Brivaracetam to Reduce Neuropathic Pain in Chronic SCI: A Randomized, Double-Blind, Placebo-Controlled...
Spinal Cord InjuriesNeuropathic PainSpinal cord injury (SCI) is associated with severe neuropathic pain that is often refractory to pharmacological intervention. Preliminary data suggest brivaracetam is a mechanism-based pharmacological intervention for neuropathic pain in SCI. Based on this and other reports in the literature, SCI-related neuropathic pain is hypothesized to occur largely because of upregulation of synaptic vesicle protein 2A (SV2A) within the substantia gelatinosa of the injured spinal cord. Furthermore, compared to placebo, brivaracetam treatment is hypothesized to reduce severe below-level SCI neuropathic pain and increases parietal operculum (partsOP1/OP4) connectivity strength measured by resting-state functional Magnetic Resonance Imaging (rsfMRI). Circulating miRNA-485 levels may be associated with change in pain intensity due to brivaracetam treatment. The study aims to determine the efficacy of brivaracetam treatment for SCI-related neuropathic pain.
Grasp-Release Assessment of a Networked Neuroprosthesis Device
Spinal Cord Injury at C5-C7 LevelSpinal Cord Injuries1 moreThe overall objective of this trial is to characterize the safety and effectiveness of the Networked Neuroprosthesis Device - Upper Extremity (NP-UE) in individuals living with cervical SCI.
Safety, Feasibility, and Efficacy of TSCS on Stabilizing Blood Pressure for Acute Inpatients With...
Acute Spinal Cord InjurySpinal Cord Injuries6 moreThis site-specific project will focus on a novel non-pharmacologic approach to stabilizing BP during AIR after acute traumatic SCI. Current forms of pharmacologic and non-pharmacologic treatments for hypotension and OH remain inadequate in the SCI population. A critical need exists for the identification of safe, practical and effective treatment options that stabilize BP after traumatic SCI. Transcutaneous Spinal Cord Stimulation (TSCS) has several advantages: (1) does not exacerbate polypharmacy, (2) can be activated/deactivated rapidly, and (3) can be applied in synergy with physical exercise. TSCS represents an alternate approach to epidural SCS, with far greater potential to reach large numbers of individuals, thus providing for a greater likelihood of clinical implementation with far fewer risks. We are asking the key question: what if applying SCS earlier after injury could prevent the development of BP instability? To facilitate adoption of TSCS for widespread clinical use, we have designed a spatial-temporal mapping and parameter configuration approach that will result in a key deliverable for SCI care: a standard, easy to follow algorithm that will maximize individual benefits of spinal neuromodulation, while minimizing the burden on healthcare professionals. This project will provide the foundational evidence to support the feasible and safe application of TSCS for widespread clinical utility in the newly injured population, thereby overcoming barriers to engagement in prescribed AIR regimens that are imposed by ANS dysfunction.
Outcomes Post Treatment: Impact on Motor Impairment of Sleep Efficiency in SCI (OPTIMISE SCI Trial)...
Spinal Cord InjuriesSpine DiseaseThis randomized clinical trial will compare three groups of individuals with cervical/thoracic, complete or incomplete spinal cord injury (SCI) that will undergo: (i) early CPAP therapy in the management of moderate-to-severe sleep-related breathing disorders (SRBDs) among adults at 6 weeks after SCI; (ii) delayed CPAP therapy in the management of moderate-to-severe SRBDs among adults at 22 weeks after SCI; and (iii) no treatment as they either have mild or no SRBD.
Effect of Hypercapnia Treatment on Respiratory Recovery After Spinal Cord Injury
Sleep ApneaSCI/D1 moreIt is estimated that 1,275,000 people in the United States alone live with spinal cord injury, including around 100,000 Veterans with spinal cord injury, making the V.A. the largest integrated health care system in the world for spinal cord injuries injury care. New therapies are needed to prevent the morbidities and mortalities associated with the high prevalence of respiratory disorders in Veterans with spinal cord injury. The current research project and future studies would set the base for developing innovative therapies for this disorder. This proposal addresses a new therapeutic intervention for sleep apnea in spinal cord injury. The investigators hypothesized that daily hypercapnia treatments improve respiratory symptoms and alleviate sleep apnea in patients with chronic spinal cord injury. The investigators will perform a pilot study to examine the impact of daily hypercapnia treatments for-two week durations among Veterans with spinal cord injury. The investigators believe that this novel approach to treating sleep apnea and will yield significant new knowledge that improves the health and quality of life of these patients.
Transcutaneous Spinal Stimulation for Lower Limb Spasticity in Spinal Cord Injury
Spinal Cord InjuriesSpasticity1 moreSpasticity develops months after spinal cord injury (SCI) and persists over time. It presents as a mixture of tonic features, namely increased muscle tone (hypertonia) and phasic features, such as hyperactive reflexes (hyperreflexia), clonus, and involuntary muscle contractions (spasms). Spasticity is often disabling because it interferes with hygiene, transfers, and locomotion and can disturb sleep and cause pain. For these reasons, most individuals seek treatments for spasticity after SCI. New developments in electrical neuromodulation with transcutaneous spinal stimulation (TSS) show promising results in managing spasticity non-pharmacologically. The underlying principle of TSS interventions is that the afferent input generated by posterior root stimulation modifies the excitability of the lumbosacral network to suppress pathophysiologic spinal motor output contributing to distinctive features of spasticity. However, the previous TSS studies used almost identical protocols in terms of stimulation frequency and intensity despite the great flexibility offered by this treatment strategy and the favorable results with the epidural stimulation at higher frequencies. Therefore, the proposed study takes a new direction to systematically investigate the standalone and comparative efficacy of four TSS interventions, including those used in previous studies. Our central hypothesis is that electrical neuromodulation with the selected TSS protocols (frequency: 50/100 Hz; intensity: 0.45 or 0.9 times the sub-motor threshold) can reduce and distinctly modify tonic and phasic components of spasticity on short- and long-term basis. We will test our hypothesis using a prospective, experimental, cross-over, assessor-masked study design in 12 individuals with chronic SCI (more than 1-year post-injury). Aim 1. Determine the time course of changes and immediate after-effects of each TSS protocol on tonic and phasic spasticity. The results will reveal the evolution of changes in spasticity during 30-min of TSS and the most effective protocol for producing immediate aftereffects. Aim 2. Determine the effect of TSS on spasticity after a trial of home-based therapy with each protocol. The participants will administer 30 min of TSS daily for six days with each of the four TSS protocols selected randomly. This aim will reveal the long-term carry-over effects of TSS intervention on various components of spasticity after SCI. Aim 3. Determine the participants' experience with TSS as a home-based therapy through focus group meetings. We will conduct focus group meetings after participants finish the home-based therapy trial. Accomplishing this specific aim will provide a valuable perspective on the value, challenges, and acceptability of TSS as a home-based intervention. The study addresses important questions for advancing scientific knowledge and clinical management of spasticity after SCI. Specifically, it will examine the efficacy of TSS frequencies and intensities on tonic and phasic spasticity. The study results will be relevant for a high proportion of individuals living with SCI that could benefit from this novel and low-cost non-pharmacological approach to managing spasticity after SCI.
Tele-rehabilitation Using tDCS Combined With Exercise in People With Spinal Cord Injury
Spinal Cord InjuryIncomplete Spinal Cord InjuryThis study aims to explore the effect of trans cranial direct current stimulation (tDCS) combined with self-exercise at home for 1 month training (3 sessions/week, for 4 weeks). The outcome assessment including motor function, functional activity, spasticity through neurological assessment (H reflex latency and H/M amplitude ratio) and quality of life will be assessed before, after the intervention and at 1- month follow-up. Participant will communicate with physical therapist via video online platform for every sessions (12 sessions).
Spinal Cord Stimulation for Spinal Cord Injury Patients - Regain Walk and Alleviate Pain
Spinal Cord InjuryThe study aims to examine the plausible interventional mechanisms underlying the effects of epidural spinal cord stimulation.
Efficacy of a Brain-Computer Interface Controlled Functional Electrical Stimulation Therapy for...
Cervical Spinal Cord InjuryThe study's main goal is to determine the efficacy of a therapy with brain-computer interface controlled functional electrical stimulation for neurorehabilitation of spinal cord injury patients' upper limbs. For this purpose, a randomized controlled trial will be performed to compare the clinical and physiological effects of the brain-computer interface therapy with those of a sham intervention comprised by the application of functional electrical stimulation independently of brain-computer interface control.
Systemic Hypothermia in Acute Cervical Spinal Cord Injury
Spinal Cord InjuryAcuteThis study is a prospective multi-center trial designed to determine the safety profile and efficacy of modest (33ºC) intravascular hypothermia following acute cervical (C1 to C8) Spinal Cord Injury (SCI).