View clinical trials related to Cerebral Palsy.
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 currently one of the major causes of disability in children. The presence of various disorders (muscle stiffness, architectural bone defects, spasticity) leads to a number of functional impacts, including severe impairment of mobility, particularly locomotion. Locomotion can be assessed using a motion capture system that enables 3-dimensional analysis, in order to help make treatment decisions and quantify them. Although these systems are currently considered to be the gold standard, the fact remains that they cause a certain amount of patient fatigue (long set-up times) and that walking is assessed in a laboratory rather than in real life. Today, technological advances have brought to the fore other gait analysis devices, such as inertial measurement units (IMUs). Various systems incorporating IMUs in the feet, for example, respond to these problems of analysing walking in real-life situations. The IMUs record the movements and orientation of the foot in space; the data is then processed by algorithms to recognise walking steps and calculate the spatio-temporal parameters of locomotion. Additional IMUs positioned on the body can be grafted onto this system to provide a more precise analysis of locomotion, in particular by calculating the movements of the various joints of the lower limb. However, before such devices can be used in a pathological paediatric population, they must be validated in a healthy population. This validation must be conducted using a precise method that has been widely documented in the COSMIN recommendations (Consensus-based Standards for the selection of health Measurement Instruments). The first stage will assess the safety of the IMU devices in a healthy paediatric population, and the validity of the spatio-temporal parameters. If these properties are deemed to be compliant, these same parameters will be assessed in a paediatric population with cerebral palsy in the second stage.
Children with cerebral palsy (CP) show varying degrees of motor impairment and movement disorders whose perceptive-visual contribution has yet to be established. The literature reports that children with CP have more frequent neuro-visual disorders. The link between the location and size of the brain lesion and neurovisual symptomatology has yet to be explored. In this retrospective clinical data study, we will investigate in children with PC whether there is an anatomo-clinical correlation between visuo-spatial disorders is the brain injury of interest to the dorsal visual pathway. We will explore the volume of grey and white matter parietal involvement. To test visuo-spatial disorders, we will use the PVSE (Visuo-Spatial Elementary Perception) test which does not require motor skills or language and is therefore suitable for children with a PC. This test will make it possible to better identify the deficit or deficits in order to adapt an early remediation. It could serve as a reference for comparing several pathologies/etiologies.
This RCT aims to investigate the effect of repetitive transcranial magnatic stimulation (rTMS) in treating children with hemiplegoc cerebral palsy. The study will measure any improvement in spasticity after using contra-lesional inhibitory rTMS follow by intensive limb training. Participants will attend a 10-day rTMS treatment sessions, follow by intensive training of the impaired limb. They will also undergo MRI scans before and after the treatment to investiagte the underlying neurophysiological mechanisms that lead to changes clinically by using TMS as well as MR-DKI. Researchers will compare the intervention group and the sham group to see if rTMS could result in improvement of participants' spasticity.
The purpose of this study is to test the safety of placing Deep Brain Stimulators (DBS) in a part of the brain called the cerebellum and using electrical stimulation of that part of the brain to treat movement symptoms related to cerebral palsy. Ten children and young adults with dyskinetic cerebral palsy will be implanted with a Medtronic Percept Primary Cell Neurostimulator. We will pilot videotaped automated movement recognition techniques and formal gait analysis, as well as collect and characterize each subject's physiological and neuroimaging markers that may predict hyperkinetic pathological states and their response to therapeutic DBS.
To assess the safety and tolerability of single and multiple doses of MTR-601 in normal healthy volunteers under fed and fasted conditions. To evaluate the plasma and urine pharmacokinetics (PK) of MTR-601. To evaluate the pharmacodynamic (PD) effects of MTR-601 on muscle strength and muscle accumulation of MTR-601 by muscle biopsy and other potential mechanistic, predictive and PD markers of MTR-601.
This project focuses on motor development, muscle growth and muscle activity. Using advanced, instrumented tests such as , the link between muscles and the movement characteristics will be studied. In addition, the evolution of these neuro-biomechanical determinants during the first year of life will be investigated. The examinations are planned for a group of high-risk infants (e.g. premature birth, cases of asphyxia, etc.) compared with a group of infants with typical development.
Cerebral Palsy (CP) is the most common developmental disorder in childhood. Individuals' independence in daily living activities and participation in education, games, social and community activities are restricted. Technology applications in the field of rehabilitation are gaining momentum. EXOPULSE Mollii Suit method, one of the newest rehabilitation technology products, is a non-invasive neuromodulation approach with a garment that covers the whole body and electrodes placed inside. Designed to improve motor function by reducing spasticity and pain, the method is based on the principle of reciprocal inhibition, which occurs by stimulating the antagonist of a spastic muscle at low frequencies and intensities. Therefore, the aim of our study is to examine the effectiveness of the Mollii Suit application on gross and fine motor function, spasticity severity, balance, walking, selective motor control, postural control, daily living activities, quality of life, pain and sleep quality in individuals with ambulatory spastic CP.
The goal of this prospective cohort study is to learn about the impact of an adapted dance program in youth with cerebral palsy. The main questions it aims to answer are: 1. Are there clinically significant benefits for children with cerebral palsy who participate in an Adaptive Dance Program? 2. Is it feasible to implement an adaptive dance program using action-observation principles for children diagnosed with Cerebral Palsy (CP)? Participants will complete a pre-dance program assessment, participate in a 10-week dance program (20 hours), and complete a post-dance program assessment.
The proposed research project aims to answer the question "Are immersive technology systems effective in the rehabilitation management of pediatric patients with cerebral palsy and with mobility limitations?". The current study is the second of three phases, and it aims to create an immersive gamification technology system for the management of patients with cerebral palsy and with mobility disorders and to determine its clinical effectiveness, safety, and usability among children with mild to moderate cerebral palsy.