205 Clinical Trials for Spinal Cord Injuries
The purpose of this study is twofold: (1) Develop a new evaluation scale for mental body representations (MBR, i.e., body awareness and visuospatial body maps) for adults with spinal cord injury (SCI) with and without neuropathic pain. (2) Assess the psychometric properties of usability, reliability, and validity of the new evaluation scale This is a cross-sectional observational study design. For Aim 1, this study will involve initial item generation for a novel MBR evaluation scale for SCI through email communication, and individual interviews proctored remotely through Zoom, or, if preferred by the participant, in-person. For Aim 2, the study will include a Zoom call for consenting and questionnaires, as well as an in-person visit where participants will be tested with the new SCI-BodyMap evaluation scale, and a questionnaire asking about the usability and satisfaction of the new evaluation scale.
This is an open-label study of andecaliximab in participants at risk of developing bone where bone should not be, such as in muscle, tendons, and other soft tissues following traumatic spinal cord injury. The goal of this study is to assess the safety of andecaliximab, how much drug is in the body over time (pharmacokinetics/PK), and how it affects the body (pharmacodynamics/PD) in participants who have had a recent traumatic spinal cord injury.
Spinal cord injury (SCI) disrupts neural pathways to respiratory motor neurons, diminishing breathing capacity and airway defense (e.g., cough). Indeed, respiratory impairment is a leading cause of infection, re-hospitalization and death after SCI. There is a critical need for new strategies to restore breathing ability and airway defense in people with SCI. Acute intermittent hypoxia (AIH) - repetitive exposure to brief episodes of low inspired oxygen - is a promising strategy to restore breathing capacity by promoting spinal neuroplasticity. Exciting outcomes in \>12 SCI trials completed to date demonstrate that AIH improves human respiratory and limb function. Unfortunately, \~40% of individuals exhibit minimal response to AIH, making it essential to 1) optimize AIH protocols to maximize functional benefits; and 2) identify genetic biomarkers distinguishing those most/least likely to benefit from AIH-based treatments. The purpose of the pilot study, to be conducted in a small sample of participants with sub-acute SCI (1 to 6 months post injury), is to preliminarily compare the immediate effects of two intermittent hypoxia protocols. Since AIH-induced plasticity may be induced via serotonin or adenosine-driven mechanisms and these pathways compete and inhibit each other, each protocol favors a distinct mechanistic pathway. The long-term objective is to test the hypothesis that a longer duration (i.e., augmented) hypoxia protocol, favoring adenosine mechanisms, enhances respiratory motor plasticity more than an AIH protocol targeting serotonin mechanisms (low O2 + CO2) in people with sub-acute SCI. Since an individual's genetics can influence the response to rehabilitation, investigators are also preliminarily investigating how certain genes are related to breathing changes after these treatments. Data acquired through this pilot study will be used to inform a larger, more definitive clinical trial and will contribute to estimations of the magnitude and direction of effects.
The goal of this observational study is to learn about the effects of a 9-week dietician-guided program modified from the National Diabetic Prevention Program (modified DPP-diet) in people with spinal cord injury on body composition and insulin sensitivity. The main question it aims to answer is: Does 9 week modified DPP-diet reduce body fat percentage and insulin resistance? Participants will: Have 9 weeks of Telehealth visit with dietician certified in providing DPP. Visit the laboratory before, immediately and 9 weeks after completion of the modified DPP-diet. Share with the researcher on the perceived benefit and obstacles in implementing the modified DPP-diet as part of their daily activities.
Stimulation of the spinal cord and brain represents a new experimental therapy that may have potential to restore movement after spinal cord injury. While some scientists have begun to study the effect of electrical stimulation on patient's ability to walk and move their legs after lower spinal cord injury, the use of stimulation of the upper (cervical) spine to restore arm and hand function after cervical spinal cord injury remains less well explored. The investigators are doing this research study to improve understanding of whether cervical spinal cord stimulation and brain stimulation can be used to improve arm and hand function. To do this, the investigators will combine spine stimulation (in the form of electrical stimulation from electrical stimulation wires temporarily implanted next to the cervical spinal cord) and brain stimulation (in the form of transcranial magnetic stimulation). The investigators will perform a series of experiments over 29 days to study whether these forms of stimulation can be applied and combined to provide improvement in arm and hand function.
The purpose of this study is to test a strategy to potentiate functional recovery of lower limb motor function in individuals with spinal cord injury (SCI). The FDA approved drug, Dalfampridine (4-AP). 4-AP will be used twice-daily in combination of Spike-timing-dependent plasticity (STDP) stimulation and STDP stimulation with limb training.
The DOSED clinical study evaluates the safety and utility of a novel delivery device to deliver LCTOPC1, a cell therapy, to the spinal cord of patients with a spinal cord injury (SCI). LCTOPC1 is designed to replace or support cells that are absent or dysfunctional due to traumatic injury, with a goal to help improve the quality of life and restore or augment functional activity in persons suffering from a traumatic cervical or thoracic injuries.
The University at Buffalo (UB) Department of Rehabilitation Sciences is looking for adult volunteers with and without spinal cord injuries for a study on hand movement. The goal of the study is to learn about how the brain, nerves, and muscles of the body are connected and perform everyday tasks. This may help us to develop ways to improve the hand functions of people with spinal cord injuries.
The purpose of this clinical trial is to understand the safety and practicality of using spinal cord transcutaneous (through the skin) stimulation in an inpatient setting as well as how the combination of activity-based training (ABT) and spinal cord transcutaneous stimulation (scTS) can improve participants' ability to use their hands, arms, and trunk in an inpatient rehabilitation program. The main questions it aims to answer are: * Is the combination of spinal cord transcutaneous stimulation and ABT is safe and practical when applied to individuals with acute to subacute cervical SCI during inpatient rehabilitation? * How the combined intervention can improve hand and arm function when applied to those individuals? The investigators will assess the safety, feasibility, and preliminary efficacy of the combined intervention and compare to a sham control (sham stimulation combined with ABT) and a ABT only group to see if the combined intervention can lead to greater function recovery. Participants will: * Receive one type of the three intervention (scTS+ABT, sham scTS+ABT, or ABT only) for 10 sessions with 30 mins/session over 2 weeks. * Receive assessment before, during, and immediately after the intervention, and at 1-month, 2-month, and 3-month follow-up visits.
The goal of this pilot clinical trial is to find out how well low dose naltrexone works for people with pain due to spinal cord injury. The main questions it aims to answer are: will low dose naltrexone reduce pain, and increase the quality of life for people with central neuropathic pain due to spinal cord injury. Hypothesis 1: LDN will decrease the severity of CNP in adult patients with SCI as measured by the Neuropathic Pain Scale (NPS) Hypothesis 2: LDN will improve quality of life of patients with SCI as measured by various validated clinical tools There is no comparison group. This study is being completed to give investigators more information for how to best run a larger clinical trial. Participants will be asked to take an oral dose of 4.5mg of naltrexone, daily, for 12 weeks.
It is not known whether a new diabetes drug, semaglutide, is an effective treatment for type 2 diabetes for persons with spinal cord injury (SCI), a population at higher risk for this condition. Therefore, this study looks at the effect of semaglutide on glucose levels in the body and other information about type 2 diabetes and obesity.
The purpose of this research is to examine the effects that functional electrical stimulation (FES) therapy has on the way the arms, brain and spinal cord work. The study team wants to understand what recovery looks like in persons with a spinal cord injury (SCI) or peripheral nerve injury (PNI) using the MyndMove (MyndTec Inc., Ontario, Canada) therapy system. This type of therapy uses stimulation to help people with SCI and other neurological conditions to perform common tasks, work out, or strengthen muscles.
Patients with traumatic spinal cord injury (tSCI) often suffer from spinal cord swelling inside the thecal sac, which contains the spinal cord and surrounding fluid, leading to increased pressure on the spinal cord tissue and decreased spinal cord blood flow at the site of injury. The combination of increased pressure and decreased blood flow causes vascular hypoperfusion of the spinal cord and exacerbates the severity of injury. This is also referred to as secondary injury. Thus, knowledge of spinal cord hypoperfusion would allow the treating physician to optimize the hemodynamic condition of the patient with acute spinal cord injury and potentially improve functional outcomes.
The purpose of this study is to understand how standing and sitting balance control is altered after spinal cord injury and how a new type of robotic assistive device may be used with spinal stimulation to improve muscle function. The investigators will be testing a device called the Tethered Pelvic Asist Device (or "TPAD") in this study. The TPAD may be helpful in two ways. It can be used to help control and support of the trunk, pelvis, and knees during stand training. Also, the TPAD can be used as a training tool by providing controlled "pushes" or "perturbations" that must be corrected by the person with spinal cord injury in order to maintain proper posture and upright balance. This could be helpful for improving muscle function after spinal cord injury. Participants will be placed into one of two groups based on availability and preference. Group 1 will receive TPAD training with stimulation and assessments with and without stimulation. Participation in this group lasts approximately 4 months. Group 2 will only receive assessments with and without stimulation. Participation in this group last approximately 3 weeks.
This is a first-in-human, Phase 1b/2a, open-label, dose-escalation study of a single treatment course consisting of multiple intradetrusor injections of EG110A in male and female adult participants with Neurogenic Detrusor Overactivity (NDO)-related incontinence following Spinal Cord Injury (SCI), who have persistent incontinence after standard of care therapy and who perform Clear Intermittent Catheterization (CIC) on a regular basis.
The purpose of this research is to test if Auricular Vagal Nerve Stimulation (aVNS) is safe in persons with spinal cord injury (SCI).
This is a Phase 1b study to assess the safety, tolerability, PK, and PD of investigational phage therapy (IP) in adults with SCI and bladder colonization (ASB). It is a single-center, randomized, double-blind, placebo-controlled study in adults with SCI with neurogenic bladders and bacteriuria who use indwelling catheters, or who require intermittent catheterization for bladder drainage.
The goal of this prospective observational study is to determine whether brief intraoperative electrical stimulation and temporary postoperative electrical stimulation improve motor and/or pain outcomes for patients with cervical spinal cord injury undergoing standard of care nerve transfer surgery to improve hand function. The main hypotheses include: Hypothesis #1: Brief intraoperative electrical stimulation of the donor nerves will result in improved motor outcomes (hand function) compared to standard nerve transfer surgery in patients with cervical spinal cord injuries. Hypothesis #2: Placement of a temporary peripheral nerve stimulator for 60 days of postoperative electrical stimulation will result in improved pain outcomes compared to standard nerve transfer surgery in patients with cervical spinal cord injuries. Researchers will prospectively enroll patients with cervical spinal cord injury and no hand function who will undergo standard of care nerve transfer surgery combined with standard of care brief intraoperative electrical stimulation and temporary postoperative electrical stimulation. Motor and pain outcomes will be compared to a retrospective group of patients who underwent nerve transfer surgery without intraoperative or postoperative electrical stimulation. Participants will receive standard medical care (nothing experimental) as part of this study. Participants will: * Have a preoperative assessment including physical examination, electrodiagnostic studies, functional electrical stimulation, and will complete questionnaires assessing function and quality of life * Agree upon a surgical plan, including the specific nerve transfers to be performed and whether to include brief intraoperative electrical stimulation and/or temporary postoperative electrical stimulation before being considered for enrollment in the study * Will undergo standard of care nerve transfer surgery, with at least one nerve transfer targeting improvement in hand function and will receive brief intraoperative electrical stimulation of the donor nerves and placement of a temporary peripheral nerve stimulator * Will follow-up with the surgeon 3, 6, 12, 24, and 36 months after the surgery * Will have a physical examination and will complete questionnaires at the postoperative visits * Will participate in hand therapy following the operation * Will be eligible for placement of a permanent peripheral nerve stimulator, depending on response to the temporary peripheral nerve stimulator.
The study will be a non-randomized, non-blinded pilot study to analyze the safety and feasibility of a non-significant risk device, transcutaneous spinal cord stimulation. The aim is to include 30 total patients, 10 patients in each of 3 groups: 1. Non-traumatic spinal cord injury (ntSCI) with diagnosis of degenerative cervical myelopathy and offered surgical intervention. 2. Early tSCI screened during the hospital admission when cervical/thoracic spinal injury was diagnosed. 3. Delayed tSCI (control) screened 6-24 months after acute cervical/thoracic spinal injury.
The purpose of this research is to explore the effect of magnetic stimulation to activate the brain, electrical spinal cord stimulation to activate spinal cord, and electrical muscle stimulation used to activate upper limb (arms), lower limb (legs) and trunk (stomach) muscles in people with spinal cord injury (SCI) and able-bodied subjects (without SCI).
The purpose of this study is to assess the effect of various hemodynamic management strategies on functional neurologic outcomes and non-neurologic adverse events in the first 5 days following acute spinal cord injury (SCI). The hemodynamic management strategies assessed include targeting a mean arterial blood pressure (MAP) goal of 85-90 mmHg, targeting a spinal cord perfusion pressure (SCPP) goal of ≥65 mmHg, or targeting normal hemodynamics, which is a MAP goal of ≥65 mmHg.
The goal of this clinical trial is to evaluate safety and tolerability of multiple oral doses of EC5026 in male and female patients with neuropathic pain due to spinal cord injury. The main question it aims to answer is whether EC5026 is safe and well tolerated in SCI patients with neuropathic pain. In addition, this trial will also study the effects of EC5026 on pain. Researchers will compare EC5026 to placebo. Participants will be asked to: * Take EC5026 or placebo in a masked fashion, once daily, for 14 consecutive days. * Undergo physical exams, vital signs assessments, ECGs, and blood draws * Complete assessments of pain, sleep, functional status, and perception of change
The purpose of this research is to test the effectiveness of a new therapy, called Brain-Computer Interface (BCI)-Transcutaneous Spinal Cord Stimulation (TSCS), for improving walking in people with an incomplete spinal cord injury (SCI).
The primary objective of this study is to gather information about the effectiveness of abdominal FES to improve bowel management time (BMT) for people with chronic SCI. This study will also evaluate whether abdominal FES can improve: 1) bowel-related quality of life, 2) participant-reported bowel function, 3) bowel management strategy, 4) bladder symptoms, and 5) unplanned hospital admissions. In addition, we will also explore participant perspectives and experiences about the stimulation sessions and use of the device.
The purpose of this study is to determine if playing a virtual reality walking game can help improve neuropathic pain in adults with incomplete spinal cord injury.
The heart and brain are regulated by the autonomic nervous system. Control of these organs can be disrupted in people with spinal cord injury (SCI). This may affect their ability to regulate blood pressure during daily activities and process the high-level information. Previous studies show that high-intensity exercise induces better outcomes on heart and information processing ability in non-injured people compared to moderate-intensity exercise. However, it is unknown the effects of high-intensity exercise on heart and brain function in people with SCI. Therefore, this study aims to examine the effects of a single bout of high-intensity interval training on heart and brain function in this people with SCI compared to age- and sex-matched non-injured controls.
People with spinal cord injuries may experience muscle tightness or uncontrollable spasms. This study is being conducted to investigate whether transcutaneous spinal stimulation can improve these symptoms. Transcutaneous spinal stimulation is a non-surgical intervention by applying electrical currents using skin electrodes over the lower back and belly. The investigators want to see how well the intervention of transcutaneous spinal stimulation performs by testing different levels of stimulation pulse rates. Also, transcutaneous spinal stimulation is compared to muscle relaxants such as baclofen and tizanidine, commonly given to people with spinal cord injuries, to reduce muscle stiffness and spasms. By doing this, the investigators hope to discover if transcutaneous spinal stimulation similarly reduces muscle spasms and stiffness or if combining both methods works best. This could help improve treatment options for people with spinal cord injuries in the future.
Aim 1: Determine the safety and feasibility of administration of TSCS to children in a clinical setting. Participants will be randomly assigned to experimental (TSCS) or control (sham stimulation) groups. Both groups will receive eight-weeks of individualized gait training. We will measure adverse events, including pain and skin irritation, to determine safety as the primary outcome. Hypothesis 1: Administration of TSCS to children in a clinical setting will be safe based on similar safety outcomes as sham TSCS. Hypothesis 2: TSCS is feasible based on compliance to session interventions and long-term adherence to the protocol. Additionally, we will collect data on effort during sessions of both participant and therapist. We anticipate that the participants will report less effort in the experimental condition, as compared to the control and therapists will report equal effort across conditions. Aim 2: Determine the neurophysiologic impact of TSCS within a single session. We hypothesize that participants will demonstrate increased volitional muscle activity and strength with TSCS as compared to sham stimulation. This will be assessed by surface EMG and hand-held dynamometry of the dominant-side quadriceps muscle during maximum volitional contraction (MVC), across multiple time points. Changes in EMG activity will indicate change in central excitability in response to stimulation. Aim 3: Exploratory measurement of TSCS and gait training on walking function. We hypothesize that concurrent TSCS and gait training will augment walking function in children with iSCI, as compared to gait training with sham stimulation. In addition to outcomes defined above, participants will be assessed with clinically relevant outcome measures, to include the Timed Up and Go, 10-Meter Walk Test, Walking Index for Spinal Cord Injury II, and 6-Minute Walk Test. Data collected as part of this aim will elucidate trends in responder qualities and timeline of changes to inform future studies.
Living with spinal cord injury (SCI) can have a significant negative impact on an individual's mental health and restrict participation in personally valued activities and roles. Acceptance and commitment therapy (ACT) is an evidence-based approach that can lessen symptoms of mental health disorders (e.g., depressive symptoms) and improve quality of life through mindfulness and acceptance processes and behavior change processes for valued living. Evidence for ACT for individuals living with SCI, however, is limited to a very few studies that involved in-person group-based ACT and did not focus on depressed individuals with SCI. The primary goal of this study is to evaluate the effects of an 8-week videoconferencing ACT program on improving mental health outcomes in depressed individuals living with SCI. The primary hypotheses are that the ACT group will show improvements in depressive symptoms at posttest and 2-month follow-up compared to the wait-list control group. Investigators will invite 120 individuals living with SCI and reporting depressive symptoms and randomly assign them to either the ACT group or the wait-list control group. The ACT group will receive eight weekly individual ACT sessions guided by a coach through videoconferencing with a booster session at 1-month follow-up. The wait-list control group will continue his or her own care as usual during the study period and have the option to receive eight individual ACT sessions after study participation ends. Data will be collected at pretest, posttest, and 2-month follow-up and compared between the ACT group and the control group over time. About 40% of individuals living with SCI report depressive symptoms and other mental health symptoms, and mental health disorders following SCI are associated with negative long-term outcomes. Managing uncomfortable or painful thoughts and emotions arising from functional limitations and accepting changed lives while moving forward for valued living through ACT skill practice will help individuals with SCI alleviate symptoms of mental health conditions, promote engagement in personally valued activities, and improve quality of life.
The purpose of this study is to develop a health promotion group intervention to meet the unique health promotion needs of people aging with SCI, to test the efficacy of the adapted intervention program, Living Longer and Stronger with SCI, in a randomized controlled trial and to assess the mechanisms through which the intervention may enhance physical, psychological, and social health.