , 38 (including all four limbs and head and face movements), where the limbs were interrelated with a compositional neural code. However, it is unknown whether a similar organization exists in the middle and ventral PCG; in addition to providing fundamental insight into the neural representation of movement in humans, an answer to this question is needed to inform the design of brain–computer interfaces (BCIs) that restore motor function to people with paralysis, including speech.

Here we revisit the motor representation of the whole body across a wide span of the PCG using microelectrode recordings from 8 human participants (Fig. 1a ) implanted with 20 microelectrode arrays as part of BCI clinical trials. These participants had either spinal cord injury, amyotrophic lateral sclerosis (ALS) or brainstem stroke, resulting in severe motor impairment with varying levels of residual movement across individuals. All clinical trial procedures were conducted with oversight from ethics, institutional and regulatory bodies; before enrolment, an extensive consent process engaged potential participants and reinforced that no direct benefit from study participation was expected (see  Methods ). These neural recordings collectively sampled the length of the PCG spanning from the canonical arm area (near the superior frontal sulcus) to the canonical tongue and throat area (near the Sylvian fissure), and together constitute, to our knowledge, the first comprehensive motor map of the crown of the human PCG at single-neuron resolution.

Fig. 1: Sampling the length of the PCG to assess whole-body movement representation. The alternative text for this image may have been generated using AI.

Full size image

a , Diagram of the dorsal, middle and ventral regions of the PCG sampled in this study. Neural activity was analysed from a total of 20 microelectrode arrays distributed across 8 participants with paralysis (right table). Four additional microelectrode arrays were recorded but excluded from analysis d…