249 Clinical Trials for Various Conditions
The purpose of our study is to evaluate vibrotactile Coordinated Reset (vCR) and its effects on spasticity symptoms in incomplete spinal cord injured patients. vCR will be administered with a device called the Stanford CR Glove. vCR is expected to provide patients with a non-invasive alternative to the most widely used treatments such as oral baclofen and or deep brain stimulation. Patients will be followed for three months and will be asked to come to the lab for clinical testing 4 times during this period. A total of 30 patients will be included in the study.
A scientific study is being done to test a special treatment for people who have spasticity or tight muscles. This treatment is called "stereotactic radiosurgery dorsal rhizotomy." It uses very accurate beams of radiation to target certain nerves in the back to help loosen up the muscles. In this study, people are put into two groups by chance: one group gets the real treatment, and the other group gets a "fake" treatment that doesn't do anything. This fake treatment is called a "sham." Doing this helps make sure the study is fair and the results are true. After the people in the study get their treatment, the researchers will watch and see how they do. They will check if their muscles are less stiff and if they have any side effects. By looking at the results from both groups, the researchers can find out if the special treatment really helps people with spasticity. Patients who got the "fake" treatment will be eligible to receive the "real" treatment after 6 months.
The goal of this clinical trial is to evaluate the safety and efficacy of nabiximols, a cannabinoid spray, for the treatment of moderate to severe spasticity in adult patients with AQP4-IgG positive and antibody-negative NMOSD. The main question it aims to answer is whether treatment with nabiximols improves patient-reported spasticity ratings compared to treatment with a placebo. This trial will also answer whether nabiximols impact pain, spasm frequency, mood, walking ability, and sleep. Participants will be mailed the treatments and placebo treatments, and will be asked to complete study visits and questionnaires remotely. There is also an optional sub-study that involves in-person visits with ultrasound imaging and in-person neurologic exams.
Individuals with spinal cord injury (SCI) often suffer from pain and spasticity. Traditional treatments for both of these conditions have been medications. However, it has been suggested that the counterstrain osteopathic manual manipulation treatment can decrease pain and possibly spasticity. The aim of this study is to investigate the effects of counterstrain osteopathic manual manipulation treatment on pain and spasticity in individuals with SCI.
The participants of this study will have AUL spasticity and have a need for botulinum toxin type A injections. AUL spasticity is where people develop tightening or stiffness of the muscles in the arms. Botulinum toxin type A is used for the treatment of spasticity in addition to physiotherapy. This study will ask participants to describe their experience living with AUL spasticity. This information will be used to assess the Arm Activity Measure (ArmA). ArmA is a scale designed to assess upper limb function in people with AUL spasticity. This study could suggest changes to the ArmA to improve its suitability for people with AUL spasticity or even the development of a new scale.
Spasticity develops months after spinal cord injury (SCI) and persists over time. It presents as a mixture of tonic features, namely increased muscle tone (hypertonia) and phasic features, such as hyperactive reflexes (hyperreflexia), clonus, and involuntary muscle contractions (spasms). Spasticity is often disabling because it interferes with hygiene, transfers, and locomotion and can disturb sleep and cause pain. For these reasons, most individuals seek treatments for spasticity after SCI. New developments in electrical neuromodulation with transcutaneous spinal stimulation (TSS) show promising results in managing spasticity non-pharmacologically. The underlying principle of TSS interventions is that the afferent input generated by posterior root stimulation modifies the excitability of the lumbosacral network to suppress pathophysiologic spinal motor output contributing to distinctive features of spasticity. However, the previous TSS studies used almost identical protocols in terms of stimulation frequency and intensity despite the great flexibility offered by this treatment strategy and the favorable results with the epidural stimulation at higher frequencies. Therefore, the proposed study takes a new direction to systematically investigate the standalone and comparative efficacy of four TSS interventions, including those used in previous studies. Our central hypothesis is that electrical neuromodulation with the selected TSS protocols (frequency: 50/100 Hz; intensity: 0.45 or 0.9 times the sub-motor threshold) can reduce and distinctly modify tonic and phasic components of spasticity on short- and long-term basis. We will test our hypothesis using a prospective, experimental, cross-over, assessor-masked study design in 12 individuals with chronic SCI (more than 1-year post-injury). Aim 1. Determine the time course of changes and immediate after-effects of each TSS protocol on tonic and phasic spasticity. The results will reveal the evolution of changes in spasticity during 30-min of TSS and the most effective protocol for producing immediate aftereffects. Aim 2. Determine the effect of TSS on spasticity after a trial of home-based therapy with each protocol. The participants will administer 30 min of TSS daily for six days with each of the four TSS protocols selected randomly. This aim will reveal the long-term carry-over effects of TSS intervention on various components of spasticity after SCI. Aim 3. Determine the participants' experience with TSS as a home-based therapy through focus group meetings. We will conduct focus group meetings after participants finish the home-based therapy trial. Accomplishing this specific aim will provide a valuable perspective on the value, challenges, and acceptability of TSS as a home-based intervention. The study addresses important questions for advancing scientific knowledge and clinical management of spasticity after SCI. Specifically, it will examine the efficacy of TSS frequencies and intensities on tonic and phasic spasticity. The study results will be relevant for a high proportion of individuals living with SCI that could benefit from this novel and low-cost non-pharmacological approach to managing spasticity after SCI.
People with spinal cord injury (SCI) experience a host of secondary complications that can impact their quality of life and functional independence. One of the more prevalent complications is spasticity, which occurs in response to spinal cord damage and the resulting disruption of motor pathways. Common symptoms include spasms and stiffness, and can occur more than once per hour in many people with SCI. Spasticity can have a negative impact over many quality of life domains, including loss of functional independence, activity limitations, and even employment. Its impact on health domains is also pronounced, with many people who have spasticity reporting mood disorders, depression, pain, sleep disturbances, and contractures. Spasticity can interfere with post-injury rehabilitation and lead to hospitalization. There are many treatments for spasticity in this population. However, many do not have long-term efficacy, and, if they do, they are often pharmacological in nature and carry side effects that could limit function or affect health. The goal of this pilot, randomized-controlled study is to investigate the potential efficacy and safety of a non-invasive treatment with a low side effect profile, extracorporeal shockwave therapy (ESWT). ESWT has shown some benefits in people with post-stroke spasticity with no long term side effects. Thirty individuals with chronic, traumatic SCI will be recruited. Fifteen will be provided with ESWT while the other fifteen will be given a sham treatment. Clinical and self-report measures of spasticity and its impact on quality of life will be collected, as well as quantitative ultrasound measures of muscle architecture and stiffness. The ultimate goal of this pilot project is to collect the data necessary to apply for a larger randomized-controlled trial. Conducting a larger trial will allow for a more powerful estimation of safety and efficacy of ESWT as a treatment for spasticity in people with SCI.
For many people with spinal cord injury (SCI), the goal of walking is a high priority. There are many approaches available to restore walking function after SCI; however, these approaches often involve extensive rehabilitation training and access to facilities, qualified staff, and advanced technology that make practicing walking at home difficult. For this reason, developing training approaches that could be easily performed in the home would be of great value. In addition, non-invasive spinal stimulation has the potential to increase the effectiveness of communication between the brain and spinal cord. Combining motor skill training (MST) with transcutaneous spinal stimulation (TSS) may further enhance the restoration of function in persons with SCI. Therefore, the purpose of this study is to determine if moderate-intensity, MST can improve walking-related outcomes among persons with SCI and to determine if the addition of non-invasive TSS will result in greater improvements in function compared to training alone.
The purpose of the HSP Sequencing Initiative is to better understand the role of genetics in hereditary spastic paraplegia (HSP) and related disorders. The HSPs are a group of more than 80 inherited neurological diseases that share the common feature of progressive spasticity. Collectively, the HSPs present the most common cause of inherited spasticity and associated disability, with a combined prevalence of 2-5 cases per 100,000 individuals worldwide. In childhood-onset forms, initial symptoms are often non-specific and many children may not receive a diagnosis until progressive features are recognized, often leading to a significant diagnostic delay. Genetic testing in children with spastic paraplegia is not yet standard practice. In this study, the investigators hope to identify genetic factors related to HSP. By identifying different genetic factors, the investigators hope that over time we can develop better treatments for sub-categories of HSP based on cause.
The researchers have developed games controlled by electromyographic (EMG) and inertial measurement unit (IMU) activity recorded by a sensor. These will provide biofeedback to participants post-stroke about the activity of their paretic muscles. The researchers anticipate that providing visual biofeedback will allow subjects to observe the level of co-activation in an agonist-antagonist muscle pair, and therefore initiate interventions to reduce their level of co-activation. Similarly, the researchers will provide additional haptic feedback using an assistive robot at the ankle joint (i.e., M1) and compare the results with the pure visual feedback condition. At the end, the main objective is to compare 1) conventional robotic continuous passive movement (CPM) training to 2) training with visual biofeedback and 3) training with both visual and haptic biofeedback.
This study will be conducted to evaluate the effect of multiple doses of nabiximols compared with placebo on a clinical measure of velocity-dependent muscle tone in the lower limbs (Lower Limb Muscle Tone-6 \[LLMT-6\]) in participants with multiple sclerosis (MS). LLMT-6 is defined as the average of the 6 individual Modified Ashworth Scale (MAS)-transformed scores of knee flexors, knee extensors, and plantar flexors on both sides of the body.
In an individual with MS the central nervous system (CNS) is over-protective and causes the threshold for stretch reflex and muscle tightness to be set lower than normal. This inhibits normal movement and causes abnormalities in posture, stiffness and at times joint contractures. In this pilot study we hope to assess the ability for the direct current of Neubie, which creates mechanoreceptor inputs and lengthening at the sarcomere level of muscle and joints in the spine and lower extremity, to alter the proprioceptive peripheral nervous system (PNS) at muscle spindle and GTO level with a change in CNS over-guarding during the treatment and after the treatment. If the investigators are able to create normalized stretch and muscle tension at the PNS level, it may be possible to create temporary or sustained CNS level changes. This would allow the amount of stretch and tension at the PNS level to be normalized and possibly reduce spasticity. If this theory is accurate, the investigators may be able to increase access to normalized movement, strength and functional ability in individuals with neuro-compromise.
This is a multi-center, randomized, double-blind (patient and evaluator), sham-controlled study to be conducted in stroke patients with upper-extremity spasticity. The main objectives of this study are to evaluate the performance and safety of the MyoRegulator® device in active- versus sham-treated patients after 5 consecutive days of treatment. The MyoRegulator® device is a non-significant risk (NSR) investigational non-invasive neuromodulation device that uses multi-site direct current (multi-site DCS) stimulation for the treatment of muscle spasticity.
The study team is recruiting 20 adults with spasticity due to chronic stroke and 20 adults with no neurological injuries for a 2 day study. In people with chronic stroke, one of the most common and disabling problems is spasticity (increased muscle tone or muscle stiffness). The purpose of this research study is to examine effects of dry needling on the nervous system (pathways between the muscle, spinal cord, and brain) in people with spasticity due to chronic stroke. Dry needling is a procedure in which a thin, stainless steel needle is inserted into your skin to produce a muscle twitch response. It is intended to release a knot in your muscle and relieve pain. The total study duration is 2 days. The first visit will take about 3 hours, during which dry needling will take place, and the second visit will take about 1 hour. During both visits you will be asked to participate in examinations of reflexes (muscle responses to non-invasive nerve stimulation) and arm/leg function.
Spasticity is muscle spasms, bouncing (clonus) or stiffness that can negatively impact the quality of life of people with spinal cord injury (SCI). In people with spinal cord injury, spasticity can limit muscle control of the arms and hands and cause pain, discomfort, and frustration. Transcutaneous electrical stimulation has been shown to reduce spasticity after SCI. However, this type of stimulation's effects during prolonged, at-home use has not been well studied. Additionally, traditional stimulation techniques are often only available in the clinic. Therefore, this study aims to identify if wearable intensive nerve stimulation decreases spasticity in the legs of people with SCI, and if this intervention is usable and desirable to individuals with SCI.
This research project is being conducted to investigate changes in secondary impairments, functional mobility skills, and gait variables in children with spasticity following selective percutaneous myofascial lengthening. The research project proposed here will be the first to use instrumented three-dimensional motion analysis to investigate the effects of selective percutaneous myofascial lengthening on gait kinematics and kinetics. The objectives of the study are to: 1. Compare gait kinematics and kinetics in children and young adults with lower extremity spasticity before and after selective percutaneous myofascial lengthening to determine the effects of this procedure on functional mobility. 2. Identify changes in impairments and activity limitations following selective percutaneous myofascial lengthening . 3. Identify changes in a family or caregivers perceived quality of life after their child's selective percutaneous myofascial lengthening . The aim of this study is to identify and describe the specific changes in secondary musculoskeletal impairments, activity limitations, and gait kinematics and kinetics after a selective percutaneous myofascial lengthening procedure. Gait kinematics and kinetics includes the motion of joints and body segments, and force and power, at each lower extremity joint, respectively. The results of this study will provide preliminary information on how this form of soft tissue lengthening affects functional mobility skills in children with spasticity. The study is expected to run for two years and the primary study endpoint is when participants have completed their second post- operative data collection session.
The purpose of this study is to determine whether Dysport® (abobotulinumtoxinA) injections for lower extremity spasticity showed a significant reduction of lower extremity spasticity after being injected with Dysport® (abobotulinumtoxinA) in patients with MS.
Spasticity is a common complication in MS and occurs in up to 84% of patients. The main sign of spasticity is resistance to passive limb movement characterized by increased resistance to stretching, clonus, and exaggerated deep reflexes. Osmotica Pharmaceutical is currently developing arbaclofen extended-release tablets (AERT) for the treatment of spasticity in patients with MS.
This is a single-center, double-blind, randomized, placebo-controlled, sequential Phase II trial of human recombinant hyaluronidase injections in individuals with post-stroke upper limb muscle stiffness. The investigators will recruit 56 subjects, who will be randomized to receive either the intervention or normal saline injections (first injection), and then the intervention the participants did not receive first (second injection). All individuals will receive the treatment by the end of the study.
The purpose of this study is to evaluate if it is possible to use a new 3D imaging method to guide Botulinum neurotoxin (BTX) injection for muscle spasticity management after stroke. This imaging method is called three dimensional innervation zone imaging, or 3DIZI.
The purpose of this study is to improve spasticity diagnosis through exploration of potential new diagnostic markers for spasticity that can assist in diagnosis and referral.
The purpose of this study is to test the reliability of using telemedicine so a neurologist can remotely identify residents of a long-term care facility who should be referred to a neurologist for an in-person spasticity consultation.
The purpose of this study is to improve spasticity diagnosis through development of a simple physical examination guide for primary care providers to identify patients who would benefit from being referred to a movement disorders neurologist for a spasticity evaluation.
This study will examine the impacts of two different methods of managing MS-related spasticity of the lower limbs. Both interventions will be presented via video teleconference in group classes consisting of exercises to reduce spasticity.
To date, clinical tests are unable to differentiate between the cause of muscle stiffness, although a manual instrumented spasticity assessment for the lower limb that utilizes surface electromyogram has recently been proposed. This study intends to use shear wave elastography to assess individual muscle stiffness parameters and the individual response to botulinum toxin injection in the elbow and wrist flexors. Collection of baseline spasticity parameters could then be used to predict the effect of botulinum toxin type A and ultimately serve as a basis for development of a treatment model for muscle spasticity in patients with spastic cerebral palsy.
The purpose of this study is to evaluate if 5 consecutive sessions of PathMaker anodal DoubleStim treatment, which combines non-invasive stimulation of the spinal cord (tsDCS- trans-spinal direct current stimulation) and of the median nerve at the peripheral wrist (pDCS-- peripheral direct current stimulation), can significantly reduce spasticity of the wrist and hand after stroke.
This is a safety and efficacy study of onabotulinumtoxinA in poststroke patients with upper limb spasticity.
This study will examine the epidemiology (incidence and control of a disease), burden, clinical need, and treatment patterns of spasticity in patients with a diagnosis of Cerebral Palsy (CP), Multiple Sclerosis (MS), Stroke, Spinal Cord Injury (SCI), or Traumatic Brain Injury (TBI).
The purpose of this study is to assess the efficacy and safety of multiple doses of Dysport used in the treatment of upper limb spasticity (altered skeletal muscle performance) in children with cerebral palsy (CP).
Botox act on nerve endings, yet there are no nerve endings inside the muscle, where they are typically injected. All nerves terminate on the fascia, where ASIS device can precisely deliver Botox by creating that subdermal bloodless space, between the skin and muscle. Thus enhancing and prolonging Botox's efficacy, at the same time prevent it's unnecessary adverse reactions and distant spread, especially since Botox has no reason to travel to the rest of the body any way.