View clinical trials related to Spinal Cord Injuries.
Filter by:This proof-of-principle study will determine if breathing an increased concentration of oxygen above the concentration in normal room air results in changes in the sensory and motor function in people with subacute or chronic, severe spinal cord injury (SCI).
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.
Reduced arm and hand function has a significant impact on independence and quality of life after spinal cord injury. Functional electrical stimulation therapy (FES-T) is a treatment that can produce improvements in reaching and grasping function after neurological injuries. However, not all paralyzed muscles respond equally well to the therapy. Currently, therapists cannot predict which muscles will respond, limiting their ability to create a personalized therapy plan that can maximize outcomes while making the best use of the limited treatment time available. The objective of this study is to develop a diagnostic method that will allow therapists to quickly and easily screen muscles in the clinic, in order to predict how they will respond to FES-T. Participants with cervical spinal cord injury will receive FES-T through the Rocket Family Upper Extremity Clinic at the Toronto Rehabilitation Institute - University Health Network. Muscles receiving training will undergo a electrophysiological examination before the start of therapy, and will then be tracked for strength recovery over the course of 30 sessions. Lastly, signal processing and machine learning techniques will be applied to the electrophysiological data to predict the recovery profile of each muscle. The significance of this work will be to provide personalized therapy planning in FES-T, leading to more effective use of healthcare resource as well as improved outcomes.
The purposes of the study are to quantify and compare relationships among acute changes in inflammatory markers and evoked pain sensitivity after a high-fat meal (HFM) challenge, compared to a moderate-fat meal challenge, and explore the influence of body composition on these responses, in individuals with chronic spinal cord injury
To examine the effects of Physical Therapist (PT) wound care modalities (pulsed wound irrigation (PWI) + electrical stimulation (ES), PWI only, and ES only) on wound healing in patients with spinal cord injuries (SCI).
Spasticity 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.
The study is a multicenter longitudinal observational study. The therapy content and the therapy dosage of arm/skill training for patients with cervical spinal cord injury (SCI) will be observed for the primary objective. The aim is to get insight into the current therapy content and the current therapy dosage in arm/hand skill training, with the overall aim to optimize the arm/hand skill training. For the secondary objective, in addition to the patients with cervical SCI also, patients with paraplegia as a result of SCI are included. The aim is to assess the difference between the patient's perceived dose and the therapist's estimation of the therapy dose. This will give insight into the patient's and therapist's views on therapy dose; this information will contribute to optimizing therapy dose in exercise therapy in SCI. The third aim is a pilot study to explore the usability of evening reports in SCI rehabilitation.
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 in combination of Spike-timing-dependent plasticity (STDP) stimulation and STDP stimulation with limb training.
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.
The study aims to examine the plausible interventional mechanisms underlying the effects of epidural spinal cord stimulation.