Active clinical trials for "Spinal Cord Injuries"

People with mobility disabilities are at greater risk than the general population for incurring health problems. Many of these conditions are preventable through behavior and lifestyle changes such as exercise and physical activity. Recent evidence suggests that people with disabilities experience the same physiologic response to exercise as the general population. Nonetheless, nearly three-fourths of those with disabilities report being entirely sedentary or not active enough to achieve health benefits. Despite some knowledge of issues that limit physical activity among this population, few studies have investigated methods for promoting physical activity adoption among people with disabilities, including wheelchair users. The purpose of this study is to test the effectiveness of a behavioral intervention to promote physical activity adoption over 6 months and maintenance of physical activity over another 6 months by community-dwelling manual wheelchair users.

The purpose of this research study is to demonstrate the safety and efficacy of using two NeuroPort Arrays (electrodes) for long-term recording of brain activity.

The project is intended to modify the Functional Independence Measure (FIM) for manual wheelchair users. It will determine if the new measure is a better measure of community independence for manual wheelchair users than the FIM. During the Phase 1 of the study it will then use this new measure to determine whether a home exercise program increases functional independence in wheelchair users. In Phases II and III of the study 120 manual wheelchair users will participate to test and validate the new measure and to test the effectiveness of therapeutic exercise. Subjects will range in age from 20 to 79 yrs. and have a variety of disabilities.

The study is a prospective, open, bicentric and observational study. It is conducted to assess the safety and performance of the Atalante exoskeleton system with patients with lower limb paralysis. The principal objective is to assess the performance of the Atalante system in performing ambulatory functions with motor complete SCI patients characterized by the success rate in performing a 10mWT at the last session of training with the Atalante system.

There exist a variety of outcome measures to asses gait function in individuals with a spinal cord injury (SCI). The most established measures are the 10-meter walk test (10MWT) and the 6-minute walk test (6mWT). They are used to assess treatment efficacy and recovery of gait function in individuals with SCI. However, the 10MWT is appropriate for poor walkers but not sensitive in good walkers and the 6mWT can be time-consuming and is very demanding for severely impaired patients. Therefore the 2-minute walk test (2mWT) has gained more attention in the SCI field. The 2mWT has been established in numerous neurological diseases and has shown to correlate with the 6mWT in patients with neuromuscular disease, multiple sclerosis and stroke. Though the 2mWT has not yet been validated in individuals with SCI. A limitation that affects all timed walking tests is that they suffer from limited information about gait quality (i.e. how walking function is achieved). Being able to receive information on the gait quality of a patient can help to understand the underlying mechanisms of walking improvements after an intervention (e.g. compensation vs recovery). The research in the field of inertia measuring units (IMU) develops and advances very rapidly at the moment resulting in the possibility to perform a gait analysis with a simple IMU setup. However, the reliability of such measurement setups has not yet been shown in individuals with SCI. The primary aim of this study is to test the validity and reliability of the 2mWT in the SCI population. Additionally, it will be investigated if a simple sensor setup can give additional reliable information about the gait pattern of individuals with SCI.

This study examines safety and feasibility of a study protocol using a combination of functional electrical legcycling with voluntary armwork (hybrid training) as either skiergometer or armcycling in high intensity intervals for persons with spinal cord injury paraplegia.

The purpose of this project is to pilot test a decision-making tool that is tailored for women with SCI to support them in the decision-making process. Pilot testing focuses on feasibility and preliminary efficacy.

Immediately following a spinal cord injury (SCI), patients are admitted to inpatient rehabilitation where they undergo physical reconditioning in preparation for a return to home setting. The current standard of practice for aerobic training is performing arm-ergometry for 25 mins at a frequency of three times per week. Given the move towards shortened length of stay during inpatient rehabilitation, performing MICT can consume a considerable amount of therapy time. Sprint interval training (SIT) has been shown to elicit similar improvements in physical capacity, despite a reduced time commitment to MICT. However, there are no controlled trials comparing the effects of SIT to MICT in individuals with SCI undergoing inpatient rehabilitation. The primary aim of this study was to investigate the efficacy of a five-week, thrice weekly 10 min SIT program and compare outcome measures to a traditional 25 minute MICT program on the arm-ergometer in individuals with SCI undergoing inpatient clinical rehabilitation. It was hypothesized that five weeks of SIT and MICT would induce similar changes in maximal and sub-maximal exercise performance, self-efficacy for exercise, and exercise enjoyment, despite large differences in training volume and time commitment. It was also hypothesized that SIT would be well tolerated and elicit higher levels of cardiovascular strain than MICT.

The proposed study is intended to inform the hypotheses that (1) regular dosing of exoskeleton walking will provide health benefits to non-ambulatory and poorly-ambulatory individuals with SCI, including decreased pain and spasticity, improvements in bowel and bladder function, decreased body-mass index (BMI), enhanced well-being; (2) regular dosing of exoskeleton walking will facilitate neurological or functional recovery in some individuals with SCI, particularly those with incomplete injuries; and (3) the level of mobility enabled by a lower limb exoskeleton is commensurate with the walking speeds, distances, and surfaces required for community ambulation.

Skeletal muscle is the largest endocrine organ in the body, playing an indispensable role in glucose homeostasis. Spinal cord injury (SCI) prevents skeletal muscle from carrying out this important function. Dysregulation of glucose metabolism precipitates high rates of metabolic syndrome, diabetes, and other secondary health conditions (SHCs) of SCI. These SHCs exert a negative influence on health-related quality of life (HRQOL). New discoveries support that a low level of activity throughout the day offers a more effective metabolic stimulus than brief, episodic exercise bouts. The proposed study will translate this emerging concept to the population of individuals with SCI by using low-force, long-duration electrical muscle stimulation to subsidize daily activity levels. Recently, we demonstrated that this type of stimulation up-regulates key genes that foster an oxidative, insulin-sensitive phenotype in paralyzed muscle. We will now test whether this type of activity can improve glucose homeostasis and metabolic function in patients with chronic paralysis. We hypothesize that improvements in metabolic function will be accompanied by a reduction in SHCs and a concomitant improvement in self-reported HRQOL. The long-term goal of this research is to develop a rehabilitation strategy to protect the musculoskeletal health, metabolic function, and health-related quality of life of people living with complete SCI.