Active clinical trials for "Trauma, Nervous System"

Incomplete spinal cord injuries (SCI) are the most frequent neurologic category, comprising 66.7% of all SCI cases. People with incomplete SCI may retain some ability to move the legs and therefore the capacity to regain walking. Studies that show functional improvement in locomotion via electrical stimulation of lumbosacral circuits suggest that the underlying mechanisms are neuromodulation of lumbosacral spinal cord automaticity and sensory feedback. Both epidural and transcutaneous spinal stimulation are demonstrating exciting potential to improve limb function for people after chronic SCI. Available treatment options for SCI are less than satisfactory and most often do not achieve full restoration of function. Recent experimental results suggest an exciting new approach of using electrical spinal stimulation to enable users to regain control of their weak or paralyzed muscles. Using surgically-implanted electrodes, epidural stimulation results in remarkable improvements of lower extremity function as well as autonomic functions such as bladder function and sexual function. In addition to epidural stimulation, over only the last few years a novel strategy of skin surface electrical spinal stimulation has also demonstrated exciting potential for improving walking function. Using a high-frequency stimulation pulse, current can pass through the skin without discomfort and activate the spinal cord; this results in patterned stepping movements for people without SCI and improved lower extremity function following SCI. This study will directly compare skin-surface transcutaneous stimulation with implanted epidural stimulation for improving lower extremity function.

The study team is currently recruiting volunteers who are interested in participating in a brain-spinal cord-muscle response training study that aims to better understand the changes that take place in the nervous system as a result of this type of training. After spinal cord injury, brain-to-muscle connections are often interrupted. Because these connections are important in movement control, when they are not working well, movements may be disturbed. Researchers have found that people can learn to strengthen these connections through training. Strengthening these connections may be able to improve movement control and recovery after injuries. Research participants will be asked to stand, sit, and walk during the study sessions. Electrodes are placed on the skin over leg muscles for monitoring muscle activity. For examining brain-to-muscle connections, the study team will use transcranial magnetic stimulation. The stimulation is applied over the head and will indirectly stimulate brain cells with little or no discomfort. Participation in this study requires approximately three sessions per week for four months, followed by two to three sessions over another three months. Each session lasts approximately 1 hour.

The purpose of this study is to validate the capacity of a reflex training system to change the size of the targeted reflex. For this, the researchers are recruiting 25 individuals with chronic incomplete SCI who have spasticity in the leg to participate in the reflex training procedure. The study involves approximately 45 visits with a total study duration of about 6 months.

This pilot study will determine the feasibility of implementing a combinatory rehabilitation strategy involving testosterone replacement therapy (TRT) with locomotor training (LT; walking on a treadmill with assistance and overground walking) in men with testosterone deficiency and walking dysfunction after incomplete or complete spinal cord injury. The investigators hypothesize that LT+TRT treatment will improve muscle size and bone mineral density in men with low T and ambulatory dysfunction after incomplete or complete SCI, along with muscle fundtion and walking recovery in men with T low and ambulatory dysfunction ater incomplete SCI.

Vagus nerve stimulation (VNS) activates neural pathways leading to the release of chemicals that promote plasticity and learning. Previous work has shown that the auricular branch of the vagus nerve innervates landmarks on the external ear. Work from the PI's laboratory has shown that electrical current applied to the external ear activates neural pathways implicated in the therapeutic effects of VNS. The broad objective of this project is to better understand physiological mechanisms that are modulated by auricular stimulation and its potential to enhance motor learning.

The goal of this study is to determine if training in both the forward and reverse modes on the ICARE (motor-assisted elliptical) contributes to improvements in gait and cardiorespiratory fitness.

This study is a single blinded prospective randomized monocentric study examining the effectiveness of transcutaneous auricular vagus nerve stimulation paired with rehabilitation and low frequency/antidromic stimulation of the pelvic somatic nerves. The investigator hypothesize that treatment using transcutaneous auricular vagus nerve stimulation will improve gait recovery in spinal cord injured participants already treating by rehabilitation and pelvic nerves neuromodulation.

Neurological disorders [such as Cerebral Vascular Accident (CVA) or Spinal Cord Injury (SCI)] are among the most costly health problems to society in industrialized countries. For those affected, they generate severe restrictions in mobility, significantly altering their quality of life. Deterioration in motor function after stroke or BM is closely linked to the level of force produced at joint level. This is influenced by adaptations (neurological and tissue) inherent to the pathophysiology of the injury, and characterized by the presence of a spastic paresis syndrome. A great deal of effort is devoted to motor neurorehabilitation (particularly physiotherapy) in the days and weeks following neurological injury. This so-called sub-acute rehabilitation phase is designed to have a positive impact on the patient's motor recovery (to prevent the development of spastic paresis), and to prevent future severe limitations in the long term. Disorders observed in the chronic phase (partial recovery of strength, severe orthopedic deformities) demonstrate the limits of current therapies. In view of the results obtained in healthy subjects, eccentric training now seems to be one of the most promising physiotherapy methods for recovering muscle strength and countering neurological disorders. However, its use in the sub-acute rehabilitation phase has never been evaluated in post-stroke or post-BM patients, either in terms of its effects on the strength developed in the strengthened muscles, or more locally on the neurological and tissue disorders found in these patients in the context of spastic paresis. The aim of this project is to evaluate the effects of an eccentric muscle-strengthening exercise protocol on neurological patients in the sub-acute phase of their neurological impairment. The protocol will be applied to the ankle joint, given its importance for walking and the significant deficits found at this level in neurological populations.We hypothesize that the strengthening protocol will improve muscle strength at the ankle, and generate beneficial adaptations to combat the spastic paresis syndrome (improved muscle activation, increased muscle length, muscle volume, etc.).

Postoperative Cognitive Dysfunction(POCD)is a common postoperative complications, existing clinical research focused on the adult patients, ignoring that the developing human brain with underlying neurological impairments may be at higher risk for cognitive impairment, so we need a prospective study, observe this kind of "special groups" in the brain structure and function of before and after general anesthesia, To determine the susceptibility to neurotoxicity of general anesthesia drugs.

This is an early feasibility trial to determine whether transcutaneous neuromuscular electrical stimulation, with or without transcutaneous spinal cord stimulation, using an investigational neurostimulation device improves functional arm/hand movements in individuals with paralysis or paresis due to a spinal cord injury or stroke and improves functional arm/hand or leg/foot movements in individuals with paralysis or paresis due to other brain or nerve injuries. In this study, eligible individuals that agree to participate will be asked to attend up to 5 study sessions a week for 1 year (depending on participant availability), with each session lasting up to 4 hours. At the first study session, participants will have their demographic information collected, vital signs assessed, and have measurements performed of their limbs and torso, as appropriate. They will also undergo clinical evaluations and tests to assess their current functional movement and sensation capabilities. During subsequent study sessions, participants will undergo many tasks designed to improve functional movements in paralyzed limbs. Specifically, participants will receive neuromuscular electrical stimulation to the limb(s) and/or electrical stimulation to the spinal cord to evoke specified movements. The stimulation parameters and locations on the spinal column and/or limb(s) that evoke specific movements will be noted. The movements will be assessed with visual inspection, electromyography, and/or sensors. The clinical evaluations and tests to assess functional movement and sensation capabilities will be repeated throughout the study and at the last study session to assess for functional improvements compared to the first study session. Upon completion of these study sessions, the individual's participation in the study is considered complete.