Reprint

Spinal Cord Injury and Transcutaneous Spinal Cord Stimulation

Edited by
August 2022
292 pages
  • ISBN978-3-0365-4755-8 (Hardback)
  • ISBN978-3-0365-4756-5 (PDF)

This is a Reprint of the Special Issue Spinal Cord Injury and Transcutaneous Spinal Cord Stimulation that was published in

Medicine & Pharmacology
Public Health & Healthcare
Summary

Recent research of epidural and transcutaneous electrical spinal cord stimulation has demonstrated unprecedented improvements in motor function thought to be irreversibly lost due to chronic, severe spinal cord injury. Studies in parallel assess these methods for spasticity management as an alternative to medications that are often accompanied by deleterious side effects. As a noninvasive intervention, transcutaneous spinal cord stimulation holds the great potential to find its way into wide clinical application. Its firm establishment and lasting acceptance as clinical practice in spinal cord injury will not only hinge on the demonstration of safety and efficacy, but also on the delineation of a conceptual framework of the underlying physiological mechanisms. This will also require advancing our understanding of immediate and temporary effects of transcutaneous spinal cord on neuronal circuits in the intact and injured spinal cord. The purpose of this collection of papers is to bring together peers in the field to share—and eventually fuse—their pertinent research into current neurorehabilitation practice by providing a clinical perspective and novel insights into the underlying mechanisms.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
human; neuromodulation; neurorehabilitation; non-invasive; spinal cord injury; transcutaneous spinal cord stimulation; transcutaneous spinal cord stimulation; evoked potentials motor; neuromodulation; motor activity; human; non-invasive; spinal cord injury; spinal cord stimulation; spinal reflexes; voluntary ankle control; walking; transcutaneous spinal cord stimulation; hand training; combined intervention; neuromodulation; cervical spinal cord; activity-based therapy; gait; locomotion; neuromodulation; paraplegia; task-specific training; tetraplegia; use-dependent plasticity; antispasmodic; electrical stimulation; neuromodulation; paraplegia; pendulum test; tetraplegia; transcutaneous spinal cord stimulation; intensity effect; muscle strength effect; hand training; neuromodulation; cervical spinal cord; cervical; transcutaneous spinal cord stimulation; corticospinal pathway; spinal reflex; neuromodulation; spinal cord injury; electrically evoked spinal motor potentials; spinal cord stimulation; neuromodulation; spinal cord stimulation; cervical spinal cord injury; motor evoked potentials; automation; electromyography; noninvasive; Parkinson’s disease; posterior root-muscle reflexes; spasticity; spinal cord injury; spinal cord stimulation; transcutaneous; biophysics; H reflex; human; M wave; neuromodulation; posterior root-muscle reflex; posterior root stimulation; spine alignment; spinal cord; spinal cord stimulation; spine; transcutaneous; spinal cord; spinal stimulation; corticospinal tract; functional connectivity; movement; sensorimotor networks; task dependence; neuromodulation; interlimb coordination; rehabilitation; neurophysiology; Hoffmann (H)-reflex; motor-evoked potential; locomotion; spinal cord injury; neuromodulation; transcutaneous spinal cord stimulation; electroencephalography; event-related desynchronisation; rehabilitation; posterior root muscle reflex; spinal cord injury; transcutaneous spinal cord stimulation; neuromodulation; electrical stimulation; evoked potentials; lumbar spinal cord; n/a

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