View clinical trials related to Spasticity.
Filter by:Spasticity is often observed as muscle tightness and stiffness in the upper and/or lower limbs. Upper limb spasticity can interfere with joint movement and its severity can range from mild to severe. This study will assess how effective OnabotulinumtoxinA is in treating pediatric participants with Spasticity. Change in disease activity will be evaluated. OnabotulinumtoxinA is approved drug for treatment of Spasticity. Approximately 106 pediatric participants aged 2-17 years with spasticity associated with cerebral palsy will be enrolled in approximately 10 sites across Mexico. Participants will receive OnabotulinumtoxinA as prescribed by their physician in accordance to local label and followed for 12 months. There is expected to be no additional burden for participants in this trial. Participants will attend regular visits to a hospital or clinic in their routine practice.
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 the study is to measure the outcomes of a standard care, an ultrasound guided mini-invasive percutaneous procedure, performed on recent stroke patients on reduces pain, increases function & quality of life The primary objective of the project is to reduce shoulder and/or knee pain in patients who have had a stroke so that they can more readily engage in rehabilitation. Secondary objectives are to reduce analgesic medications, increase independence and improve range of motion, to promote non-drug treatment measures in the medical toolkit, and to include an interdisciplinary care team in patient selection for interventions.
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.
Spasticity has been defined as a disorder of the sensorimotor system characterized by a velocity-dependent increase in tonic stretch reflexes (muscle tone) with exaggerated tendon jerks, resulting from hyperexcitability of the stretch reflex. The treatment goal of spasticity is Medical treatment generally combines physiotherapy with medications, depending on spasticity distribution. Systemic treatments such as oral or intrathecal baclofen are generally considered in case of generalized spasticity, whereas local treatments are considered in case of focal spasticity. Local treatments such as Botulinum Toxin type A, phenol, and alcohol present several advantages, allowing to treat of selected muscles without the risk of sedation. As stated above, they are indicated for focal spasticity but might be helpful even in the presence of generalized spasticity with identified focal goals (Bethoux et al., 2015). In particular, Botulinum Toxin type A (BoNT-A) is considered the gold standard treatment for focal spasticity, showing a level A evidence for spasticity reduction in upper- and lower-limb spasticity (Simpson et al., 2016). However, current evidence is mainly focused on post-stroke spasticity (Franceschini et al., 2014), whereas it is still limited in spasticity as a consequence of other aetiologies, such as spinal cord injury (SCI), traumatic brain injury (TBI), or multiple sclerosis (MS). Interestingly, spasticity is a major concern for the rehabilitation of these patients. The aim of this observational study is the evaluation of the clinical efficacy of BoNT-A in spasticity reduction in patients affected by neurological conditions different from post-stroke spasticity, such as SCI, TBI, and MS.
Inflammatory synaptopathy is a prominent pathogenic mechanism in multiple sclerosis (MS) and in its mouse model, which can cause excitotoxic damage by long-lasting excessive synaptic excitation and, consequentially, drives disease progression by leading to motor and cognitive deficits. As synaptopathy occurs early during the disease course and is potentially reversible, it represents an appealing therapeutic target in MS. Although reliable biomarkers of MS synaptopathy are still missing, recent researches highlighted miR-142-3p as a possible candidate. Indeed, miR-142-3p has been described to promote the IL-1beta-dependent synaptopathy by downregulating GLAST/EAAT1, a crucial glial transporter involved in glutamate homeostasis. Furthermore, mir-142-3p has been suggested as a putative negative MS prognostic factor and a target of current MS disease modifying therapies. The hypothesis of this study is that miR-142-3p represents a good biomarker for excitotoxic synaptopathy to predict MS course, and, possibly, treatment efficacy at individual level, including both pharmacological strategies and non-pharmacological interventions, like therapeutic transcranial magnetic stimulation (TMS) to ameliorate MS spasticity. To this aim, the role of miR-142-3p in MS synaptopathy, its potential impact on the efficacy of disease-modifying treatments currently used in MS therapy as well as the influence of genetic variants (SNPs) of miR-142-3p and GLAST/EAAT1 coding genes on the responsiveness to therapeutic TMS, will be further investigated in the study. By validating miR-142-3p as potential biomarker of synaptopathy, it is expect to improve MS prognosis and personalized therapies. Patients with MS, who will undergo neurological assessment, conventional brain MRI scan, and CSF and blood withdrawal for diagnostic and clinical reasons at the Neurology Unit of IRCCS INM-Neuromed will be enrolled in the study. Neurophysiological, biochemical and genetic parameters together with lower limb spasticity will be evaluated. Subjects, who will undergo blood sampling and/or lumbar puncture for clinical suspicions, later on not confirmed, will be recruited as control group. A subgroup of MS patients showing lower limb spasticity will be included in a two-week repetitive TMS stimulation protocol (iTBS) to correlate the patient responsiveness to this non-pharmacological treatment with MS-significant SNPs of both miR-142-3p and GLAST/EAAT1 coding genes.
A clinical trial is planned to study the effects of cannabis on dystonia and spasticity in children with neurological diseases. The clinical trial will include 40 children divided into two groups: children with spasticity and dystonia due to cerebral palsy, and children with spasticity and dystonia due to genetic neurodegenerative diseases. Each group will be randomly divided into two arms and will receive Avidekel cannabis oil 6-to-1 ratio of CBD to THC or enriched Avidekel cannabis oil 20-to-1 ratio of CBD to THC. During the study, various variables will be collected including: medication intake, spasticity, dystonia score, pain scale, restlessness scale, quality of life measures, safety tests, side effects, and an addiction test. The investigators hypothesize that cannabis consumption will reduce dystonia and spasticity in children with motor disability related to genetic neurodegenerative diseases and cerebral palsy and as a result improve motor function, non-motor functions and quality of life.
Concomitant use of botulinum toxin and robot would make better results regarding upper extremity function compared to robot, botulinum toxin, or no intervention.
Extended periods of tilt table standing have been observed to improve spasticity in individuals with spinal cord injury (SCI). The purpose of this study is to determine the effect of three sessions of whole body vibration while tilt table standing on spasticity in individuals with a complete or incomplete SCI above the neurological level of T10. Participants in this study will undergo whole body vibration while standing on a tilt table for a total of approximately 14 minutes for a total of 3 sessions on 3 separate days. Spasticity monitoring will be evaluated prior to and after the intervention with the Modified Penn Spasm Frequency Scale, an interview to obtain the individual's perception and impression of the effect of whole body vibration on the performance of activities of daily living, quality of life, pain scale, and global impression of change.
Stiff knee gait is defined as the lack of knee flexion in the swing phase of gait. Stiff knee gait is a frequent condition among stroke patients leading to reduce gait speed and increase energy cost. In association with neuro-rehabilitation, botulinum toxin A injections in the rectus femoris is recommended. However, the botulinum toxin A effect is transient necessitating repeated injections. The aim of this study is to compare the benefit of the rectus femoris tenotomy in comparison with botulinum toxin A injections according to the 3 domains of the International Classification of Functioning Disability and Health of the World Health Organisation