View clinical trials related to Multiple Sclerosis.
Filter by:Abstract Introduction: Postural control disorders are the most common motor disorder associated with multiple sclerosis. Objective: The aim of this study is to demonstrate the potential for improvement of postural control, motion performance and quality of life in patients with multiple sclerosis who are performing a special neurorevolutionary balancing program. Intervention: The treated group (n = 15) performed five times a week for the treatment we defined. (60 minutes per day). The experimental group performed movements using the Xbox 360 and Kinect consoles. The study team participated in 25 sessions, five times a week. The duration of treatment was 5 weeks.The MStp group (n=14) participated in a 5-week physiotherapy course. The general treatment consisted of strengthening, stretching and walking correction. During the 5-week period, 25 patients attended training. One treatment takes 60 minutes. Sensory Organisation Test / Body Sway at the end of the baseline and treatment protocol is used to evaluate each patient. The quality of life mapping was measured by subjective tests (EQ-5D-5L, ADL). To assess the depressive state, a Beck depression questionnaire was used. Balance and motion performance were used by the Berg Balance Test and 6Minutes Walk Test. The results were compared with the control group results (n = 14) and showed improvement in overall balance and motion performance.
This study aims to identify the safety and tolerability of bile acid supplementation in patients with progressive Multiple Sclerosis (MS). Participants will also be assessed for an impact of the bile acid on their immune system and gut microbiome. Half of the participants will receive the bile acid tauroursodeoxycholic acid (TUDCA) and half will receive placebo. The investigators believe participants who take TUDCA will have normalization of blood bile acid levels, a normalization of abnormal immune response and a normalization of the gut microbiome.
Increasing evidence favours exercise therapy as an efficient tool to counteract inactivity related secondary symptoms in MS. Furthermore, exercise therapy may affect MS-associated muscle contractile and energy supply dysfunctions. So far, low to moderate intensity exercise rehabilitation has shown to induce small but consistent improvements in several functional parameters. High intensity exercise training in MS seems to further improve this. However, although results are promising, impairments in both muscle contraction and energy supply probably attenuate therapy outcome. In keeping with the above described physiological role of skeletal muscle carnosine and because muscle carnosine content may be lower in MS, the primary aim of the present project is to investigate whether carnosine loading improves exercise therapy outcome (exercise capacity, body composition) and performance in MS. If the latter hypothesis can be confirmed, muscle carnosine loading could be a novel intervention to improve exercise capacity and muscle function in this population.
The aim of this study is to measure the difference in the walking performance when functional electrical stimulation (FES) is on and off in people with MS that present foot drop under different 'real life' conditions, i.e. walking while doing another task that requires your attention and after been physically tired
The primary objective of the study is to evaluate the adherence to the treatment with interferon beta-1b, in patients diagnosed with isolated syndrome (CIS), relapsing-remitting multiple sclerosis (RRMS), or secondary progressive multiple sclerosis (SPMS) who had more than 6 months in treatment.
Multiple Sclerosis (MS) is characterized by episodic attacks in which there are sharp declines in physical function. Although neurorehabilitation is the most promising clinical strategy for motor recovery in patients with MS, treatment responsiveness and outcomes are mixed. This is perhaps because each individual with MS has a different capacity to improve with rehabilitation, and this capacity may be based on a variety of baseline factors, such as disease duration, motivation, cognitive status and integrity of underlying brain structures. A better understanding of what "key ingredients" facilitate relearning of motor skills during neurorehabilitation is critically needed. Much of the focus of rehabilitation is on relearning motor skills. The initial stage of learning a motor skills often requires explicit concentration on the details of the movement. As one becomes more proficient in the motor skill, it becomes less attention-demanding and more automatic. Those who can perform motor skills more automatically will be better able to manage the additional demands of a secondary task; thus, capacity for dual-task performance can be used as an index of automaticity. Individuals with MS experience demyelination that impacts brain areas critical for motor learning. However, the specific clinical and pathological variables that facilitate capacity for motor learning in people with MS have not been identified. Identification of such variables could be leveraged to determine a patient's capacity to benefit from neurorehabilitation at the outset and potentially to maximize motor learning during rehabilitation for people with MS. Thus, there is an urgent need to determine the key ingredients most strongly associated with successful relearning of motor skills in MS patients. Our long-term goal is to develop individualized rehabilitation for persons with MS. Our overall objective in this application is to identify clinical and pathological variables associated with successful relearning of motor skills. Our central hypothesis, based on preliminary data, is that the ability to learn to make new movements automatically occurs over a dynamic range and is a function of available cognitive processing speed and the integrity of corticospinal tract and superior cerebellar peduncles. We will test these hypotheses by recruiting 146 individuals with relapsing-remitting MS to participate in a mechanistic trial not designed to be a therapeutic intervention. Participants will complete baseline testing (including neuroimaging, cognitive testing and dual-task performance) followed by 4 consecutive days of training on a challenging balance task. After a 2-day washout period, participants will return for post-testing (including dual-task performance on a dual-balance and working memory task). The rationale for the proposed research is that identification of key ingredients associated with the capacity for motor skill acquisition would allow for more targeted rehabilitation programming, thereby improving patient outcomes and reducing health care expenses. At the completion of the proposed research, we expect to understand more about the capacity for individuals with MS to improve with motor skill training, and some of the key ingredients that help predict successful shift toward task automaticity, one critical component of successful neurorehabilitation. The results of this proposal will facilitate the development of predictors of motor recovery, needed to improve rehabilitation outcomes for individuals with MS and other neurodegenerative diseases.
The primary goal of this pilot study is to explore the feasibility of cyclic vibration (CV) of the lower extremity muscles to improve walking in individuals with gait deficits from multiple sclerosis (MS).
Multiple sclerosis (MS) affects approximately 2.3 million patients worldwide, with a global median prevalence of 33 per 100,000. MS is diagnosed at an average of 30 years and affects twice as many women as men. MS is traditionally diagnosed by the presentation of lesions of the central nervous system, disseminated in time and in space, proven by clinical examination and magnetic resonance imaging. Several anatomical parameters in the eye, both vascular and neural, have been found to be altered in MS patients. Because of its unique optical properties, the eye offers the possibility of the non-invasive assessment of both structural and functional alterations in neuronal tissue. As the neuro-retina is part of the brain, it does not come as a surprise that neuro-degenerative changes in the brain are accompanied by structural and possibly also functional changes in the neuro-retina and the ocular vasculature. The current study seeks to test the hypothesis that beside the known anatomical changes, also functional changes can be detected in the retina of patients with MS. For this purpose, flicker light induced hyperemia will be measured in the retina as a functional test to assess the coupling between neural activity and blood flow. Further, structural parameters such as retinal nerve fiber layer thickness and function parameters such as ocular blood flow and retinal oxygenation will be assessed and compared to age and sex matched controls.
OBJECTIVE To investigate neurodegeneration and demyelination in the central and peripheral nervous system in multiple sclerosis linked to disease progression and mechanisms that can explain different responses to Fampridine treatment in MS patients with walking disability. METHOD The study is a prospective cohort follow-up study with 98 participants with MS and walking disability. Participants are identified as responders or non-responders to Fampridine treatment prior to the study. Participants will undergo MRI of the cerebrum with lesion load quantification, neurophysiological tests comprised of motor evoked potentials and electroneurographic examination, blood samples examining KIR4.1 antibodies, brain derived neurotrophic factor (BDNF), myelin protein zero (MPZ), peripheral myelin protein 22 (PMP22), p75-nerve growth factor receptor (p75NGFR) and anti-myelin associated glycoprotein (anti-MAG). The presence of SORCS-3 gene mutation will also be examined, as will cerebrospinal fluid levels of myelin basic protein, neurofilament heavy and light chains. Functional test of Timed 25-foot walk test (T25FW) will identify response to Fampridine treatment. A functional test battery will further detail function of upper extremities and cognition. CONCLUSION This study will add to the understanding of neurodegeneration and demyelination in CNS and PNS in patients with MS having walking disability. This will impact clinical decision-making by improving organization of immunomodulatory treatment, identifying biomarkers thus facilitating earlier treatment and improving patient control, information and education.
Multiple Sclerosis (MS) is an autoimmune disorder of the central nervous system. In MS, inflammation is known to attack areas of the brain, spinal cord, and optic nerves; resulting in disability. Current MRI technology provides an adequate view of the impact of MS on the "white matter" of the brain, which contains many of the connections between neurons. Quantification of lesions in the white matter due to MS are a standard part of clinical trials and clinical care in MS. However, it has long been known that MS not only can affect the white matter, but also the "gray matter," which contains the majority of the nerve cells in the brain and can cause inflammation in the meninges (the protective tissue that surrounds the brain and spinal cord). Autopsy studies have shown that the inflammation seen in the meninges is driven by a B-cells, a subset of white blood cells and that meningeal inflammation may be responsible for damage to the gray matter of the brain. Ocrelizumab is a new treatment for multiple sclerosis. This medication works by targeting and destroying circulating B-cells. It is thought that this may reduce the level of meningeal inflammation in patients with multiple sclerosis. By reducing meningeal inflammation, this medication may result in less damage to the gray matter and subsequently less disability in MS patients. In this study, the investigators will evaluate the use of a method on 7 tesla (7T) MRI to identify inflammation in the meninges as a potential predictor of response to ocrelizumab treatment for multiple sclerosis. Further, the investigators will evaluate if this MRI technique can be used to monitor the long-term effect of the medication on meningeal inflammation and the development of damage to the gray matter of the brain.