View clinical trials related to Muscle Spasticity.
Filter by:Spasticity (tightening, spasming and/or contractions of muscles) is a commonly encountered consequence of injuries to the central nervous system. Spasticity has an adverse effect on quality of life and function of patients with spinal cord injuries, stroke and cerebral palsy. Conventional management consists of medication, injections of botulinum toxin and occasionally extensive surgical interventions. Several studies have examined the use of repetitive magnetic stimulation of the brain and of peripheral nerves to produce long-term depression of spasticity. Recently, Theta burst sequence low-dose magnetic stimulation has been shown to mark unused synaptic connections for deletion. By using pulsed magnetic stimulation of the spinal cord the abnormal connections arising from injury may be identified for deletion, therefore potentially minimising the mis-firing circuits. The investigators plan, in this pilot study, to test whether firstly the application of pulsed magnetic stimulation of the spinal cord is achievable in patients with spinal cord injury (SCI) and secondly whether it has an effect on lower limb spasticity. These results will be used to help design a larger trial, to expand the numbers of participants and variety of pathologies treated. Participants (in-patients at the Midland Centre for Spinal Injuries) with stable SCI will be randomised to receive either intermittent pulsed magnetic stimulation or no stimulation. Patients will be blinded as to whether they are receiving stimulation (the machine will be active up and placed in the same position for both groups, except the sham group will have the stimulation coil applied in an orientation that does not deliver the magnetic field to the spinal cord).
The aim of this study is to determine the clinical spectrum and natural progression of Hereditary Spastic Paraplegias(HSP) and related disorders in a prospective multicenter natural history study, to assess the clinical, genetic and epigenetic features of patients with Spastic Paraplegias to optimize clinicalmanagement..
This study evaluates the optimal interstimulus interval for consecutive H-reflex responses in patients with spasticity.
The main objective is to study the variability and evolution of single-fiber jitter and fiber density (FD) electrophysiological parameters in a spastic muscle during botulinum toxin type A (BTA) treatment in hemiplegic patients after stroke, according to primary or multi-injected status. The secondary objectives of this study are: A. To establish a correlation between single-fibre electrophysiological parameters and the therapeutic response to BTA, clinically estimated by the MAS scale. B. Creation of a database on single fibre parameters to determine a Jitter numerical threshold beyond which the effect of BTA appears to be decreasing according to the clinical evaluation by the MAS (Modified Ashworth Scale).
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.
To investigate, through ethnography, changes in symptom burden and disability and their effects/interference on patient functioning, ability to perform activities of daily living (ADL) and quality of life (QoL) throughout the duration of one BoNT-A treatment cycle.
The purpose of this study is to determine whether a single treatment with administration of 400 Units NT 201 (botulinum toxin) is superior to placebo (no medicine) for the treatment of lower limb spasticity caused by stroke or traumatic brain injury (Main Period). Participants will be assigned to the treatment groups by chance and neither the participants nor the research staff who interact with them will know the allocation. The following 4 to 5 treatment cycles will investigate the safety and tolerability of treatment with NT 201 (botulinum toxin) when administered in doses between 400 and 800 Units (Open Label Extension Period). All participants will receive the treatment and the dose will depend on whether only lower limb spasticity or combined upper and lower limb spasticity are treated.
The aim of this study is to determine the clinical spectrum and natural progression of Hereditary Spastic Paraplegias (HSP) and related disorders in a prospective multicenter natural history study, identify digital, imaging and molecular biomarkers that can assist in diagnosis and therapy development and study the genetic etiology and molecular mechanisms of these diseases.
Goal of this study is to develop and evaluate a physiotherapy concept that is focused on bilateral leg spasticity and aims to reduce spastic gait disturbance and to improve mobility in patients suffering from HSP.
The first aim of this study is whether the inhibitory kinesio taping application can reduce spasticity. The second aim of this study is to investigate whether the kinesio taping application have neuromodulatory activity on motor neuron and stretch reflex. Hypotheses of this study: unlike healthy cases, in patients with spastic hemiplegia 1. Inhibitory kinesio taping application can reduced spasticity 2. Inhibitory kinesio taping application can reduced motor neuron activity and stretch reflex