Spinal Cord Injury-Induced Changes in Encoding and Decoding of Bipedal Walking by Motor Cortical Ensembles.
Dingyin HuShirong WangBo LiHonghao LiuJiping HePublished in: Brain sciences (2021)
Recent studies have shown that motor recovery following spinal cord injury (SCI) is task-specific. However, most consequential conclusions about locomotor functional recovery from SCI have been derived from quadrupedal locomotion paradigms. In this study, two monkeys were trained to perform a bipedal walking task, mimicking human walking, before and after T8 spinal cord hemisection. Importantly, there is no pharmacological therapy with nerve growth factor for monkeys after SCI; thus, in this study, the changes that occurred in the brain were spontaneous. The impairment of locomotion on the ipsilateral side was more severe than that on the contralateral side. We used information theory to analyze single-cell activity from the left primary motor cortex (M1), and results show that neuronal populations in the unilateral primary motor cortex gradually conveyed more information about the bilateral hindlimb muscle activities during the training of bipedal walking after SCI. We further demonstrated that, after SCI, progressively expanded information from the neuronal population reconstructed more accurate control of muscle activity. These results suggest that, after SCI, the unilateral primary motor cortex could gradually regain control of bilateral coordination and motor recovery and in turn enhance the performance of brain-machine interfaces.
Keyphrases
- spinal cord injury
- spinal cord
- neuropathic pain
- growth factor
- single cell
- white matter
- cerebral ischemia
- skeletal muscle
- endothelial cells
- health information
- resting state
- multiple sclerosis
- deep learning
- healthcare
- stem cells
- machine learning
- high throughput
- social media
- functional connectivity
- genetic diversity
- weight loss
- cell therapy