View clinical trials related to Spinal Cord Injuries.
Filter by:The purpose of the second part of the study is to examine the effect of reflex training in the leg to decrease neuropathic pain. For this, the researchers are recruiting 15 individuals with neuropathic pain due to spinal cord injury to participate in the reflex training procedure. The study involves approximately 50 visits with a total study duration of about 6.5 months (3 months for baseline and training phases followed by 1 month and 3 month follow-up visits).
Spinal cord injury (SCI) is a devastating disability with physical, social and vocational consequences. Owing to its overwhelming complications, the cost of treatment and rehabilitation increases constantly. Persons with spinal cord injury are always dependent on their families in most of house hold, recreational and activities of daily life. Majority of SCI are incomplete classification C or D as per American spinal injury Association (ASIA). Due to certain spared pathways intrinsic mechanism of neuroplasticity take place in incomplete spinal cord injuries (iSCI) which is liable for natural recovery, but this potential is limited and often slow. Therefore there is need for some advance therapeutic interventions which may enhance neuroplasticity and improve functional recovery in individuals with iSCI. It has been reported that acute intermittent hypoxia (AIH) increase neuro plasticity by causing release of spinal serotonin which stimulate serotonin type 2 (5-HT2) receptors that undergoes a series of mechanisms which increase brain derived neurotrophic factors (BDNF) which subsequently enhance motor functions of upper and lower limbs in iSCI. Despite of the growing body of literatures supporting that AIH improves both upper limb and lower limb functions along with walking ability and speed. However, their results are limited to small sample size, gender biased and lack of intralimbs assessment. As per the author knowledge, these literatures lack retention effects of AIH on upper and lower limb function. In addition variables like quality of life, disability and some biomarkers related to hypoxic effects have not been reported in any of these studies. Furthermore, it is hypothesized that variant geographic locations and socioeconomic status may affects persons with iSCI differently. So in light of these literature gaps, the author aim is to investigate the effects of AIH in upper and lower limb motor function, balance, quality of life and disability. In addition, the effects of AIH on brain derived neurotrophic factors (BDNF), hemoglobin (Hb) level, numbers of RBS and hematocrits will be assessed.
Currently, Enoxaparin is the usual prophylactic anticoagulant treatment at the acute and sub-acute phases of spinal cord injury (SCI). Patients at the sub-acute phase of SCI (rehabilitation) will be given either Enoxaparin 40 mg/day (control) or Apixaban 2.5-5 mg twice a day. Apixaban dose will be determined by the treating physician. Treatment will be continued for either 6 or 12 weeks following injury (for AIS grades C-D and A-B respectively). Endpoints: Venous thromboembolism will be evaluated by D-Dimer test every 2 weeks and an ultrasound doppler at the end of the treatment. Bleeding events will be recorded and hematocrit will be monitored every two weeks.
This research will aid in understanding of slow-breathing and its effect on heart rate and blood pressure in people with a spinal cord injury (SCI). This research will investigate if traditional 'yogic' breathing exercises can be performed by subjects with SCI and its influence on the cardiovascular system.
This randomized clinical trial will compare three groups of individuals with cervical/thoracic, complete or incomplete spinal cord injury (SCI) that will undergo: (i) early CPAP therapy in the management of moderate-to-severe sleep-related breathing disorders (SRBDs) among adults at 6 weeks after SCI; (ii) delayed CPAP therapy in the management of moderate-to-severe SRBDs among adults at 22 weeks after SCI; and (iii) no treatment as they either have mild or no SRBD.
A common problem among children with nervous system disorders is difficulty walking on their own. This has impacts beyond mobility including short and long-term health conditions associated with physical inactivity and different developmental experiences as a result of the mobility impairments. A robotic trainer can both provide rehabilitation and be an assistive device to help compensate for difficulties. Figuring out how to prescribe it is critical to improve daily life for children with significant disabilities. Preliminary use of robotic trainers have shown many benefits, such as better head control and improved independence in transfers, which greatly increases ability to live independently. Additionally, vital functions that are frequently impaired in those with less physical activity, such as sleep and bowel habits, seem to improve. Finally, these children enjoy using them. This project aims to determine who is most likely to benefit from training with a robotic trainer and investigate key details about the dose of training that is needed. Families that are already using or hope to use robotic training need this data to help improve their access to the intervention. Clinicians need this systematic approach to building evidence to ensure a future multi-centre randomized control trial is well designed. This study is needed to help improve the lives of those who live with significant disabilities. The objective is to evaluate the feasibility and impacts of delivering robotic gait training at home. Integral in this study is capturing the user perspectives. This will both provide preliminary evidence-based advice to potential users, their families, and clinicians as well as provide key metrics to design a definitive multi-centre randomized control trial. The investigators will provide robotic gait trainers, specifically Trexo robotic gait trainers, to participants and their families to use in their home communities for 12 weeks to evaluate the feasibility and impacts of intensive robotic gait training in people who cannot walk independently. Assessments will be completed throughout the duration of study, including before, during, and after the training intervention, with the goal of evaluating a wide range of feasibility considerations and impacts from robotic training.
This study will help the investigators better understand the changes in short-term excitability and long-term plasticity of corticospinal, reticulospinal and spinal neural circuits and how the changes impact the improvements of spinal cord stimulation (SCS) mediated motor function.
Male self catherterisng observational study.
VA research has been advancing a high-performance brain-computer interface (BCI) to improve independence for Veterans and others living with tetraplegia or the inability to speak resulting from amyotrophic lateral sclerosis, spinal cord injury or stoke. In this project, the investigators enhance deep learning neural network decoders and multi-state gesture decoding for increased accuracy and reliability and deploy them on a battery-powered mobile BCI device for independent use of computers and touch-enabled mobile devices at home. The accuracy and usability of the mobile iBCI will be evaluated with participants already enrolled separately in the investigational clinical trial of the BrainGate neural interface.
This study will provide nutrition counseling via FaceTime on an iPad to persons with traumatic spinal cord injury (SCI) who are overweight or obese and are at least one-year post-injury. Nutrition counseling may help participants to develop eating behaviors that match the participants' needs and help improve heart health. The purpose of this project is to decrease the risk of complications like obesity, high cholesterol, or diabetes, and explore associations between bowel and bladder function and nutrition. This study will require 3 in person visits that are about 3 months apart. The total length of the study is about 6 months and includes 3 months of telenutrition counseling.