This trial aims to see if putting eletrical stimulation on the neck can help improve hand and arm function in those with high level injuries.
Author: CureSteps
This trial aims to see how electrical stimulation, delivered through the skin (transcutaneous), effects spasticity in those with spinal cord injury to see if stimulation is a possible alternative to anti-spasticity medication.
On December 7, 2014, Joe Beatty, then 60 years old, was body-surfing on Kaanapali Beach in Hawaii, a popular place with tourists on the west side of Maui island and known for its calm, crystal-blue ocean waters. Long considered a family-friendly beach, Kaanapali is widely thought of as an ideal spot for both children and adults to swim; however, on that day for Beatty, this normally safe environment turned unusually dangerous. (excerpt)
It is commonly assumed that restoration of locomotion is the ultimate goal after spinal cord injury (SCI). However, lower urinary tract (LUT) dysfunction is universal among SCI patients and significantly impacts their health and quality of life. Micturition is a neurologically complex behavior that depends on intact sensory and motor innervation. SCI disrupts both motor and sensory function and leads to marked abnormalities in urine storage and emptying. Current therapies for LUT dysfunction after SCI focus on preventing complications and managing symptoms rather than restoring function. In this study, we demonstrate that Transcutaneous Electrical Spinal Stimulation for LUT functional Augmentation (TESSLA), a non-invasive neuromodulatory technique, can reengage the spinal circuits’ active in LUT function and normalize bladder and urethral sphincter function in individuals with SCI. Specifically, TESSLA reduced detrusor overactivity (DO), decreased detrusor-sphincter dyssynergia (DSD), increased bladder capacity and enabled voiding. TESSLA may represent a novel approach to transform the intrinsic spinal networks to a more functionally physiological state. Each of these features has significant clinical implications. Improvement and restoration of LUT function after SCI stand to significantly benefit patients by improving their quality of life and reducing the risk of incontinence, kidney injury and urinary tract infection, all the while lowering healthcare costs. (excerpt)
Abstract
The combined effects of cervical electrical stimulation alone or in combination with the monoaminergic agonist buspirone on upper limb motor function were determined in six subjects with motor complete (AIS B) injury at C5 or above and more than one year from time of injury. Voluntary upper limb function was evaluated through measures of controlled hand contraction, handgrip force production, dexterity measures, and validated clinical assessment batteries. Repeated measure analysis of variance was used to evaluate functional metrics, EMG amplitude, and changes in mean grip strength. In aggregate, mean hand strength increased by greater than 300% with transcutaneous electrical stimulation and buspirone while a corresponding clinically significant improvement was observed in upper extremity motor scores and the action research arm test. Some functional improvements persisted for an extended period after the study interventions were discontinued. We demonstrate that, with these novel interventions, cervical spinal circuitry can be neuromodulated to improve volitional control of hand function in tetraplegic subjects. The potential impact of these findings on individuals with upper limb paralysis could be dramatic functionally, psychologically, and economically.
Newswise — A team of Johns Hopkins neurosurgeons and biomedical engineers has received $13.48 million from the Defense Advanced Research Projects Agency (DARPA) to develop implantable ultrasound and other devices that could revolutionize care for people suffering from spinal cord injuries. The results could benefit thousands of U.S. service members and civilians who sustain spinal cord injuries every year. (excerpt)
Researchers have developed a molecule that can restore lost connections in the spinal cords and brains of mice with cerebellar ataxia, Alzheimer’s disease and spinal cord injury.
Researchers have demonstrated that a molecule they created can restore lost connections in the spinal cords and brains of mice with neurological disorders including cerebellar ataxia, Alzheimer’s disease and spinal cord injury.
The research involved scientists in the UK Medical Research Council Laboratory of Molecular Biology (MRC LMB) and collaborators from Japan and Germany.
This scientific commentary refers to ‘Nogo receptor decoy promotes recovery and corticospinal growth in non-human primate spinal cord injury’, by Wang et al. (doi:10.1093/brain/awaa116).