View clinical trials related to Spinal Cord Injuries.
Filter by:Chronic pain affects 1 in 4 US adults, and many cases are resistant to almost any treatment. Deep brain stimulation (DBS) holds promise as a new option for patients suffering from treatment-resistant chronic pain, but traditional approaches target only brain regions involved in one aspect of the pain experience and provide continuous 24/7 brain stimulation which may lose effect over time. By developing new technology that targets multiple, complimentary brain regions in an adaptive fashion, the investigators will test a new therapy for chronic pain that has potential for better, more enduring analgesia.
Rotator cuff disease (i.e., rotator cuff tendinopathy or tear) is a common cause of shoulder pain in persons with chronic spinal cord injury (SCI). It usually resolves with non-operative treatments such as pharmacological agents and physical therapy; however, when this fails, rotator cuff surgery may be the only option. Corticosteroid injections are another alternative to provide temporary relief, but can over time accelerate degeneration of the tendon and lead to further damage. Autologous adipose tissue injection has recently emerged as a promising new treatment for joint pain and soft tissue injury. Adipose can be used to provide cushioning and filling of structural defects and has been shown to have an abundance of bioactive elements and regenerative perivascular cells (pericytes). The purpose of this study is to explore the efficacy of autologous, micro-fragmented adipose tissue (Lipogems®) injection under ultrasound guidance for chronic shoulder pain in persons with SCI compared with the standard-of-care, corticosteroid injection.
INTRODUCTION: Due to the low incidence of pediatric spinal cord injury (SCI) and the high demand for knowledge and research, international cooperation is needed to build a solid and shared understanding of the extent of the problem, and also uniformity in treatment and measurement methods. The aim of the study is to map organization of care and rehabilitation of children and adolescents < 18 years of age with SCI, to explore qualitatively psychosocial aspects of individuals and to establish use of common outcome measures in 10 rehabilitation units from seven countries, cooperating within the Sunnaas International Network in Rehabilitation (SIN); China, USA, Russia, Israel, Palestine, Norway and Sweden. METHOD: In Phase I two cross-sectional studies will be conducted to set the scene for the outcome studies following in Phase II (2020-2022). Phase I consists of a quantitative descriptive study using a websurvey to describe and compare the systems of care and delivery of inpatient rehabilitation services for pediatric SCI patients. In addition, a qualitative study will explore the psychosocial aspects of living with a childhood acquired SCI. Two adolescents, aged 13-17 years and at least 6 months post-acute treatment, from each unit will interviewed using a semi-structured interview guide. Ethical approval has been applied for in each unit, and the study is registered at ClinicalTrial-gov. A workshop for the 24 study team members, where the main focus was to ensure that data collection is conducted in a good manner, was held in May 2018, and data collection is expected finalized by 2020. Phase II (planning stage) will consist of methodological outcome studies. DISCUSSION: Phase I of the study will broaden the body of knowledge on pediatric SCI internationally, thus enabling comparison, discussion and development of organizational models and quality of care and rehabilitation for young persons with SCI. Phase II will contribute to the use of common and reliable outcome measures for these patients.
This is a randomized clinical controlled trial (RCT) to investigate the impact of a personalized nutritional intervention on functional and clinical outcomes the first year after traumatic spinal cord injury. The long term goal is to prevent gain of body fat mass and obesity.
The main goal of the project is to develop multiple noninvasive neuromodulatory strategies to facilitate full weight bearing stepping overground in people with paralysis. We will determine the effectiveness of combining noninvasive spinal cord stimulation and the administration of buspirone (a monoaminergic agonist) in facilitating locomotor activity in a gravity-neutral apparatus, during body weight supported stepping on a treadmill, when stepping overground in an assistive robotic exoskeleton, or during full weight bearing stepping overground in a rolling walker. Our objective is to identify the experimental variables that define the efficacy of these novel neuromodulatory techniques over a 5 year period in 15 participants with severe spinal cord injury who are at least one year post-injury.
Functional electrical stimulation (FES) has been used to activate paralysed muscles and restore movement after spinal cord injury and stroke. This technology involves the application of low-level electrical currents to the nerves and muscles to cause muscle contraction where the user's ability to achieve that through voluntary means has been lost. Providing control of muscle contraction in a coordinated way can mean that users are able once again to produce functional movements in otherwise paralysed limbs. Routine clinical use is limited to the prevention of drop foot in the lower limb following stroke and occasional therapeutic use in the hand and shoulder. Systems providing functional reach and grasp, however, have not achieved clinical or commercial success. This project aims to develop methods for personalising assistive technology to restore arm function in people with high-level spinal cord injury. The investigators will use a combination of electrical stimulation to elicit forces in muscles no longer under voluntary control, and mobile arm supports to compensate for insufficient muscle force where necessary. The investigators will use computational models specific to an individual's functional limitations to produce patient-specific interventions. The project will be in three phases: building a model to predict the effects of electrical stimulation on a paralysed arm with arm support, development of methodologies using this model to optimise the arm support and stimulation system, and testing of stimulation controllers designed using this approach.
Spinal cord injury (SCI) is a devastating, life-altering injury; requiring tremendous changes in an individual's lifestyle. Cycling, provides an ideal way for individuals with SCI to exercise and address the long-term consequences of SCI by targeting the lower extremity muscles. Cycling with the addition of functional electrical stimulation (FES) allows persons with paralysis to exercise their paretic or paralysed leg muscles. The Queen Elizabeth National Spinal Injury Unit (QENSIU) in Glasgow offers FES cycling for people with spinal cord injuries, which combines functional electrical stimulation (FES) with a motorised ergometer that allows repetitive cycling activity. It stimulates muscles with electrodes attached to the skin, producing muscle contractions and patterned activity. So far no previous randomised control trials on FES cycling in the acute SCI population have reported changes in ability to undertake activities of daily living or the trunk balance.
Neuropathic pain is a common complication following spinal cord injury (SCI) that significantly decreases quality of life. Treatment options are limited, and current treatments can have significant side effects. Those with SCI have identified a need for additional treatment options, particularly those that are not medications. Nabilone and an anti-inflammatory diet are two treatments that may provide pain relief while being better tolerated. This study will evaluate the benefits of these treatments for neuropathic pain after SCI. Study participants will receive either an anti-inflammatory diet or a placebo diet, and nabilone or a placebo for 4 weeks. It is expected that an anti-inflammatory diet and nabilone will significantly decrease pain intensity and improve function. The combination of both treatments together is expected to have a greater effect than each alone.
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 hypo-perfusion of the spinal cord and exacerbates the severity of injury. This is also referred to as secondary injury. Thus, knowledge of spinal cord hypo-perfusion would allow the treating physician to optimize the hemodynamic condition of patient with acute spinal cord injury and potentially improve functional outcome. We plan to use contrast-enhanced ultrasound (CEUS) to determine decrease of blood flow in the spinal cord at the site of injury, during the routine surgery that these patients require to decompress and stabilize their injured spine. This may help us to determine the efficacy of certain treatments in improving blood flow and patients suffering from tSCI.
This study evaluates the feasibility and effects of H-MEX powered exoskeleton in individuals with paraplegia as a result of spinal cord injury.