View clinical trials related to Incomplete Spinal Cord Injury.
Filter by:Robotic therapies aim to improve limb function in individuals with neurological injury. Modulation of robotic assistance in many of these therapies is achieved by measuring the extant volitional strength of limb muscles. However, current sensing techniques, such as electromyography, are often unable to correctly measure the voluntary strength of a targeted muscle. The difficulty is due to their inability to remove ambiguity caused by interference from activities of neighboring muscles. These discrepancies in the measurement can cause the robot to provide inadequate assistance or over-assistance. Improper robotic assistance slows function recovery, and can potentially lead to falls during robot-assisted walking. An ultrasound imaging approach is an alternative voluntary strength detection methodology, which can allow direct visualization and measurement of muscle contraction activities. The aim is to formulate an electromyography-ultrasound imaging-based technique to sense residual voluntary strength in ankle muscles for individuals with neuromuscular disorders. The estimated voluntary strength will be involved in the advanced controller's design of robotic rehabilitative devices, including powered ankle exoskeleton and functional electrical stimulation system. It is hypothesized that the ankle joint voluntary strength will be estimated more accurately by using the proposed electromyography-ultrasound imaging-based technique. And this will help the robotic rehabilitative devices achieve a more adaptive and efficient assistance control, and maximize the ankle joint rehabilitation training benefits.
Neuromuscular electrical stimulation (NMES) remains as one of the effective rehabilitation modalities for addressing recovery of neuromuscular function after a spinal cord injury (SCI). To achieve optimal effects, the NMES interventions that involve or promote voluntary efforts from SCI participants are preferred. However, these interventions are limited by the fact that the active monitoring of voluntary effort, particularly at the stimulated muscle level is unattainable. The objective of the proposed study is to develop SMARTq (Stimulated Muscle Assessment in Real-Time). This novel system will provide a quasi real-time assessment of intrinsic neuromuscular responses of a stimulated muscle during NMES. Specifically, the proposed system will consist of our novel algorithms interfaced with the EMG data acquisition hardware to process the EMG data recorded from a stimulated muscle in real-time during NMES. The term 'quasi' is used to account for the processing delay of approximately 1 to 2 seconds that may potentially occur. The proposed system will be developed and validated using the data collected from the able-bodied (AB) as well as individuals with incomplete SCI (iSCI). The applicability of the system will be evaluated on individuals with complete SCI (cSCI). Our central hypothesis is that the real-time tracking of neuromuscular responses during a train of NMES will provide valuable information on inherent neuromuscular changes, volitional participation, and neuromuscular recovery. The significance of the proposed study is that, if successful, it will deliver a highly novel system which can allow researchers and clinicians to - 1) evaluate the direct electrophysiological effects of varied combination of NMES on a stimulated muscle in real-time; 2) quantify, track and manipulate the levels of voluntary efforts or volitional drive 'on-fly' during NMES for extracting optimal benefits; 3) track the neuromuscular recovery of the stimulated muscle, particularly for cSCI populations, when any functional changes have not been observed yet; and 4) directly observe the neuromuscular fatigue derived from the electrophysiological data at the stimulated muscle. These are highly significant opportunities that can allow the clinicians and researchers to transform the current as well as future NMES interventions into highly effective training modalities as each intervention will be operated at an individual's neuromuscular level.
Previous studies have shown that the neuroplasticity of the residual corticospinal fibers, the motor cortex and the spinal neurons plays an important role in the spontaneous functional recovery of people with neurological or musculoskeletal pathology. However, it is also possible to stimulate the neuroplasticity mechanisms of these structures through techniques aimed at rehabilitating different deficits (for example, motor function or sensitivity). In general, intervention programs are usually carried out, in most cases, using low-cost strategies such as therapeutic physical exercise programs. The objective of this study is to analyze the effectiveness of visual illusion therapies in combination with conventional exercises on the symptoms and signs related to incomplete spinal cord injury that affects the upper limb. The study will include the realization of three measurements that will be carried out one day before starting the program, one day after finishing it, and one month later (follow-up). The clinical assessment will be composed of the study of the following variables: Motor function and motor skills, Upper limb isometric force, Muscle activation, Muscle tone, Quality of life, Functionality. All interventions will last eight weeks and will be planned according to the availability of volunteers. In each session, it will be recorded if any type of adverse effect occurs. There will be four types of interventions: i. Visual Illusion (IV) and therapeutic exercise program (PE), ii.placebo and PE, iii. IV, iv. IV placebo.
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).
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
After incomplete spinal cord injury (iSCI), many people still have control over their upper and/or lower limbs, but secondary conditions such as spasticity impair the function they have left. Spasticity includes increased reflex response and muscle tone, and is often painful. In this study we want to test a rehabilitation therapy to reduce spasticity after iSCI and improve participants' control over their extremities. The study involves recording participants' brain signals (EEG) and displaying them on a computer, so that they learn to control specific features derived from their brain waves. This is called neurofeedback (NF). Two studies conducted in our group that explored NF effect on central neuropathic pain in iSCI reported as incidental finding a decrease in spasms, muscle tightness and foot drop. The effect of NF is immediate and lasts up to 24 hours. In this study, we will explore systematically the short- and medium-term effect of NF on a larger number of iSCI, to inform a potential randomized clinical trial. Gaining control over one's brain activity requires practice and 80-90% people eventually learn the skill. Each participant will therefore attend five sessions of NF taking no longer than two hours each. 20 participants will be recruited and assigned to either upper or lower limb spasticity groups. This will allow us to determine if the mechanism of NF differs between arms and legs. Participants will be further grouped into sub-acute and chronic groups, depending on the time since injury, to pinpoint at what stage post-injury NF is the most effective. All groups will receive the same number of NF sessions. The primary outcome of this study is the change in spasticity of the hand or leg, as measured by the Modified Ashworth Scale (MAS). Secondary outcomes include use of arm/leg, quality of life, and the relation between functional improvement and EEG changes. Outcomes will be compared before/after each session, and before/after the whole intervention period, both inter- and intra-group.
Roughly 60% of people with Spinal Cord Injury (SCI) have an incomplete one, with a strength, sensibility, and muscle tone alteration. Moreover, this condition involves a high impact on the psychological and socioeconomic levels. After an incomplete SCI, spontaneous functional recovery occurs. This recovery is strong associated with injury and person characteristics, and with corticospinal fibers, motor cortex, and spinal neurons neuroplasticity. However, also it is possible to stimulate neuroplasticity mechanisms of these structures throughout rehabilitation techniques. Generally, with external devices, exoskeletons, or physical exercise therapy. With it, clinicians achieve early, intensive and specific therapies. This reorganization and recovery can be influenced because of mirror neurons, located in motor and premotor areas, and in other cortical and subcortical areas. These types of neurons are activated with a functional action observation. Due to incomplete SCI neuroplasticity recover, these therapies (concretely, illusion visual systems) have been the object of systematic review in this population with the aim of knowing its repercussion on neuropathic pain in chronic patients. Moseley and collaborators in 2007 were the first of proposing a virtual gat system that induced patients' gait illusion. The promising results in this intervention, leading institutions performed similar studies with other stimuli and devices, with good results. However, SCI studies are focused on neuropathic pain and not in motor function (like in other populations). Therefore, there is not any study that assesses mirror neurons activity in the physical condition and/or in functional gait capaity in incomplete spinal cord injury population. On the basis of the above, the study principal aim is to evaluate a virtual gait treatment effectiveness compared with combined interventions with specific gait physical exercise in functional capacity in the incomplete spinal cord injury population. Concretely in follow outcomes: gait, functionality, strength, muscle tone, sensibility, and neuropathic pain.
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.
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.
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.