View clinical trials related to Spasticity, Muscle.
Filter by:The purpose of this study is to assess the immediate effects of CRet associated to Functional Massage (F.M) in terms of gait and functionality after stroke
Spasticity is due to an abnormal processing of a normal input from muscle spindles in the spinal cord.
This is a randomized clinical trial to study the effect of tDCS in participants with subacute ischemic stroke, the study participants will be randomly assigned into three groups; bihemispheric, unihemispheric and sham group.
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.
The purpose of this study is to provide continuing evaluation and reporting of safety and performance of the SynchroMed II Infusion System within its intended use. Data will support post-market surveillance obligations.
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.
Spasticity, defined as a velocity dependent increase in tonic stretch reflexes, is one of the most prominent motor problems that occur in patients with cerebral palsy (CP). This causes difficulty in achieving balance, mobility, and an upright stance. CP is a group of permanent disorders that affect the development of movement and posture caused by a non-progressive damage to the brain. Because CP occurs in 2-3 of 1000 individuals, it is one of the most common causes of severe physical disability in children. Mismanagement of spasticity can lead to contracture which is extremely difficult to treat and may result in severe functional disabilities. The current management of spasticity in CP includes physical therapy (i.e. passive stretching), oral medication, botulinum toxin injection, and surgery. Botulinum toxin injection has been proven to effectively reduce spasticity yet many patients are unable to get access to this treatment due to its high cost. Moreover, Botulinum toxin injection is currently not covered by the public health insurance of Indonesia. Therefore, other modalities which are more affordable and are non-invasive therapies should be considered as a treatment option for spasticity. Radial Extracorporeal Shockwave Therapy (rESWT) has been utilized in the medical practice for the treatment of several musculoskeletal disorders such as chronic tendinopathies and spasticity. It is hypothesized that ESWT has two main effects which include a direct effect from mechanical forces at the treatment point and an indirect effect from cavitation. Even though rESWT has less penetration capacity over the focused Extracorporeal Shockwave Therapy (fESWT), rESWT is still believed to be more superior to fESWT because it requires less precise focusing, is less painful, and costs less. These also make rESWT the more appropriate choice for children with CP. Many studies have proven the efficacy of ESWT in reducing spasticity in spastic CP patients with significantly long lasting effects. Despite promising results, there still has yet to be a recommended guideline for the treatment of spasticity in children using rESWT. One of the critical parameters needed to be determined is the frequency of treatment. Therefore, the objective of this study is to understand whether the reduction in gastrocnemius stiffness in children with spastic CP is influenced by the frequency of ESWT sessions.
Spasticity of stroke patient, a very common complication in clinical practice, affects performance of hand function and gait pattern. It also interferes with quality of life of patients severely. Currently first line clinical approach to spasticity consist of physical therapy and pharmacological management. However, there are still some refractory cases that needed local intervention such as Botox injection. So far, we only can use subjective methods to measure muscle tension, such as modified Ashworth scale and Tone Assessment Scale. In our previous study, we found that ultrasound shear wave image could correlate with muscle stiffness caused by poststroke spasticity. With this new method, we aim to establish a more objective method in measuring abnormal poststroke muscle tension before and after treatments and further monitor therapeutic effect. We also include several assessment scales to evaluate the correlation between measured muscle spasm and activity of daily living. We hypothesize that the rheological changes in muscles muscle spasm after Botox injection can be detected by ultrasound shear wave image. Therapeutic effect can also be seen in its effect on daily functions. In this project, we will use shear wave imaging of ultrasound to investigate the elasticity (and hardness) of the biceps brachii and brachialis muscle in stroke patients with unilateral hemiplegia before and after Botox injection. The findings of this project will provide the objective evaluation of muscle spasticity and its correlation with functional status, which will provide new points of view toward treatment of spasticity.
Cerebral palsy (CP) is a group of permanent disorders affecting movement and postural development that are caused by non-progressive disruptions of the brain, usually occurring during fetal period or infancy. It is commonly accompanied with sensory disorders and learning disability. In 2016, more than 17 million people are affected by CP with a prevalence of 1.5 to 2.5 per 1,000 live births. CP remains to be the most common cause of severe physical disability in children. The Centres for Disease Control and Prevention (CDC) estimated an economic cost of US$4.1 million per CP patient that comprises of medical services, special education and productivity loss. Current management of spasticity involves physical manipulation such as passive stretching and splinting, sometimes combined with oral pharmacologic treatment, intrathecal baclofen therapy and botulinum toxin injection. At times, surgical procedures such as Surgical Dorsal Rhizotomy (SDR) can also be considered. Botulinum toxin injection has been shown to reduce spasticity for up to 6 months, however, the cost of the procedure remains to be an issue in developing countries like Indonesia. Therefore, other modality such as a non-invasive therapy should be considered as an alternative treatment for spasticity. Radial Extracorporeal Shockwave Therapy (rESWT) is a non-invasive treatment that has been shown to effectively improve spasticity in patients with spastic motor type CP, despite unclear underlying mechanism. According to International Society for Medical Shockwave Treatment (ISMST), there has yet to be a recommended guideline for the treatment of spasticity in children using rESWT. One crucial physical parameter needed to be determined is the number of pulse required to efficiently reduce spasticity. The number of pulse directly affects the duration of ESWT per session (the higher the number of pulse given, the longer the therapy session). This may be a concern for spastic motor type CP due to accompanying sensory and learning disability. Therefore, the objective of this study was to understand whether the reduction in hamstring stiffness in children with spastic CP could be influenced by the number of pulse in a single ESWT session.
The proposed clinical trial will employ the NEUROExos Elbow Module (NEEM), an active robotic exoskeleton, for the passive mobilization and active training of elbow flexion and extension in 60 sub-acute and chronic stroke patients with motor impairments (hemiparesis and/or spasticity) of the right arm. The study protocol is a randomized controlled trial consisting of a 4-week functional rehabilitation program, with both clinical and robotically instrumented assessments to be conducted at baseline and post-treatment.