Active clinical trials for "Spinal Cord Injuries"

The purpose of this study is to analyze the safety and efficacy of autologous bone marrow mesenchymal stem cell transplantation in patients with cervical chronic and complete spinal cord injury.

The purpose of this study is to analyze the safety and efficacy of autologous bone marrow mesenchymal stem cell transplantation in patients with thoracolumbar chronic and complete spinal cord injury.

This study aim to evaluate the safety and efficacy of intrathecal transplantation of allogeneic umbilical cord derived mesenchymal stem cells (UC-MSC) for treatment of different phrases of spinal cord injury. Here, the history of spinal cord injury is divided into three periods, Sub-acute SCI, Early stage of chronic SCI, and Late stage of chronic SCI, which is 2W-2M, 2M-12M, and more than 12M after injury, respectively. The purpose is to investigate whether the patients with spinal cord injury benefit from UC-MSC transplantation, and then find out the best time for SCI treatment. In this part of the study, the investigators will treat patients with late stage of chronic spinal cord injury with UC-MSC transplantation or placebo.

In Taiwan, there are more than 23,000 individuals with spinal cord injuries (SCI, mean age: 27 years), with an increment of new 1,200 SCI individuals each year. Recovery of ambulatory function is among the most important therapeutic goals because 92% of the individuals with SCI have to use the wheelchair for the rest of their lives. The lower limb powered exoskeleton robot, FREE Walk, used for training in this research was developed by FREE Bionics Inc. The main purpose of this research is to test the safety and feasibility of FREE Walk exoskeleton robot. In addition, the research will further investigate the range of injury levels for the intended SCI users and the learning time needed for the users to independently operate the exoskeleton robot.

Bowel care (BC) is a time-consuming and cumbersome activity of daily living for most individuals with SCI. Previous studies have reported that the average time to complete a BC routine is 45 minutes; 10-20% of SCI individuals report BC routines lasting for more than 1 hour. In past studies, the investigators have shown that a medication called neostigmine can increase bowel activity and thus, promote bowel movement. The investigators have successfully used this medication with traditional and novel methods of colonoscopic preparations, and have shown that it improves the quality of these preparations. In this study, we would like to test the applicability of this medication to bowel care routines. The investigators believe that the addition of this medication to the beginning of regular bowel regiments will significantly decrease the time and effort needed to complete BC, thus improving patient perception of their BC routines and quality of life. SCI individuals followed by the James J Peters VA Medical Center (JJPVAMC) SCI Medical Service are admitted on a routine basis for inpatient respite care, therapy, and/or annual physicals. Such inpatient stays typically range in duration from 1 week to 3 weeks, during which the patient undergo BC routines assisted by the inpatient care team. BC routines are typically performed every other day, or thrice weekly (Monday, Wednesday, Friday) in "Blue Rooms" located on the inpatient SCI wards (IE and ID). The bowel care routine, including duration of procedure, use of assistive medications or devices, and completeness of bowel care are documented in the patients' electronic medical chart (CPRS) by care providers. The investigators propose to perform the described protocol in individuals who have been admitted to the hospital for routine care and are otherwise healthy. In doing so, the investigators can ensure that patients are vigilantly monitored during each BC session, and that any changes in BC pattern are accurately observed and documented. Furthermore, by performing these procedures on an inpatient basis, study investigators can ensure the consistency of care and daily routine, allowing for better control of study conditions.

Dyspnea is "a subjective experience of breathing discomfort that consists of qualitatively distinct sensations that vary in intensity". It is known that sensory information from the respiratory system activates regions of the cerebral cortex to produce the perception of dyspnea but far less is known about the neurophysiology of dyspnea than about vision, hearing, or even pain. Dyspnea likely arises from multiple nervous system sources, but the exact locations have not been well identified. Investigations of the mechanisms underlying respiratory sensations have included studies of airway anesthesia, chest wall strapping, exercise, heart-lung transplantation, hyperventilation, and opioid use. Study of the perception of breathing sensations in individuals with a spinal cord injury presents additional opportunity. The goal of the proposed project is to examine the effects of increasingly severe levels of spinal cord injury on the perception of breathing sensations in participants who are able to breathe without the use of a ventilator. The investigators hypothesize that the perception of breathing varies with the extent of somatosensory information that reaches cerebral cortex.

The purpose of this study is to assess the safety and efficacy of NeuroRegen scaffold with bone marrow mononuclear cells (BMMCs) or mesenchymal stem cells (MSCs) in patients with chronic spinal cord injury.

Ambulation would bring many physiological and psychological benefits and getting up and walking has been a dream for paraplegia patients.The reciprocating gait orthoses (RGOs) for paraplegics particularly draws research attentions because it mimics human gait pattern.But, the high energy consumption and low walking speeds caused the frequent abandonment or the low utilization of the reciprocating gait orthoses.To improve the design reducing the energy expenditure, it requires biomechanical analysis of the pathological gait such that the gait deviations and energy consuming mechanisms can be identified and remedial means can be implemented. The investigators hypotheses will include that there would exist an energy saving mechanism of human reciprocating locomotion based on the principle of conservation of mechanical energy.Secondly, kinematic and kinetic gait determinants could be derived from the energy saving mechanism. Finally, the control of knee joint coordinating with the hip joint movements would facilitate the gait progression and further reduce the energy consumption. The objective of this clinical trial is to evaluate the gait of paraplegic patients with reciprocating gait orthoses and to support the investigators research in biomechanical analysis, design and control of reciprocating gait orthoses for paraplegia patients. An experiment to study the pathological gait of paraplegia patients with an existing reciprocating gait orthosis will be carried out.

The primary goal of the proposed clinical trial is to investigate the combined effects of walking training and monoaminergic agents (SSRIs and TIZ) on motor function of individuals in sub-acute (2-7 mo) human motor incomplete Spinal Cord Injury (SCI), with a primary emphasis on improvement in locomotor capability. We hypothesize that the use of these drugs applied early following SCI may facilitate independent stepping ability, and its combination with intensive stepping training will result in improved locomotor recovery following incomplete SCI. Loss of descending control via norepinephrine inputs following spinal cord injury can impair normal sensorimotor function through depressing motor excitability and impairing walking capacity. Replacing these inputs with drugs can alter the excitability and assist with reorganization of locomotor circuits. Assessment of single-dose administration of these agents has been tested in patients with motor incomplete spinal cord injury; only limited changes in walking performance have been noted. The resultant onset of weakness and increase in involuntary reflexes following motor incomplete SCI may partly be a result of damage to descending pathways to the spinal cord that control the release of serotonin. In models of SCI, for example, application of agents that simulate serotonin has been shown to change voluntary motor behaviors, including improvement of walking recovery. In humans following neurological injury, the effects of 5HT agents are unclear. Few previous reports indicate improved motor function following administration of agents which enhance the available serotonin in the brain, although some data suggests that increased serotonin may be beneficial. In this application, we propose to study the effects of clinically used agents that increase or decrease intrinsic serotonin activity in the brain on strength and walking ability following human motor incomplete SCI. Using detailed electrophysiological recordings, and biomechanical and behavioral measures, we will determine the effects of single or chronic doses of these drugs on voluntary and involuntary motor behaviors during clinical measures and walking measures. The novelty of this proposed research is the expectation that agents that increase serotonin activity may increase abnormal reflexes in SCI, but simultaneously help to facilitate motor and walking recovery. Despite potential improvements in voluntary function, the use of pharmacological agents that may enhance spastic motor behaviors following SCI is in marked contrast to the way in which drugs are typically used in the clinical setting.

Following injury to the spinal cord, the spinal circuit undergoes a series of adaptations. In parallel with the spinal circuit adaptation, the muscular properties also adapt. In human and animal studies, histochemical and physiological evidences showed that the paralyzed muscle transferred from slow, fatigue-resistant to fast, fatigable after injury. Reversal of neuromuscular property for persons with SCI needs to be resolved. Studies using high load electrical stimulations showed a reverse change of muscular properties, such as hypertrophy and reversal of fiber type transformations but failed to show a reversal of spinal circuitry function. Previous studies found that fast continuous passive motion (CPM) altered the H reflex excitability in human. Animal studies found that passive cycling and passive stretching delayed atrophy and influenced the transition of type I and IIa MHC. Theses findings lead to a hypothesis that mechanical stimulation might be able to reverse both spinal circuitry and muscular properties after SCI but it has not been confirmed in human study. The purpose of this project is to investigate the effect of mechanical stimulation by fast CPM on the reversing adaptation of human paralyzed muscle after SCI.