Active clinical trials for "Spinal Cord Injuries"

The proposed study is a pilot study intended to inform the hypothesis that regular walking in an exoskeleton within the home and community might offer health benefit, neurological recovery, and/or mobility benefit to the user. This exploratory pilot study is also intended to assess the level of compliance (i.e., exoskeleton use) among study participants by characterizing extent the device is used beyond the minimum required.

People with cervical spinal cord injury (SCI) and amyotrophic lateral sclerosis (ALS) have reduced connections in the nerve circuits between the brain and the hands. Activating spared nerve circuits is one potential way to improve recovery. The investigators are testing different combinations of physical wrist and hand movements paired with magnetic brain stimulation and electrical spinal cord or nerve stimulation to see the effects on nerve transmission to hand muscles. This is a preliminary study. This study is testing for temporary changes in nerve transmission to hand muscles. There is no expectation of long-term benefit from this study. If temporary changes are seen in this study, then future studies would focus on how to prolong that effect.

Spinal cord neural circuitry exists in the lumbar enlargement that makes it possible to stand and create synergistic, rhythmic stepping activity in the lower limbs. In the past 20 years, clinicians have tried to reengage such these circuits for standing and walking in the lower spinal cord of paralyzed humans through novel paradigms of physical therapy, pharmacological stimulation of the spinal cord, or recently - epidural stimulation of the spinal cord. Although standing and stepping with these maneuvers are rudimentary at best, these human studies offer promise to restore controlled, lower extremity movement to the spinal cord injured (SCI) individual. Evidence from animal data suggests that more focal activation of intraspinal circuitry (IntraSpinal Micro-Stimulation - ISMS) would produce more fatigue resistant, natural standing and stepping activity in humans. To date, there has been no direct confirmation of such circuitry in the spinal cord of bipedal humans who have been paralyzed. Furthermore, mapping of such circuitry would provide the basis of a novel intraspinal neuroprosthetic that should be able to restore control of standing or walking in a manner that is much more physiologically normal and tolerable than by stimulating each individual muscle group. Proof of the existence of these spinal circuits in man, and the ability to activate and control these circuits by first mapping the spinal cord is the basis of this proposal.

The aim of this study is the validation of a novel gait assessment method implemented in the Lokomat gait trainer with respect to established clinical gait assessment methods. The walking assessment method is based on the progressive reduction of the support of the device. The outcome measures of this algorithm will be the support needed in the different gait phases (guidance force of hip and knee joints) and the support required to the body weight support system (unloading). The hypothesis is that the guidance force and the support of the device will converge to a profile individual for each subject that is representative of one's impairment in the different gait phases. The reliability of the method will be tested collecting data from two sessions of Lokomat training. The validity of the method will be tested comparing the outcome of the assessment task with established clinical walking assessment measures.

The main objective is to quantify energy expenditure when using the SmartDrive system during manual wheelchair propulsion in external conditions (slope, straight line). For this two comparisons are performed: Comparison of energy expenditure with and without the use of a system SmartDrive 6 minute propulsion test. Comparison the risk of musculoskeletal disorders of the wrist during a 6 minute propulsion test.

This study seeks to establish the sensitivity and specificity of what appears to be a unique brainstem biomarker of Parkinson's Disease (PD) - an electrically induced olygosynaptic nasotrigeminal reflex response - in differentiating early stage PD from normal controls and from patients with various other neurodegenerative diseases. This study will additionally compare the biomarker to olfactory testing.

In this study, investigators will show proof-of-concept that brain signals can be used in real-time, closed-loop mode to trigger stimulation for hand function. Subjects will undergo surgery to implant a unilateral subdural strip electrode (Resume II, Model 3587A) over the motor cortex. These electrodes implanted in the brain will enable bioelectrical data recording (sensing) from the brain to the implanted Activa PC+S. The cortical sensing data will be either processed in the Activa PC+S; or off-loaded via the Nexus D communication device (Medtronic) to a computer.

Spinal cord injury often results in complete or partial loss of functioning of the upper and or lower limbs, leading to the affected individual experiencing difficulties in performing activities of daily living. This in turn results in reduced participation in social, religious, recreational and economic activities (employment). Globally, there is a low employment rate (11-67%) amongst PLWSCI. In South Africa, according to Statistics South Africa, the unemployment rate of people with disabilities is estimated to be 25.2%. However, there is no information available on employment amongst PLWSCI in South Africa. Furthermore, there is insufficient knowledge related to SCI in South Africa to enable a model to be developed and implemented. Data on the current SCI rehabilitation practices (with specific reference to vocational rehabilitation); employment status and factors (both personal and environmental); barriers and facilitators of employment amongst PLWSCI is limited. This information is needed to develop a return to work model for individuals with SCI in South Africa. In South Africa, a legal framework exists that promotes the employment as well as assistance of people with disabilities in the workplace, such as: the Constitution of Republic of South Africa, 1996; the Employment Equity Act (EEA), 1998; the Promotion of Equality and Prevention of Unfair Discrimination Act (PEPUDA), 2000; Labour Relations Act (LRA), 1995; Skills Development Act (SDA), 1998; Public Service Act (PSA), 1994; Basic Conditions of Employment Act (BCEA), 1997 and the Integrated National Disability Strategy (2000). However, rehabilitation interventions provided in rehabilitation institutions are mainly medical, with limited attempts to prepare those with SCI to return to gainful employment. There is therefore a need for a well-coordinated, multi-sectorial, multi-disciplinary and multi-factorial rehabilitation intervention that will promote the employment of PLWSCI in South Africa.

The aim of this observational, non-controlled, non-profit study is to describe the responses to rehabilitative training with the robotic exoskeleton EKSO-GT in patients with incomplete motor Spinal Cord Injury (AIS C or D). Such rehabilitative tool is employed during inpatient intensive rehabilitation in a 3rd level Italian hospital. Safety and tolerability of the device are also assessed and described.

The specific aim of this study is to evoke functional movement in the hand of both healthy individuals and individuals diagnosed with a stable cervical spinal cord injury with non-functional movement of the fingers. The primary purpose of this study is to determine the feasibility of achieving refined hand movements through electrical stimulation of the muscles within the forearm. It is believed that this study will be able to identify specific stimulation parameters and electrode spatial configurations responsible for various refined hand movements. After an eligible individual agrees to participate in this study, s/he will receive transcutaneous electrical stimulation on the forearm in order to evoke different hand and finger movements. The precision, specificity, and extent of these movements will be visually assessed. In order to better evaluate these movements, participants may also be asked to perform various functional tasks with their hand. The grip strength and evoked forces at the fingertips will also be measured using sensors. There will be up to 4 study sessions each week for up to 8 weeks, with each session lasting up to 4 hours. Upon completion of these study sessions, the individual's participation in the study is considered complete.