View clinical trials related to Spinal Cord Injuries.
Filter by:Ninety-nine individuals meeting the study's inclusion/exclusion criteria will be enrolled in this study. The objective of this study is to evaluate three different therapeutic approaches to synergistically retrain functional movement patterns of the upper extremities in combination with trunk stabilization to promote neurologic and functional recovery after SCI. Each subject will complete 40 sessions of intervention. Subjects will also complete a Baseline Evaluation (week 0), Re-Evaluation (week 4), Post Treatment Evaluation (week 8), and a Follow-Up Evaluation (week 12).
The overall purpose of this study is to test the efficacy of multi-modal training combining activity-based locomotor training and transcutaneous spinal stimulation (ABLT+scTS) to improve sitting posture and trunk control in children with a chronic spinal cord injury. The investigators will recruit 12 participants, ages 3-12 with chronic, acquired SCI, T10 and above and non-ambulatory. The participants in this study will be novices to scTS and AB-LT.
Chronic spinal cord injury (SCI) pain is complex and difficult to treat. For individuals with SCI, pain often begins early in the course of their SCI and continues longitudinally. Unfortunately, SCI-related pain is frequently not responsive to medical treatment and medical treatments that are available and commonly used, such as opioids, have negative side-effects and risk of addiction. Nonpharmacological (non-medication) interventions to reduce chronic pain show promise both for individuals with SCI as well as other chronic pain conditions. Research on psychological interventions for chronic pain over the past two decades has consistently found these interventions to be more effective than no treatment, standard care, pain education, or relaxation training alone. However, many of these interventions are designed and implemented in outpatient settings after chronic pain has already developed. The development of early, effective, and preventative interventions to reduce the development of chronic pain has the potential to vastly improve quality of life for individuals with SCI. Having demonstrated the feasibility and acceptance of this treatment in an earlier study, the purpose of this randomized clinical trial is to compare the treatment of Hypnosis Enhanced Cognitive (HYPCT) therapy to Pain Education (ED) for reducing acute and chronic pain for individuals with new spinal cord injuries. The main goals of the study are to: - Aim 1: Test the effectiveness of HYPCT during inpatient rehabilitation for SCI compared to a ED for reducing current pain intensity. - Aim 2: Determine the post-intervention impact of HYPCT sessions compared to ED on average pain intensity. Participants will be asked to: - Complete 4 surveys over seven months - Complete pre and post treatment pain assessments for each of 4 treatment/control sessions Participants will be assigned to one of two groups for treatment and receive either: - 4 Hypnotic Cognitive therapy sessions or - 4 Pain Education sessions
The purpose of these case studies is to determine the efficacy of the Kinesthetic Awareness Training (KAT) device in facilitating the restoration of desired movement patterns when people with acquired central nervous system damage perform functional activities such as walking, transitioning from one position to another, or reaching with the arms.
The aim of the study is to investigate the effects of 6 weeks of technological-assisted rehabilitation on function of upper extremity and hand in subjects with incomplete cervical spinal cord injury.
In a current first-in-human study, called Stimulation Movement Overground (STIMO, NCT02936453), Epidural Electrical Stimulation (EES) of the spinal cord is applied to enable individuals with chronic severe spinal cord injury (SCI) to complete intensive locomotor neurorehabilitation training. In this clinical feasibility study, it was demonstrated that EES results in an immediate enhancement of walking function, and that when applied repeatedly as part of a neurorehabilitation program, EES can improve leg motor control and trigger neurological recovery in individuals with severe SCI to a certain extent (Wagner et al. 2018). Preclinical studies showed that linking brain activity to the onset and modulation of spinal cord stimulation protocols not only improves the usability of the stimulation, but also augments neurological recovery. Indeed, rats rapidly learned to modulate their cortical activity in order to adjust the amplitude of spinal cord stimulation protocols. This brain-spine interface allowed them to increase the amplitude of the movement of their otherwise paralyzed legs to climb up a staircase (Bonizzato et al. 2018). Moreover, gait rehabilitation enabled by this brain-spine interface (BSI) augmented plasticity and neurological recovery. When EES was correlated with cortical neuron activity during training, rats showed better recovery than when training was only supported by continuous stimulation (Bonizzato et al. 2018). This concept of brain spine-interface was validated in non-human primates (Capogrosso et al. 2016). Clinatec (Grenoble, France) has developed a fully implantable electrocorticogram (ECoG) recording device with a 64-channel epidural electrode array capable of recording electrical signals from the motor cortex for an extended period of time and with a high signal to noise ratio the electrical signals from the motor cortex. This ECoG-based system allowed tetraplegic patients to control an exoskeleton (ClinicalTrials.gov, NCT02550522) with up to 8 degrees of freedom for the upper limb control (Benabid et al. 2019). This device was implanted in 2 individuals so far; one of them has been using this system both at the hospital and at home for more than 3 years. We hypothesize that ECoG-controlled EES in individuals with SCI will establish a direct bridge between the patient's motor intention and the spinal cord below the lesion, which will not only improve or restore voluntary control of leg movements, but will also boost neuroplasticity and neurological recovery when combined with neurorehabilitation.
After partial spinal cord injury, gait deficits may be present and often remain even after intensive rehabilitation. New robotic technologies have recently emerged to help augment the extent of rehabilitation. However, these are complex tools to integrate into clinical practice and little is known about the potential factors that may influence the uptake of a locomotor program using this technology by clinicians. The goal of this project is to bring together researchers, administrators, clinicians and patients to define and implement an overground robotized gait training program in clinic. We will also investigate the added value of leg and trunk muscle stimulation combined with robotic walking training, to see if it could enhance recovery.
The overall goal of Transforming Research and Clinical Knowledge in Spinal Cord Injury (TRACK-SCI) study is to determine the relationships among the clinical, neuroimaging, cognitive, genetic and proteomic biomarker characteristics of acute traumatic spinal cord injury (SCI). TRACK-SCI seeks to combine high quality care variables with high density physiology data collection to better understand diagnose, characterize, and track the temporal profile of recovery for SCI patients. The Investigators are enrolling patients within 24 hours of injury who present to a TRACK-SCI site with a spinal cord injury that meets eligibility criteria.
A common therapeutic intervention after spinal cord injury (SCI) is prolonged standing in a standing frame. For people with SCI, standing for 40 minutes or more, three to four times weekly improves several health-related issues including well-being, circulation, skin integrity, reflex activity, bowel and bladder function, digestion, sleep, pain, and fatigue. However, a person who experiences orthostatic hypotension (OH)-defined as a decrease of 20mm hg in systolic blood pressure or a decrease of 10mm hg in diastolic pressure within 3 minutes of standing from a sitting or supine position-secondary to SCI may not tolerate positioning in a standing frame, thus resulting in a loss of access to these health benefits. OH is common for people with SCI. It results from central nervous system dysregulation causing pooling of blood in the lower extremities that can lead to dizziness, light-headedness, blurred vision, weakness, fatigue, nausea, palpitations, headache, and/or syncope. Although an array of physical and pharmacologic interventions are available to people in the general population for managing OH, few such interventions have been evaluated for use by people with SCI, especially when the level of injury is C5 or above. One possible intervention that may be effective for people with OH secondary to SCI is functional electrical stimulation (FES) because its application results in a dose-dependent increase in blood pressure. An unanswered question is whether the placement of FES electrodes on various parts of the body has differential effects. Therefore, the purpose of this study is to evaluate blood pressure responses among people with OH secondary to cervical SCI when receiving FES intervention involving the placement of electrodes in three different positions as well as when receiving no FES intervention during tilt table sessions. The selected positions for electrode placement are: (a) the calves, (b) the quads and abdominals, and (c) the quads, abdominals, and calves. The researchers hypothesize that FES intervention, regardless of placement, will result in better control of OH than no FES intervention and that no significant blood pressure difference will occur across the three FES placements.
The purpose of this study is to evaluate the possibility to use electromyography in acute phase after a traumatic spinal cord injury to measure quantitatively and objectively the bulbocavernosus reflex. This study also aims to determine if there is a relationship between the bulbocavernosus reflex and neuro-functional recovery 3 months after a traumatic spinal cord injury. To do so, 20 patients admitted for acute traumatic spinal cord injury will be recruited prospectively. Within 72 hours post-trauma, the bulbocavernous reflex of all participants will be assessed according to the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI) and by electromyography. Neurological improvement during the rehabilitation process and functional status at 3 months following the traumatic spinal cord injury will also be assessed.