View clinical trials related to Multiple Sclerosis.
Filter by:The current study will add to the current knowledge by combining several electrophysiological techniques to examine the relationship between physiological responses and cognitive fatigue and daily activity performance in a stress- and fatigue-inducing protocol. The aims of this study are: 1) to evaluate the feasibility and usability of assessing physiological responses in an experimental set-up and 2) to investigate the association between physiological outcomes, experimentally induced stress and cognitive fatigue in people with multiple sclerosis (MS) and healthy controls.
The thalamus is composed of several nuclei interlocked in a complex anatomy. In multiple sclerosis (MS), the thalamus can be altered due to disconnection by white matter lesions and due to direct damages that could be partly mediated by CSF. Due to such pathophysiology and complex anatomy, some nuclei could be more vulnerable to multiple sclerosis than others. We will test this hypothesis by using a new algorithm to automatically segment several nuclei that we will be applied to the French national MS database
Patients with multiple sclerosis will be randomized into two groups. One group will receive live telerehabilitation sessions 3 times a week over a course of three months. The other group will receive video instructions for aerobic and strengthening exercises. Patients fatigue, sleep quality and quality of life will be measured.
Multiple sclerosis negatively affects the endurance and functionality in the upper extremities. 20 female patients aged 18-70 years who were diagnosed with MS will be included in the study. Demographic, family, cigarette alcohol use, etc. information will be obtained from the patients and the study will begin. Timed 25-Step Walking Test, upper extremity endurance with UULEX, Hand-Shoulder and Arm Problems Questionnaire (DASH) and Nine-hole Board Test (DDTT) evaluation were performed on the patients. Manual muscle test for muscle strength, handheld dynamometer handheld Grip strength will be measured with a dynamometer and spasticity will be measured with the Ashworth scale. Depression status of the patients will be determined by the Beck depression scale, and the presence of dyspnea will be determined by the dyspnea scale. The validity and reliability of the Unsupported Upper Extremity Exercise Test (UULEX) will be investigated with the obtained data. In order to give the most accurate result of the test in adults over 65 years of age, 3 repetitions will be performed with a resting period of half an hour. Limitation of activities of daily living will be evaluated with MSQOL-54 specific to Multiple Sclerosis. Intraclass correlation coefficient (ICC) will be used to determine test-retest reliability.
Progressive-onset multiple sclerosis (PPMS) occurs in about 15% of all people living with MS. PPMS remains understudied, and most disease-modifying treatments are ineffective for PPMS. To date, it is unknown why some people progress immediately from MS onset. The present study will assess the role of gray matter in PPMS by characterizing it with ultra-high field magnetic resonance imaging (MRI). While both white and gray matter are affected in relapsing MS, in PPMS tissue damage is primarily in the cortex. Cortical gray matter consists largely of neuronal cell bodies, which send electrical signals to create a functional response, such as arm or leg movement. While white matter damage slows the signal response, cortical damage inhibits the initial creation of electrical signals. There is a great need to research and develop scientific biomarkers to identify and monitor progression and repair in PPMS. In this project, 7 Tesla MRI is used to investigate the cortical gray matter in people with PPMS. 7 Tesla MRI is the safest and most detailed way to study the brain. Because the cortex is only a few millimeters thick, it has been traditionally difficult to investigate. At 7 Tesla, different layers and lesions within the cortex can be seen. In addition, this project will use myelin-sensitive MRI to determine the biological underpinnings of both cortical lesions and the 'normal appearing' cortical damage in PPMS. This will answer relevant questions about the brain's capacity for repair, the extent of demyelination and the occurrence of inherent cortical remyelination and provides an avenue for the development of novel clinical MR biomarkers tailored to PPMS.
Background: Multiple Sclerosis (MS) is a chronic condition of the central nervous system; around 1 in 600 people in the United Kingdom have MS. Many people with MS (70%) have cognitive difficulties, which they experience as distressing and disabling, and there is currently a lack of treatment options to improve these difficulties. SMART (Strengthening Mental Abilities with Relational Training) - a theory-based online cognitive training programme, which has been shown to improve general cognitive abilities - has not been tested with people who have MS. Aims: To conduct a feasibility study to inform development of a definitive trial of SMART for improving cognitive functioning in people with MS. The investigators will assess: 1. Acceptability to participants of the intervention, delivery format, inclusion/exclusion criteria, baseline and outcome measures, randomisation protocol, and study procedures 2. The framework for a cost-effectiveness analysis alongside a definitive trial 3. Participant recruitment and retention rates 4. Sample-size needed for fully powered trial 5. Signal of efficacy Plan: To address Aims 1-5, the investigators will recruit 60 adults with MS who are experiencing cognitive difficulties, identified from MS clinics. Participants will complete baseline assessments of their cognitive abilities and answer questionnaires about their cognitive difficulties, personal priorities, mood, fatigue, self-efficacy, quality of life, and healthcare services used. Assessments will be administered by a researcher, face-to-face or remotely. Participants will be randomly allocated to one of three arms (20 per group): Group 1: Receives SMART intervention online - plus usual care (MS Nurse support). SMART intervention involves completing a series of logic problems, which are designed to train skills that scaffold complex cognition. Group 2: Receives usual care alone. Group 3: Receives a 'control' intervention online - plus usual care. Baseline measures will be re-administered at three- and six-months post-randomisation. Researchers and patient-partners (people with personal experience of MS, who will act as co-researchers) will also interview 30 participants about their experience of the study and treatment. All qualitative data will be transcribed and thematically analysed in terms of a priori feasibility aims. Quantitative data will enable sample-size calculation for a definitive study and determine signal of efficacy.
Multiple sclerosis (MS) is an inflammatory autoimmune disease associated with an imbalance between pro- and anti-inflammatory markers (cytokines) resulting in a demyelinating and neurodegenerative disease. There is early evidence that spinal manipulation (chiropractic care) is better than control in influencing immune (cytokine) activity in asymptomatic participants, but few studies have been completed in participants with chronic inflammatory conditions, such as MS. The purpose of this project is to examine the immediate (after a single thoracic spinal manipulation treatment) and summative impact (after 8 thoracic spinal manipulation treatments occurring over 4 weeks) on pro-inflammatory (interleukin (IL) IL-1ß, IL-2, IL-6, Tumor necrosis factor-alpha) and anti-inflammatory (IL-4, IL-10) plasma cytokines 20 minutes and 2 hours after thoracic spinal manipulation in participants diagnosed with neuroinflammatory relapsing-remitting MS (RR-MS). Spinal manipulation treatment will be limited to the thoracic spine. Secondary outcomes will include determining the impact of 8 thoracic spinal manipulations on fatigue, cognitive processing speed, pain, depression, sleep, and motor function through questionnaires and performance of various in assessments such as the timed 25 foot walk test.
To access SAR442168 in the RMS populstion. Efficaty will be accessed by adjudicated relapse rate, disability progression, and MRI findings of disease activity.
Multiple sclerosis (MS) typically afflict young people in their twenties, when they start a career and establish a family. The disease thus imposes a severe impact on quality of life and heavy economic burdens on society. Critical barriers to progress in the field are the lack of knowledge of relevant immune cell subsets driving the pathology and the targets of the immune response within the central nervous system. In this project, we will test the hypothesis that a subgroup of MS patients is defined by a genetically determined B cell response against specific antigenic epitopes. The hypothesis is based on our recent, pioneering results showing that approximately half of MS patients have a restricted population of B cells in the cerebrospinal fluid defined by polymorphisms in the constant heavy-chain of the immunoglobulin B cell receptor, the G1m1 allotype. Here, we aim to characterize the G1m1 B cells, to disentangle the genetic basis of the B cell response, and to identify the molecular targets.
This study examines the feasibility and preliminary effects of user-centered exergames (video game-based physical exercise) in persons with multiple sclerosis (PwMS). The user-centered exergames were developed within a interdisciplinary team to meet the requirements of the end-users. The individualized exergames were designed for the Dividat Senso, a pressure sensitive plate connected to a personal computer and a frontal screen. This concurrent motor-cognitive training aims to improve motor and cognitive functions in an ecological valid setting. The cognitive functions are triggered by specific stimuli in the game scenarios. The video games are controlled via specific (whole body) movements as steps, weight shifting, jumps, and arm movements. The training focus is mainly on balance and coordination as well as executive functions and attention. Furthermore, the meaningful games (colorful and appealing visuals) were designed to motivate the players to move. Participants are allocated to the either the intervention group or the control group (quasi-randomization). Participants in the intervention group perform 16 training session over a period of 4 to 8 weeks (depending on in- or out-patient). One training session lasts between 15-25 minutes. Since the difficulty of the games is adaptive to the ability level of each participant, they should neither be over- nor under-challenged. Participates in the control group continue their normal daily routine over 8 weeks. Measurements are performed before, in-between, and after the intervention period to assess feasibility parameters as well as motor and cognitive functions in all participants.