View clinical trials related to Spasticity, Muscle.
Filter by:This is a descriptive, prospective, non-controlled clinical investigation to be conducted on approximately 10 enrolled subjects at one site at Haukeland University Hospital in Bergen, Norway. The target subjects are male or female, 18-70 years, diagnosed with MS according to revised McDonald criteria (9) with spasticity and pain associated with the spasticity. Spasticity is evaluated based on self-reported spasticity using the numerical rating scale (NRS) which describes the average score of spasticity over the last 24 hours at >4 (where the scale scores spasticity from 0-10, where 0 is no spasticity, and 10 is worst possible spasticity), - combined with pain in the lower extremities last 24 hours. The pilot investigation is done to evaluate if FlowOx2.0™ can be used to treat spasticity with concomitant pain in patients with multiple sclerosis, using intermittent negative pressure affecting arteriovenous reflex.
Living with cerebral palsy is challenging for the child as well as the family charged with their care and support needs. Many families seek effective and sustainable interventions to improve gait of their children with cerebral palsy. The Mollii suit is a non-invasive therapeutic technology using electrical stimulation in the form of whole-body garment with multiple electrodes individually programmed to stimulate selected muscles. This study aims to examine if the Mollii suit improve gait in ambulant children with cerebral palsy and if the Mollii suit is acceptable and tolerable to children with cerebral palsy. We will recruit up to 20 children with cerebral palsy. This study will evaluate change in gait and function following a four-week intervention period using a protocol of wearing the Mollii suit at home for one hour every day for four weeks using instrumented 3-dimensional gait analysis and objective standardised assessment tools.
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 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.
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 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.