Active clinical trials for "Multiple Sclerosis"

We are studying this investigational drug treatment, comparing it with placebo, to evaluate whether it is effective in reducing the number of MRI lesions with a minimum number of side effects. The investigational drug will be administered in the clinic weekly for 5 injections (induction phase) then monthly for 8 additional injections (maintenance phase). Approximately 150 male and female patients (100 active and 50 placebo), aged 18 to 55 years, with relapsing MS and at least one but no more than 10 total Gd-enhancing lesions on cranial MRI scans during the run-in phase will be randomized into this study.

This study will examine the safety of Zenapax (daclizumab) in patients with multiple sclerosis (MS). MS is thought to be caused by an over-reactive immune response. T-lymphocytes (cells of the immune system), are thought to damage myelin, a substance that covers the nerve and parts of the spinal cord and is damaged in patients with MS. Interleukin-2 is a natural substance in the body that is necessary for the growth of T-lymphocytes. Zenapax is a genetically engineered antibody that blocks the activity of interleukin-2 and thus interferes with the growth of lymphocytes. Therefore, Zenapax may prevent some of the damage to myelin that occurs in multiple sclerosis. Patients between 18 and 65 years of age with relapsing remitting MS may be eligible for this study. Patients with secondary-progressive or primary progressive MS may not participate. Candidates will be screened with a complete neurological and medical evaluation and review of medical records. Participants will undergo the following tests and procedures: Baseline evaluation: Participants have four magnetic resonance imaging (MRI) scans over a 3-month period to assess disease activity. For the MRI scans, the patient lies on a table that slides into the scanner - a narrow metal cylinder with a strong magnetic field. Scanning time varies from 20 minutes to 3 hours, with most scans lasting between 45 and 90 minutes. Only patients with activity at or above a certain level are eligible to continue with the treatment phase of the study. Zenapax treatment: Patients receive intravenous (through a vein) infusions of Zenapax. The first two infusions are 2 weeks apart, followed by 13 monthly infusions. MRI scans: Patients undergo MRI scanning before every infusion to evaluate disease activity and identify new brain lesions. Blood and urine tests: Blood and urine samples are collected at each clinic visit for routine laboratory evaluations, immunologic study, and genetic testing to determine a predisposition for responding to Zenapax treatment. Lumbar puncture (spinal tap): This procedure will be done during the last month before starting treatment and during the seventh month of treatment to examine immune changes that occur in the cerebrospinal fluid (CSF), which circulates through and surrounds the brain and spinal cord. A local anesthetic is given and a needle is inserted in the space between the bones in the lower back where the CSF circulates below the spinal cord. A small amount of fluid is collected through the needle. Skin test: A needle is placed just under the skin is done to assess the patient's immune status to common antigens such as tetanus, mumps and candida. Lymphocytopheresis: Lymphocytes are collected three times - once during the last month of baseline before starting treatment, once during the fifth month of treatment, and once during the last month of treatment - for immunologic study. Blood is collected through a needle in an arm vein in a similar way to donating blood. The blood flows from the vein through a catheter (plastic tube) into a machine that separates it into its components by centrifugation (spinning). The lymphocytes are removed and the rest of the blood (red cells, plasma and platelets) is returned to the body, either through the same needle or through another needle in the other arm.

To assess the safety and efficacy of 10 milligram (mg) twice a day (b.i.d.) Fampridine-SR in patients diagnosed with multiple sclerosis (MS), in a double-blind, placebo-controlled, parallel group study.

The purpose of this study is to determine the effects, both good and bad, of IPX056 on subjects and their spasticity. This study will also determine the relationship between the amount of IPX056 in blood and the effects on spasticity. Lastly, this study will determine how long IPX056 affects spasticity.

The purpose of the study is to show that individuals treated with Fampridine-SR tablets are significantly more likely to have consistent improvements in their walking than those treated with placebo tablets.

The primary purpose of this study is to develop, implement and conduct a preliminary evaluation of a new service for people who are severely affected by multiple sclerosis. The investigators conducted open interviews with patients, families and staff, plus a literature review to model and pilot this new service. Then the investigators developed, tested and ran the service and will evaluate it using a randomised controlled trial, where people affected by MS are randomised to either receive the service immediately (fast track group) or after a three month wait (standard best practice). This methodology follows that of the Medical Research Council (MRC) framework for the development and evaluation of complex services and treatments. The investigators interview people and their carers in the fast track and standard practice groups, and followed them over time. This phase of trial enables us to calculate sample size and test proof of concept for a full randomised trial. However, our working hypothesis was that there would be no difference between those people who received the fast track service or the standard best practice in terms of symptom controlled, and carer needs.

This study will compare an implant with the technique of sensory training to determine which method may improve the ability to swallow and reduce the risk of choking. Many people with a brain injury or neurological disorders experience difficulty in swallowing. Past studies have shown that an electrical pulse applied to muscles or an increase in sensory stimulation to the throat can help. Patients ages 18 to 90 who have had a brain injury or neurological disorder and who have had trouble swallowing for 6 months or longer may be eligible for this study. Patients will undergo a physical examination, pregnancy test, and exam by a throat and speech physician. Fiber-optic endoscopic evaluation of swallowing with sensory testing involves a flexible tube passed through the nose to the back of the throat to allow observation of the voice box. Videofluoroscopy, an X-ray of the head and neck, will be done while patients swallow. Patients experiencing trouble with the upper esophagus may undergo additional procedures, including manometry to measure pressure changes in the back of the throat, and reevaluation through the fiber-optic tube. Patients in this study will have a magnetic resonance imaging (MRI) scan, which uses a strong magnetic field to obtain images of the body. Patients will lie on a table that slides into the enclosed tunnel of the scanner. The scan will take 20 to 25 minutes. Patients will be assigned randomly to one of two groups: the intramuscular group, to have a stimulation device implanted in the neck, and the vibrotactile group, to receive a vibrotactile stimulator. All patients will have 10 training sessions with their devices, plus follow-up. Those patients in the first group will undergo surgery, under general anesthesia, for the implant. Three weeks following the implant procedure, patients will come to NIH to have the stimulator turned on and programmed and to learn how to use the device. Those patients in the second group will have about 2 to 3 weeks of training in using a vibrotactile device, and then they will take it home to use. All patients will return to NIH at 3 months to ensure proper use of the devices, and they will visit for follow-up at 6 months and 12 months for tests and questionnaires. ...

The purpose of this investigation is to determine the effect of Whole Body Vibration Therapy (WBV) on balance in a participant with multiple sclerosis (MS) related balance deficits as measured by the NeuroCom Balance Master, the Sapphire IIME EMG Device and the Kurtzke Expanded Disability Status Scale (EDSS) and the Berg Balance Score.

Our goal is the elucidation of the mechanisms of action of autologous hematopoietic stem cell transplant (HSCT) and immunoablation by high-dose cyclophosphamide in multiple sclerosis (MS). The molecular pathogenesis of multiple sclerosis is poorly understood although T-cell mediated immune destruction of myelin is thought to be an important element. We hypothesize, and the results of previous studies suggest, that radical immuno-ablation characterized by a profound T cell depletion can arrest the progression of disease. Patients with MS with poor prognosis based on the rate of progression and refractoriness to approved treatments (interferon-beta, glatiramer acetate) will be enrolled in clinical trials at the collaborating institution (NWU-Dr. R. Burt; Dr. D Kerr, JHU) and will receive either immune ablation with cyclophosphamide and the antibody Campath-1 followed by reconstitution with autologous peripheral blood stem cells, a procedure similar to autologous bone marrow transplantation, or high-dose cyclophosphamide treatment without stem cell rescue. While the overall treatment-related mortality worldwide is approximately 10%, the collaborating institution and investigators have an outstanding safety record in performing the procedure with no fatal adverse events after having transplanted more than 30 transplants with a previously more aggressive regimen than the one that is in use now. The underlying rationale for this treatment is that immuno-ablation could eliminate myelin-reactive T cells which, in disease-susceptible individuals, may have been activated by previous exposure to environmental agents or other acquired mechanisms of immune dysregulation. In the proposed study we plan to address whether HSCT or immunoablation without stem cell rescue act beneficially in MS via the eradication of myelin-reactive T cells and reconstitution of a functional and non-autoimmune immune repertoire. To achieve this goal, we will compare peripheral blood T cell reactivities to myelin antigens before and after the treatment in 34 patients with MS. In parallel, to identify potential disease-mediating cells that do not recognize these myelin antigens, we will search for clonally expanded cells in the blood of MS patients before treatment employing molecular analysis of T cell receptor repertoire. Expanded T cell clones will be tracked during post-transplant follow-up of patients. If the eradication of certain clonotypes resulting from immuno-ablation correlates with disease remission, we will attempt to isolate these cells in culture from pre-treatment samples and determine their specificity using combinatorial peptide libraries. We would use the same approach in case of reappearance or new clonal expansions concomitant to disease relapses. We will combine these studies with a broader, unbiased approach that employs microarray technology to identify potential changes in gene expression profiles. This approach may also lead to the identification of novel therapeutic targets for pharmacological treatment.

Determine the efficacy, safety, and tolerability of BG00012 in MS patients.