Active clinical trials for "Muscle Spasticity"

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.

The aim of the study is to see whether a physical therapy program can relieve pain, decrease spasticity and increase muscle contraction force by using the super inductive system (high frequency electromagnetic field). It is a longitudinal, prospective study, of 60 patients with spasticity after stroke. No new treatment method is tested, as the Super inductive system is approved for physical therapy by the Ministry of Health.

The study team is currently recruiting volunteers who are interested in participating in a brain-spinal cord-muscle response training study that aims to better understand the changes that take place in the nervous system as a result of this type of training. After spinal cord injury, brain-to-muscle connections are often interrupted. Because these connections are important in movement control, when they are not working well, movements may be disturbed. Researchers have found that people can learn to strengthen these connections through training. Strengthening these connections may be able to improve movement control and recovery after injuries. Research participants will be asked to stand, sit, and walk during the study sessions. Electrodes are placed on the skin over leg muscles for monitoring muscle activity. For examining brain-to-muscle connections, the study team will use transcranial magnetic stimulation. The stimulation is applied over the head and will indirectly stimulate brain cells with little or no discomfort. Participation in this study requires approximately three sessions per week for four months, followed by two to three sessions over another three months. Each session lasts approximately 1 hour.

Stroke represents one of the main causes of adult disability and will be one of the main contributors to the burden of disease in 2030. However, the healthcare systems are not able to respond to the current demand let alone its future increase. There is a need to deploy new approaches that advance current rehabilitation methods and enhance their efficiency. One of the latest approaches used for the rehabilitation of a wide range of deficits of the nervous system is based on virtual reality (VR) applications, which combine training scenarios with dedicated interface devices. Market drivers exist for new ICT based treatment solutions. IBEC/ Eodyne Systems has developed and commercialised the Rehabilitation Gaming System (RGS), a science-based ICT solution for neurorehabilitation combining brain theory, AI, cloud computing and virtual reality and targeting motor and cognitive recovery after stroke. RGS provides a continuum of evaluations and therapeutic solutions that accompany the patient from the clinic to the therapy centre. RGS has been clinically validated showing its superiority over other products while reducing cost also through its use of standard off-the-shelf hardware and a Software as a Service model (SaaS). Commercial evaluations have shown that RGS acts as a workforce multiplier while delivering a high quality of care at clinical centres (RGS@Clinic). However, in order to achieve significant benefits in the patients' QoL, it is essential that RGS becomes an at home solution providing 24/7 monitoring and care. For this reason, this project aims at investigating the RGS acceptability and adoption model. The findings derived from this study will contribute to establish a novel and superior neurorehabilitation paradigm that can accelerate the recovery of hemiparetic stroke patients. Besides the clinical impact, such achievement could have relevant socioeconomic impact.

The purpose of this study is to validate the capacity of a reflex training system to change the size of the targeted reflex. For this, the researchers are recruiting 25 individuals with chronic incomplete SCI who have spasticity in the leg to participate in the reflex training procedure. The study involves approximately 45 visits with a total study duration of about 6 months.

Stroke is nowadays a leading cause of disability with devastating sequelae. Upper limb spasticity is one of them. Nevertheless, not all the muscles are equally affected, as some may turn spastic or paretic and other remain intact. This unique pathophysiological mosaic dictates a precise therapeutic plan. Existing spasticity treatment has significant drawbacks due to its unspecific targeting and short duration. A causal, life-lasting treatment, precisely adapted to every single patient's needs and to disease pattern, is currently missing. Hyperselective muscle denervation and subsequent cognitive reinnervation with appropriate unaffected donor nerves may break the pathological spastic circuit and provide volitional muscle control. With this pioneering study we will perform cognitive nerve transfers to spastic muscles and will prospectively investigate their effects on clinical, electrophysiological, molecular-biological and histological level. Accurate donor nerve selection will be for the first time quantified through motor unit number estimation with high-density needle electromyography. This revolutionary concept can open the window to a new era of therapeutic possibilities for stroke victims.

This study is based on a 4-week double-blind, randomized, controlled, parallel design investigation to investigate the impact of intermittent negative pressure on spasticity and pain in people with multiple sclerosis (pwMS) (NCT05562453). The investigational device (FlowOx2.0™) is composed of a Pressure Chamber and a Control Unit (and disposable parts). All subjects will receive the same pressure chamber but be randomized to either a Control Unit that generates intermittent negative pressure (INP) of - (minus) 40 mmHg or a Control Unit that generates INP of - 10 mmHg. FlowOx2.0™ generating -40 mmHg is the investigational device, and FlowOx2.0™ generating -10 mmHg, is the comparator device. After the initial 4-week double-blind period (NCT05562453), all participants will be offered the -40mmHg control unit to be used during a 6-months optional extension part. The participants who volunteer to continue in the 6-months optional extension part will be included in this study.

Spasticity - a variety of motor over-activity and part of the upper motor neuron syndrome - is a common cause of impaired motor function after brain injuries of different etiologies. In addition, it may cause pain and impaired hygiene, contractures, deformities etc. Spasticity has been reported in 30 to 90% of patients with stroke, traumatic brain injury (TBI), incomplete spinal cord injury (SCI) and cerebral palsy (CP). Spasticity therapy has emerged as an important approach to alleviate related symptoms. Positive effects on spasticity are well recognized following systemic and intra-thecal pharmacological treatment, as well as after intra-muscularly injected substances; the effect of the latter is, however, of limited duration. While pharmacological spasticity therapy has been applied for decades, surgical procedures remain fairly uncommon in adults with spasticity, but not in pediatric patients with CP, and outcomes after surgical treatment are scarcely described in the literature. The study center is a specialized unit initially focused on reconstructive as well as spasticity reducing surgery in the upper extremities for SCI patients. Subsequently, patients with spasticity also due to various other Central nervous system diseases have been referred to the center for surgical treatment. Studies describing the effect of spasticity-reducing surgery in the upper extremities are rare and the group is heterogeneous. The aim of the study is therefore to evaluate the results and compare against todays golden standard treatment (boutuliniumtoxin injections).

Background: Unilateral Spastic Cerebral Palsy (USPC) is caused by an injury in one brain hemisphere in the immature brain, and affects the contralateral side of the body, especially on the upper limb. It induces motor and somatosensory damages, that are closely related to the hand function. Evidence posits mirror therapy to be a therapy with potential effects on bimanual performance and somatosensory function, that may influence on quality of life. The aim of this study is to demonstrate the effectiveness of a motor program with mirror therapy in children with USCP in the improvement of the bimanual performance, the somatosensory function and quality of life compared with the same program without mirror. Methods: This study is a Randomised Clinical Trial. The participants are children with USCP aged between 8 and 12 years old classified in levels I and II in Manual Ability Classification System, recruited from Fundació Aspace Catalunya. The eligibility criteria are a) to not have had surgical interventions, botulinum toxin or shock waves 3 months before the study; b) to not be receiving intensive therapies on the upper limb; c) to not have attentional or behavioural difficulties; d) to not have moderate to high intellectual disability; e) to not have non-treated epilepsy; and f) to not have non-corrected visual problems. A total of 22 participants will be recruited for this study, and will be randomised in two groups: control and experimental, through the opaque envelope technique. The experimental group will perform a 5-week motor program consisting of 4 bimanual exercises with mirror therapy, to be done at home 30 minutes a day, 5 days a week, while the control group will perform the same program without the mirror. The assessments will be done by a blinded evaluator and will include bimanual performance (Children's Hand-use Experience Questionnaire), somatosensory function and quality of life (PedsQL™), and will be performed at the beginning, at the end of the intervention and 1-month follow-up. Discussion: Favourably results in this study may imply the implementation of a low-cost therapy, suitable to be done at home, and with no contraindications for children with USCP. Moreover, the suitability to be adapted and performed at home could increase the family implication and empowerment, increasing its confidence in the disability process.

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.