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NCT07645144
Spinal cord injuries (SCI) impair neural communication, leading to difficulties in walking due to muscle weakness, altered reflexes, and impaired muscle activation below the injury. Functional electrical stimulation (FES) has been shown to enhance voluntary control, strength, and walking performance when used during gait training. This study aims to assess whether the FES yields superior improvements in walking ability compared to conventional gait training without stimulation.
NCT07641101
This is a single-blind randomized controlled trial for patients with neurogenic bladder after incomplete spinal cord injury. Participants are randomly divided into two groups. The control group receives routine transitional nursing and telephone follow-up, while the intervention group gets 4-week app-supported transitional care including health education, bladder recording and online consultation. After intervention, bladder residual urine, urinary tract infection rate, self-care ability and quality of life are compared between two groups.
NCT04340063
Spinal cord injury (SCI) affects \~42,000 Veterans. The VA provides the single largest network of SCI care in the nation. The lifetime financial burden of SCI can exceed $3 million. A major cost of SCI is impaired mobility. Limited mobility contributes to decreased ability to work, increased care requirements, secondary injury, depression, bone mineral density loss, diabetes, and decreased cardiovascular health. Among ambulatory individuals with iSCI, residual balance deficits are common and are strongly correlated with both functional walking ability and participation in walking activities. The development of effective rehabilitation tools to improve dynamic balance would substantially improve quality of life for Veterans living with iSCI. Improving mobility through interventions that enhance dynamic balance would positively impact health, independence, and the ability to integrate into social, intellectual, and occupational environments.
NCT06214546
Body weight support systems are commonly used for gait training. A new breed of devices for gait training are soft exosuits. To optimize rehabilitation outcomes, it is important to gain deeper insight in the effect of these support systems on gait. The aim of this study is to investigate the effect of a body weight support system and soft exosuit on dynamic balance and knee and hip kinematics during gait in people with incomplete spinal cord injury.
NCT04977037
This study evaluates a remotely supervised, home-based therapeutic program to improve upper-limb voluntary movement in adults with tetraplegia caused by incomplete spinal cord injury (iSCI).
NCT05975606
This project is randomized controlled trial which will explore the effect of pairing repetitive Transcranial Magnetic Stimulation (rTMS) with Functional Electrical Stimulation (FES) Cycling on lower extremity function in people with incomplete spinal cord injury and compare the effects to each one of these interventions alone.
NCT06906536
The goal of this study is to clarify mechanisms of acute intermittent hypoxia and to examine the effect on lower limb function in persons with chronic, incomplete spinal cord injury.
NCT06552507
Overall Objective: To assess whether incorporating duraplasty alongside bony decompression enhances motor function outcomes in individuals following Traumatic Spinal Cord Injury (TSCI). Rationale for Research: In a systematic review, individuals suffering from cervical Traumatic Spinal Cord Injuries (TSCIs) identified specific priorities for improvement in their quality of life. These priorities encompassed enhanced arm and hand function, improved bladder and bowel control, sexual function, and the nurturing of personal relationships with their families and friends. In this context, the investigators posit that augmenting standard treatment with expansion duraplasty has the potential to address several critical aspects of TSCI. Our hypothesis centers on the idea that the incorporation of duraplasty into the treatment regimen can lead to a reduction in spinal cord compression, an enhancement in Spinal Cord Perfusion Pressure (SCPP), an amelioration in spinal cord metabolism, and a mitigation of inflammation at the injury site. The investigatorsanticipate that these physiological and metabolic enhancements will contribute to increased neuronal survival, ultimately resulting in improved motor outcomes. These improved motor outcomes, in turn, are expected to translate into enhanced limb function, superior bladder and bowel control, and an overall improvement in the quality of life for the patients. Our investigative focus encompasses a comprehensive examination of the impact of duraplasty on various facets of spinal cord physiology, metabolism, inflammation, motor and sensory performance, and Health-Related Quality of Life (HRQoL) measures. These HRQoL measures encompass aspects such as hand function, ambulation, bladder and bowel function, as well as the mental, emotional, and social well-being of the patients. In the north area of R.O.C, individuals with TSCI are initially admitted to Linkou Chang Guan Memorial Hospital, where they typically undergo surgery involving spinal instrumentation (e.g., screws and rods) to address deformities and instability. Bony decompression, typically carried out through laminectomy, is a common surgical intervention aimed at addressing the adverse effects of bony compression on the spinal cord. It is worth noting that a significant majority of surgeons (ranging from 85% to 96%) advocate for bony decompression as a primary treatment for TSCI, as recommended by the National Institute for Health and Care Excellence (NICE) guidelines in 2016. However, the effectiveness of bony decompression in improving outcomes following TSCI remains a topic of debate and uncertainty, largely due to the absence of robust evidence from randomized controlled trials (RCTs). Our proposal suggests that bony decompression in isolation may offer only partial relief to the swollen and injured spinal cord, which continues to experience compression against the dura. This may explain the persisting uncertainty surrounding the benefits of bony decompression in TSCI treatment. Achieving adequate cord decompression through surgical intervention assumes particular importance in this context, given the lack of pharmaceutical treatments proven to enhance outcomes in individuals with acute and severe TSCI. While the administration of methylprednisolone initially showed promise, subsequent trials, observational studies, and meta-analyses have cast doubt on its efficacy and raised concerns about potential harm. The management of TSCI in the R.O.C is characterized by considerable variation among major trauma centers, encompassing diverse practices related to factors such as target blood pressure, choice of anesthetic agents, extent of monitoring (including the use of arterial and central lines), and timing of surgery. To circumvent these controversies and differences in practice, the "The outcome of Injured cervical Spinal Cord with Uncontrolled Swelling under Duraplasty" trial has been meticulously designed in a single major trauma center to allow participating surgeon can follow the same protocol about time to surgery and medically management. The "The outcome of Injured cervical Spinal Cord with Uncontrolled Swelling under Duraplasty" trial was conceived with the aim of addressing these critical questions surrounding TSCI management, ultimately seeking to improve the outcomes and quality of life for individuals grappling with this challenging condition.
NCT06079138
This study aims to explore the effect of trans cranial direct current stimulation (tDCS) combined with self-exercise at home for 1 month training (3 sessions/week, for 4 weeks). The outcome assessment including motor function, functional activity, spasticity through neurological assessment (H reflex latency and H/M amplitude ratio) and quality of life will be assessed before, after the intervention and at 1- month follow-up. Participant will communicate with physical therapist via video online platform for every sessions (12 sessions).
NCT04102826
Functional electrical stimulation (FES) has been used to activate paralysed muscles and restore movement after spinal cord injury and stroke. This technology involves the application of low-level electrical currents to the nerves and muscles to cause muscle contraction where the user's ability to achieve that through voluntary means has been lost. Providing control of muscle contraction in a coordinated way can mean that users are able once again to produce functional movements in otherwise paralysed limbs. Routine clinical use is limited to the prevention of drop foot in the lower limb following stroke and occasional therapeutic use in the hand and shoulder. Systems providing functional reach and grasp, however, have not achieved clinical or commercial success. This project aims to develop methods for personalising assistive technology to restore arm function in people with high-level spinal cord injury. The investigators will use a combination of electrical stimulation to elicit forces in muscles no longer under voluntary control, and mobile arm supports to compensate for insufficient muscle force where necessary. The investigators will use computational models specific to an individual's functional limitations to produce patient-specific interventions. The project will be in three phases: building a model to predict the effects of electrical stimulation on a paralysed arm with arm support, development of methodologies using this model to optimise the arm support and stimulation system, and testing of stimulation controllers designed using this approach.
NCT04568928
After partial spinal cord injury, gait deficits may be present and often remain even after intensive rehabilitation. New robotic technologies have recently emerged to help augment the extent of rehabilitation. However, these are complex tools to integrate into clinical practice and little is known about the potential factors that may influence the uptake of a locomotor program using this technology by clinicians. The goal of this project is to bring together researchers, administrators, clinicians and patients to define and implement an overground robotized gait training program in clinic. We will also investigate the added value of leg and trunk muscle stimulation combined with robotic walking training, to see if it could enhance recovery.
NCT04910412
This study aim to investigate the effects of anodal transcranial direct current stimulation combined with gait training for 5 consecutive session on gait performance, balance, sit to stand performance and quality of life in persons with incomplete SCI at post intervention, 1-month follow-up and 2-month follow up
NCT03548649
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.
NCT00610974
The research proposed here will determine the effect of a novel treadmill gait training strategy using a robotic gait trainer (the Lokomat) on functional ambulation in people with SCI. The effect of the new therapy will be evaluated by analyzing changes in functional ambulation and gait patterns during walking.