Active clinical trials for "Spinal Cord Injuries"

This project aims to evaluate the safety and efficacy of using a short-acting drug to reduce the maximal blood pressure during dangerous blood pressure spikes that happen during bowel care in individuals with spinal cord injury. the investigators will monitor the physiological effects of this drug during at-home bowel care to best understand the drug's effects in typical use.

Regular physical activity improves physical fitness, fatigue, quality of life, gait and reduces progression of the disability in persons with SCI. However, persons with SCI are less physically active than the general population. Approximately 50% of people with SCI experience fatigue which impacts their daily activities. Ischaemic preconditioning (IPC) is exposure of the body to brief periods of circulatory occlusion and reperfusion to protect organs against ischaemic injury. Recent studies have shown that IPC also improves exercise performance in healthy participants. The aim of this study is to determine whether it is feasible to use IPC to improve upper-body exercise performance in people with SCI. Setting: Potential candidates will be identified from the Outpatient clinic at the Princess Royal Spinal Injuries Hospital (PRSCIC), Northern General Hospital, Sheffield. Design: Acute single blind randomised controlled trial. Forty patients with SCI above 18 years and with preserved triceps function to conduct triceps strength testing will be randomised to receive either an IPC or sham intervention. Interventions: IPC will be administered to the upper limb using cuff inflation pressures of 200 mmHg or 60mm Hg above the systolic BP (whichever is higher). Four cycles of cuff inflation each lasting 5 min in duration followed by 5-min period of cuff deflation will be applied. The Sham intervention will be administered with a BP cuff over the upper arm being inflated at a pressure 30mmg Hg below the diastolic blood pressure. The sham cycles will comprise of four cycles of cuff inflation each lasting 5 min in duration followed by 5-min period of cuff deflation. Researchers will assess the feasibility of IPC as well as its efficacy to improve triceps maximal voluntary contraction and endurance compared with Sham.

The goal of this clinical trial is to learn more about the enteric nervous system (ENS) and the intestinal epithelial barrier (IEB) in patients with spinal cord injury (SCI). The main questions it aims to answer are : to characterize the functional (permeability, serotonin production, enteric neuronal phenotype, etc.), proteomic (junction molecules) and transcriptomic (inflammation genes, neuromediator expression, etc.) remodeling of the colonic mucosa and ENS in SCI patients, in comparison with control data. to correlate intestinal permeability (and all remodeling parameters) with the type of neurological impairment i.e. the neurological level of the lesion, quantification of neurological impairment (motor and sensory scores) and the completeness and incompleteness of a lesion. to identify a link with disease severity markers to identify therapeutic targets that could subsequently be tested in the animal model before being proposed in clinical trials. Participants will have colonic biopsies taken following a colonoscopy/rectosigmoidoscopy previously indicated for spinal cord injured patients. Biopsies will be obtained from the right and left colon.

For many people with spinal cord injury or brain injury, seeking employment after injury is an important goal. There are services available to help people with disabilities. However, the best ways to coordinate and deliver these services are not yet known. This project will compare two ways of coordinating and delivering services that are designed to help people with spinal cord injury or brain injury obtain employment.

NeuroSuitUp is a multidisciplinary neurophysiological & neural rehabilitation engineering project, developed by the Lab of Medical Physics & Digital Innovation, School of Medicine, Faculty of Health Science Aristotle University of Thessaloniki and supported by a Neurosurgical Department. This research is co-financed by Greece and the European Union (European Social Fund- ESF) through the Operational Programme "Human Resources Development, Education and Lifelong Learning 2014- 2020" in the context of the project ""NeuroSuitUp"" (MIS 5047840). The website for the project can be accessed at https://imedphys.med.auth.gr/project/neurosuitup . The investigation's primary objectives include the development, testing and optimization of an intervention based on multiple immersive man-machine interfaces offering rich feedback, that include a) mountable robotic arm controlled with wireless Brain-Computer Interface and b) wearable robotics jacket & gloves in combination with a serious game application and c) augmented reality module for the presentation of the previous two, as well as the development and validation of a self-paced neuro-rehabilitation protocol for patients with Cervical Spinal Cord Injury and the study of cortical activity in chronic spinal cord injury.

Background: Patient engagement is a cornerstone of patient-centered care. Studies show that an increased level of patient engagement in medical rehabilitation is associated with greater functional recovery. To achieve higher levels of patient engagement, it is important to improve therapists' techniques for goal setting and clinician-therapist communication. Thus, we have developed a manualized intervention for post-acute rehabilitation, Enhanced Medical Rehabilitation (EMR), which is an evidence-based program to increase patient engagement and achieve a greater intensity of therapy, thereby optimizing the patient's functional and psychosocial recovery. EMR is an integrated set of skills for occupational and physical therapists that transform rehabilitation through (1) a patient-directed, interactive approach; (2) increased treatment intensity; and (3) frequent feedback to patients on effort and progress. We have developed training and supervision methods to enable therapists to carry out these skills with high fidelity. In our previous EMR study of older adults in skilled nursing facilities, patients treated by EMR-trained therapists had greater engagement in therapy, higher-intensity therapy sessions, and better functional outcomes. Due to the complexity of the inpatient spinal cord injury (SCI) rehabilitation environment, it is unknown whether the EMR program will be clinically relevant to inpatient rehabilitation settings and acceptable to SCI populations. Therefore, it is necessary to conduct a systematic adaptation approach to address all hospital- and provider-level barriers, and test this adapted program to a new setting (inpatient rehabilitation) and a new population (patients with SCI), without compromising the core elements of the original EMR. Objective: We propose to adopt the EMR program for use in inpatient SCI rehabilitation settings using an implementation science-driven approach. We also propose a randomized trial of 80 patients with SCI to test the effects of EMR on improving engagement and treatment intensity, as well as functional and psychosocial outcomes over standard of care (SOC) rehabilitation. Methods: We will randomize patients into EMR or SOC groups. For the EMR group, four therapists will be trained and supervised in EMR and will incorporate EMR techniques into therapy sessions. In the SOC group, four therapists will carry out therapy sessions as usual. Expected Outcomes: With respect to EMR intervention adaptions, we hypothesize that the EMR program, including a treatment manual and other materials, will be customized with input from our Spinal Cord Injury-Community Advisory Board (SCI-CAB). Patients randomized to EMR will have greater engagement and intensity and greater functional and psychosocial recovery compared to those randomized to SOC rehabilitation. Significance: The impact is high. EMR is patient-centered rehabilitation, and it is designed for real-world clinical practice. Success in this line of research will improve therapists' skills working with patients and optimizing patient outcomes, ensuring that inpatient SCI rehabilitation is more patient-centered, to the benefit of individuals with SCI.

Over one million Americans rely on their upper extremities for manual wheelchair propulsion. Shoulder overuse injuries are prevalent among manual wheelchair users and these injuries often result in shoulder pain. Severe shoulder pain can lead some wheelchair users to transition from manual to powered mobility, complicating transportation, and reducing independence in activities of daily living. This project will expand the understanding of a new wheelchair design that allows better positioning of the hand rims and allows for different gearing. The investigators will study steady-state propulsion efficiency with different gear ratios and develop a new system with multiple gear ratios. The advanced gearing will allow for a low gear when initiating movement, going uphill, or when moving over carpet, and then a higher gear option for movements on hard flat level terrain. This system has the potential to dramatically improve shoulder ergonomics and reduce pain in many future manual wheelchair users.

The goal of this descriptive non-randomized feasibility study is to assess aspects of feasibility of the intervention arm in a planned full-scale randomized controlled trial testing the effectiveness of a self-management program for persons who have sustained a moderate to severe traumatic injury. All outcomes will be evaluated based on pre-defined success criteria. The main outcomes in the feasibility study are: Consent rate of eligible patients Drop-out rate Attendance rate in the program sessions Secondary outcomes are the participants' acceptance, reception, and perceived usefulness. Other outcomes are fidelity and protocol adherence, as well as the feasibility of a telehealth version of the program and the data collection methods. The participants will receive a group-based self-management program consisting of eight weekly 2.5-hour sessions delivered by a multidisciplinary team. The self-management program is manualized and includes psychoeducation, training in self-management skills and strategies, setting goals, action planning, and sharing of experiences. The participants will also complete the pre- and post-intervention assessments.

Rehabilitation robotics has the potential to facilitate rehabilitation at home and empower people with spinal injuries to self-manage increasing their independence and improving their quality of life. The objective of this study is to assess for the first time in the NHS the efficacy of a commercial robotic orthosis for upper limb rehabilitation in patients with spinal cord injury. The device is produced by Myomo (myomo.com) which is an American company. We will be assessing the wearable robotic orthosis also known as robotic exoskeleton in two different neuro-rehabilitation centres: National Spinal injuries Unit in Glasgow (Scotland) and The Robert Jones and Agnus Hunt Orthopaedic Hospital in Oswestry (England). The study will involve nine spinal cord injured tetraplegic inpatients in total. Patients will follow a twelve-week rehabilitation programme with three to four sessions per week in addition to their usual care and rehabilitation. Each session lasts for approximately 45 minutes. Participants arm function, range of motion, spasticity level will be measured before, half-way and at the end of the programme to assess change in these and other parameters. Training will focus on the dominant arm of the patient and compared to the other arm at every assessment stage. We shall evaluate therapists' and patients' satisfaction with the commercial device in addition to assessing various clinical measures to evaluate the efficacy of using the robotic orthosis in rehabilitation and recovery of arm function.

Persons with higher levels of spinal cord injury (above the 6th thoracic vertebrae: Hi-SCI) are unable to maintain their core body temperature (Tcore) within the normal range (97.5-99.7 °F) when exposed to warm environments. Even limited exposure to warm temperatures can cause hyperthermia (Tcore 100.4°F) in Hi-SCI. Mild hyperthermia causes discomfort and impaired thinking, but if unchecked, can lead to permanent damage to the brain, multiple body organ failure, and death. Warm seasonal temperatures have an adverse effect on personal comfort and the ability to participate in daily social activities in persons with Hi-SCI. Interventions addressing this vulnerability to hyperthermia are limited. A self-regulating "smart" cooling vest designed for persons with Hi-SCI, that can effectively dissipate body heat, is a novel and promising strategy to address this problem. Once the current prototype is further developed and bench-tested, the investigators will test the vest in able-bodied participants for safety and comfort. The investigators will then test the vest in participants with Hi-SCI for efficacy. The aim for the cooling vest to minimize the expected increase of 1.1°F in Tcore by at least 50 percent and increase thermal comfort, during a controlled exposure to heat (95°F). If successful, the vest will provide a promising intervention to decrease the adverse impact of warm temperatures on comfort, quality of life, and participation in societal functions for Veterans with Hi-SCI during the warmer seasons.