Active clinical trials for "Muscle Spasticity"

The patients who were diagnosed with stroke in governmental/university/private hospitals, and who needed rehabilitation because of the increased flexor tone in the elbow joint, decreased range of motion and/or decreased function of the upper extremity will be invited to the study in accordance with the criteria that are given in inclusion and exclusion part. Participants will be randomly assigned to one of two parallel groups, either the PNF Stretching Group (n=17) or the Prolonged Stretching Group (n=17), according to the order of participation in the study by simple randomization. An online computer program will be used to assign participants (https://www.randomizer.org/). Exercises that will increase proximal stabilization and control will be applied to both groups for 4 weeks, 5 days a week. In addition to the exercises, prolonged stretches for 10 minutes will be applied to the Prolonged Stretching Group, and PNF stretching will be applied to the PNF Stretching Group. At the beginning and the end of the study, muscle architecture, muscular viscoelastic properties, range of motion, proprioception, upper extremity motor performance and function and posture will be evaluated.

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 50 subjects, 25 males and 25 females, who will be randomized to receive either hyaluronidase plus saline (treatment arm, n=25) or normal saline (control arm, n=25) injections (first injection) in Phase 1 of the study over 5 visits that will test all 3 study aims. Then subjects will join the Phase 2 to receive a second injection, where the treatment arm will receive the placebo and the placebo arm will receive the treatment. It is expected that approximately 50 participants will be enrolled to produce 42 evaluable participants. This design will ensure that all subjects receive the drug treatment, which will facilitate recruitment. The injecting physician, the assessors, and the patients will be blind to group assignment. Randomization will be initiated by the IDS pharmacy as per the study statistician. All patients will be assessed at seven visits over 9 weeks of the study: Visit 1 - screening and baseline assessment of aims 1 and 2 (week 1-2); Visit 2 - pre-injection MRI for aim 3 (week 1-2); Visit 3 - first injection (week 2); Visit 4 - post-injection MRI (week 3-5); Visit 5 - post-injection follow up for aims 1 and 2 (week 3-5); CROSSOVER TO OPPOSITE TREATMENT ARM Visit 6 - Second injection (week 6); Visit 7 - post-injection follow-up for aims 1 and 2/ final study visit (week 7-9). There will be no MRI assessment after the second injection as the technique is adequately sensitive to demonstrate changes with a small sample size. The investigators will follow the patients for approximately 9 weeks in this study. After obtaining informed consent, subjects will be screened to ensure that the subjects meet study criteria.

Stroke is of high morbidity and mortality, and surviving patients are often unable to take care of themselves because of severe motor dysfunction. The brain has plasticity, and makes adaptive changes after stroke, resulting in the reorganization and compensation of neural networks. However, the muscle tone of some patients will significantly increase during the recovery process, which affects the rehabilitation effect. Neuromodulation techniques such as repetitive transcranial magnetic stimulation (rTMS) have been widely used to promote brain network remodeling after stroke. The investigators attempted to evaluate the motor brain network characteristics of spastic patients by fNIRS, and used the most active brain regions as rTMS stimulation regions to evaluate the improvement effect of this individualized treatment on post-stroke spasticity.

Background Effective management of spasticity, a debilitating and challenging condition afflicting many recovering from and living with neurological conditions, may reduce long term consequences such as limb contracture, skin breakdown, compromised mobility, caregiver burden and discomfort. In rehabilitation, spasticity represents a significant barrier to successful rehabilitation outcomes. Effective spasticity management can increases the length of individual functional status, reduces equipment/care needs, hospital admissions and extends the time people can stay safely at home, which would represent an economic benefit to the health system. Extra-corporeal Shock Wave Therapy (ESWT), an intense short energy wave delivered directly at the region of affected muscles has, in past randomized controlled studies, demonstrated positive outcomes for this population (spastic stroke population, TBI), on its own and as an adjunct to current modalities. In fact, one retrospective observational study demonstrated an increased efficacy of Toxin botulinum at 1 month when combined with ESWT. Where existing treatment options may be limited by coverage, access to delivery, complications and side effects, ESWT represents a potential to be a safe, low cost, efficacious alternative that can be administered by any trained clinician. Aims The aims of this pilot study will be to explore the hypothesis that adding ESWT to Botulinum Neurotoxin A (BoNTA) in spasticity post-stroke (TBI)will demonstrate greater clinical and patient reported outcomes compared to standard treatment with BoNTA alone, a comparison only once previously studied. Methods Incorporating randomization and placebo control (n= 20 in each arm), this patient-centric study will examine treatment goals and holistic perception of benefit after the treatment experience. We will use patient reported outcomes at baseline and at defined intervals after intervention. We will test our hypothesis using clinical and patient reported scales, such as the patient reported numeric rating scale (NRS) and goniometric range for spasticity as our primary outcome in conjunction with measures of muscle stiffness, quality of life, feasibility and acceptability of the protocol to help inform future study direction.

The purpose of the study is to assess the safety and efficacy of increasing doses of IPN10200 with the aim to evaluate the Pharmacodynamics (PD) profile of IPN10200 and to establish the total IPN10200 doses(s) that offer the best efficacy/safety profile when used for the treatment of Adult upper limb (AUL) spasticity.

Cerebral palsy is a neurological disorder with abnormalities in muscle tone, movement disorders and motor incapability. It attributes to harm to the growing brain. Cerebral approach including brain and its palsy referred to weakness and problems while using the muscles. It is characterized by way of the incapability to normally control motor features, and it has. the capacity to have an impact on the general improvement of a child with the aid of affecting the child's capability to explore, talk, learn, and grow to be independent. Spastic CP is the most common type among children and debts for almost 77% among all instances. It is the major problem in CP child making movement difficult or even impossible.

Cerebral Palsy (CP) is is estimated to be around 1.5-3 per live birth, with prenatal factors accounting for 75% of cases. CP appears in early childhood and persists with age and is characterized by permanent lesions or abnormalities affecting the immature brain. It mainly occurs as a motor system disorder (e.g., abnormal movements or posture) with the presence of hemiplegia, diplegia or tetraplegia, and spastic, dyskinetic or atactic syndromes. .This study will explore the potential clinical benefits of the Molliimethod in children with cerebral palsy. Spasticity impacts balance and mobility, halts the patients quality of life and their ability to perform their activity of daily living, and could also increase the risk of fractures and falls. Available interventions that aim on improving spasticity are facing limitations such as varios side effects. Therefore, developing novel therapies such as the EXOPULSE Mollii Suit could help to overcome such limitations and noninvasively improve balance, mobility, quality of life and reduce spasticity and pain in children with CP.

The purpose of this study is to investigate the feasibility of a 10-week plan with a nutritional supplement (leucine) and to perform pilot analyses on the effect of leucine on macroscopic muscle morphology in children with cerebral palsy.

The purpose of this project is to examine and compare the immediate and long-term effects of combined Botulinum toxin type A(BoNT-A) injection with exoskeleton Robotic assisted gait training (RABT) in patients with post-stroke stiff-knee gait.

Cerebral Palsy (CP) is a group of movement and posture disorders associated with a non-progressive affect during brain development that can cause limitation of activity and disability. The most common movement disorders in CP are spasticity and dystonia. Currently, the treatment of muscle stiffness called spasticity includes physiotherapy, casting and device, various drugs and surgical treatment. Botulinum toxin injection into the muscle also acts by reducing muscle contraction. ESWT is a method used in various musculoskeletal diseases. It has been previously applied to pediatric patients and has been shown to be effective and painless in ankle muscle stiffness. However, there are few studies investigating the effect of ESWT on functionality.