Abstract
Electrical spinal cord stimulation (SCS) has been gaining momentum as a potential therapy for motor paralysis in consequence of spinal cord injury (SCI). Specifically, recent studies combining SCS with activity-based training have reported unprecedented improvements in motor function in people with chronic SCI that persist even without stimulation. In this work, we first provide an overview of the critical scientific advancements that have led to the current uses of SCS in neurorehabilitation: e.g. the understanding that SCS activates dormant spinal circuits below the lesion by recruiting large-to-medium diameter sensory afferents within the posterior roots. We discuss how this led to the standardization of implant position which resulted in consistent observations by independent clinical studies that SCS in combination with physical training promotes improvements in motor performance and neurorecovery. While all reported participants were able to move previously paralyzed limbs from day 1, recovery of more complex motor functions was gradual, and the timeframe for first observations was proportional to the task complexity. Interestingly, individuals with SCI classified as AIS B and C regained motor function in paralyzed joints even without stimulation, but not individuals with motor and sensory complete SCI (AIS A). Experiments in animal models of SCI investigating the potential mechanisms underpinning this neurorecovery suggest a synaptic reorganization of cortico-reticulo-spinal circuits that correlate with improvements in voluntary motor control. Future experiments in humans and animal models of paralysis will be critical to understand the potential and limits for functional improvements in people with different types, levels, timeframes, and severities of SCI.
Highlights
Recent studies combining spinal cord stimulation (SCS) with activity-based training have reported lasting improvements in motor function that were historically thought impossible in the chronic stage of spinal cord injury (SCI)
Are motor improvements limited to individuals with spared descending neural fibers? The combined results from the three main clinical studies included in this review suggest recovery outcomes are directly related to lesion severity (Fig. 3) which we believe is indicative of the link between SCS and the amount of spared descending neural fibers
The prosthetic effect of SCS on motor function below the injury can enable the delivery of activity-based interventions that lead to unprecedented functional improvements in the chronic stage of paralysis (Angeli et al 2018; Gill et al 2018; Wagner et al 2018)
Summary
Recent studies combining spinal cord stimulation (SCS) with activity-based training have reported lasting improvements in motor function that were historically thought impossible in the chronic stage of spinal cord injury (SCI). SCS-mediated neurorecovery in humans with SCI Standardization of practice enabled interventional clinical trials to study whether the delivery of SCS in combination with physical training could improve functional outcomes in individuals with SCI.
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