Active clinical trials for "Multiple Sclerosis, Chronic Progressive"

This study is a single cohort, central registration system, all-case, open-label, multicenter observational study in patients using Mayzent for the indication of secondary progressive multiple sclerosis.

This project is to: Quantify differences in axonal integrity and organization in aMS versus naPMS patients. Quantify changes in axonal integrity and organization in aMS versus naPMS patients over a two-year period. Validate the combination of imaging parameters that best differentiate aMS versus naPMS patients using histopathology.

This study is being conducted to investigate risk factors for disability progression in Multiple Sclerosis and related disorders (MSRD). The primary goal is to assess whether combining information from visual assessment, blood markers, as well as historical and ongoing longitudinal MRIs of the brain, orbit (the part of the skull where eyes are located), and/or spinal cord can predict changes in quantitative disability measures related to MSRD and neurological disease.

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.

Prospective, single center, open label, phase I/IIa escalating dose study. To evaluate the safety and efficacy of escalating doses of SCM-010 in subjects with SPMS.

The purpose of this project is to study genetic determinants of mitochondrial impairment in primary progressive multiple sclerosis. Specific aims are: 1) identify mitochondrial-related pathways, inherited and somatic mitochondrial DNA mutations associated to primary progressive multiple sclerosis, 2) functionally assess the identified genetic alterations.

In multiple sclerosis (MS) brains, inflammation induces specific abnormalities of synaptic transmission, collectively called inflammatory synaptopathy. Such synaptopathy consists in unbalanced glutamatergic and GABAergic transmission and in remarkable changes in synaptic plasticity, causing excitotoxic neurodegeneration and impairing the clinical compensation of the ongoing brain damage, thereby exacerbating the clinical manifestation of the disease. In progressive MS (PMS), synaptopathy is characterized by pathological potentatiation of glutamate-mediated synaptic up-scaling (Centonze et al., 2008; Rossi et al., 2013) and loss of long-term synaptic potentiation [LTP (Weiss et al., 2014)], both caused by proinflammatory molecules (released by microglia, astroglia, and infiltrating T and B lymphocytes) (Malenka et al., 2004; Di Filippo et al., 2017; Stampanoni Bassi et al., 2019). The combination of increased up-scaling and decreased LTP has a significant impact on the clinical manifestations of PMS, often presenting with signs and symptoms indicating length-dependent degeneration of neurons of the corticospinal tract. Altered LTP expression impairs brain ability to compensate ongoing neuronal loss (Stampanoni Bassi et al., 2020), and pathological TNF-mediated up-scaling may directly promote excitotoxic damage and neurodegeneration (Rossi et al., 2014). In addition, up-scaling and LTP are mutually exclusive at a given synapse through a mechanism of synaptic occlusion (i.e., pre-existing up-scaling saturates and prevents subsequent LTP expression), further promoting neurodegeneration by preventing the pro-survival effect of LTP, the induction of which activates intracellular anti-apoptotic pathways (Bartlett & Wang, 2013). It follows that a neuromodulation approach that can chronically (over several months) dampen up-scaling expression in the primary motor cortex (M1) of PMS patients could be beneficial by preventing excitotoxic neurodegenerative damage triggered by up-scaling itself (Centonze et al. 2008, Rossi et al. 2014), and also by promoting LTP induction and LTP-dependent functional compensation of deficits, thereby reducing the speed of the neurodegeneration process through increased LTP-dependent neuronal survival and preservation of dendritic spines (Ksiazek-Winiarek et al., 2015). Our study aims to test whether transcranial static magnetic field stimulation (tSMS) could represent such a therapeutic approach, as recently proposed in patients with amyotrophic lateral sclerosis (ALS) (Di Lazzaro et al, 2021). Forty (40) ambulatory patients with PMS, presenting with the ascending myelopathy phenotype of the disease, will be recruited at the MS Center of the Unit of Neurology of the IRCCS Neuromed in Pozzilli (IS). In this randomized, sham-controlled, double-blind, within-subjects, cross-over study (allocation ratio 1:1), we will test the ability of repeated sessions of tSMS applied bilaterally over the M1 to safely reduce disability progression in patients with PMS. Patients will be randomly assigned to either real or sham tSMS. Each patient will participate in two experimental phases (real or sham stimulation). Each patient will self-administer tSMS over right and left M1, two session per day, 60 minutes each. The order will be randomly established and counterbalanced across participants. Both investigators and participants will be blinded to stimulation parameters. In the "real stimulation" phase, tSMS will be applied for 120 minutes each day, at home, for 12 consecutive months. In the "sham stimulation" phase, sham tSMS will be delivered with non-magnetic metal cylinders, with the same size, weight and appearance of the magnets. Clinical evaluations, including the Multiple Sclerosis Functional Composite measure (MSFC) will be performed before, during and after each experimental phase ("real" and "sham"). In addition, blood levels of neurofilaments, excitability and plasticity of M1, and MRI measures of cortical thickness will be measured before, during and after each stimulation phase.

This clinical trial aims to demonstrate that metformin can prevent clinical disability in patients with progressive MS by stopping or slowing down neurodegeneration by enhancing endogenous remyelination. Patients will continue their DMT treatment: metformin or placebo will be used as add-on study treatment.

The aim of the study is to analyze the effects of Nordic Walking and free walking in the clinical-functional, postural balance, motor control, muscular echographic quality, and gait analysis (pendulum gait mechanism), in people with Multiple Sclerosis.

Given that up to 70% of people with secondary progressive MS are cognitively impaired, the search for effective treatments is considered a priority by people living with the disease. This proposal will address the effectiveness of cognitive rehabilitation (CR) and exercise, either alone, or in combination in this regard. A team of MS researchers has been assembled from the USA, Canada, the United Kingdom, Italy, Denmark, Germany and Belgium for this. A total of 360 people with progressive MS will make up the sample. Brain MRIs will be undertaken in a third of the sample before and after the 12 weeks of treatment to document the functional changes that are expected to occur with symptom improvement.