View clinical trials related to Motor Neuron Disease.
Filter by:Amyotrophic Lateral Sclerosis (ALS) is a progressive neurodegenerative disease that targets motor neurons. Prognosis is invariably fatal within 3-5 years since manifestation of the disease. Despite improved understanding of the mechanisms underlying ALS, the treatment remains essentially only supportive and focused on symptoms relief. Over the past few years, stem cell research has expanded greatly as a tool for developing new therapies to treat incurable diseases. Stem cell therapy has been shown as promising in several animal ALS models and human clinical trials.
STUDY OVERVIEW Brain injury can result in a loss of consciousness or awareness, to varying degrees. Some injuries are mild and cause relatively minor changes in consciousness. However, in severe cases a person can be left in a state where they are "awake" but unaware, which is called unresponsive wakefulness syndrome (UWS, previously known as a vegetative state). Up to 43% of patients with a UWS diagnosis, regain some conscious awareness, and are then reclassified as minimally conscious after further assessment by clinical experts. Many of those in the minimally conscious state (MCS) and all with unresponsive wakefulness syndrome (UWS) are incapable of providing any, or consistent, overt motor responses and therefore, in some cases, existing measures of consciousness are not able to provide an accurate assessment. Furthermore, patients with locked-in syndrome (LIS), which is not a disorder of consciousness as patients are wholly aware, also, struggle to produce overt motor responses due to paralysis and anarthria, leading to long delays in accurate diagnoses using current measures to determine levels of consciousness and awareness. There is evidence that LIS patients, and a subset of patients with prolonged disorders of consciousness (DoC), can imagine movement (such as imagining lifting a heavy weight with their right arm) when given instructions presented either auditorily or visually - and the pattern of brain activity that they produce when imagining these movements, can be recorded using a method known as electroencephalography (or EEG). With these findings, the investigators have gathered evidence that EEG-based bedside detection of conscious awareness is possible using Brain- Computer Interface (BCI) technology - whereby a computer programme translates information from the users EEG-recorded patterns of activity, to computer commands that allow the user to interact via a user interface. The BCI system for the current study employs three possible imagined movement combinations for a two-class movement classification; left- vs right-arm, right-arm vs feet, and left-arm vs feet. Participants are trained, using real-time feedback on their performance, to use one of these combinations of imagined movement to respond to 'yes' or 'no' answer questions in the Q&A sessions, by imagining one movement for 'yes' and the other for 'no'. A single combination of movements is chosen for each participant at the outset, and this participant-specific combination is used throughout their sessions. The study comprises three phases. The assessment Phase I (sessions 1-2) is to determine if the patient can imagine movements and produce detectable modulation in sensorimotor rhythms and thus is responding to instructions. Phase II (sessions 3-6) involves motor-imagery (MI) -BCI training with neurofeedback to facilitate learning of brain activity modulation; Phase III (sessions 7-10) assesses patients' MI-BCI response to closed questions, categorized to assess biographical, numerical, logical, and situational awareness. The present study augments the evidence of the efficacy for EEG-based BCI technology as an objective movement-independent diagnostic tool for the assessment of, and distinction between, PDoC and LIS patients.
This study aims to evaluate the safety of a wireless implantable neurodevice microsystem in tetraplegic patients, as well as the efficacy of the electrodes for long-term recording of neural activities and the successful control of an external device.
Patients with motor neurone disease (MND) typically experience relentless motor decline and die within three years of symptom onset from respiratory muscle weakness. There are currently no effective therapies and the discovery of novel therapies is hampered by the lack of a sensitive disease biomarker. Consequently, there is a huge drive to discover novel biomarkers, which can reliably track disease progression over time. These can then be incorporated into clinical drug trials to expedite effective drug discovery. Muscle fasciculations represent the hyperexcitability of diseased motor neurons and are almost universally present from the early stages of MND. The investigators predict that the site, frequency and shape of fasciculations might provide a sensitive measure of disease progression in an individual. In order to calibrate this technique, the investigators will conduct a 12-month longitudinal study, recruiting 24 patients from the King's College Hospital Motor Nerve Clinic, comprising a mixture of patients with MND and those with benign fasciculation syndrome. Patients in this latter group have fasciculations but do not develop weakness and have normal lifespans. They are therefore an optimal control group. At each visit, the investigators will take resting HDSEMG recordings from all four limbs and perform standard clinical measures of disease progression. The investigators will also monitor the decline in motor unit number using a newly validated neurophysiological technique, called Motor Unit Number Index (MUNIX).
The research is aimed to explore the needs of clinical patients and their caregiver,so as to provide suggestions to the designer of the communication system.
The research is aimed to asses the validity of the communication system improving the quality of life and the degree of sanctification of clinical patients and their caregiver.
This is a Phase III, multi-centre, randomized, double-blind, placebo-controlled, parallel-group study to evaluate Safety and Efficacy of Tauroursodeoxycholic (TUDCA) as add-on Treatment in Patients Affected by Amyotrophic Lateral Sclerosis (ALS).
The study was a non-randomized open label pilot study. It was an observational design conducted at one (1) site in the US. All enrolled subjects received treatment with the MN4000. This pilot study evaluated subject satisfaction with the therapy and adherence to the therapy during the 90-day treatment period, and also collected clinical outcome data. Outcomes were assessed before, during and after the MN4000 treatment period.
To evaluate if transcranial magnetic stimulation can be used as a biomarker in Amyotrophic Lateral sclerosis (ALS).
Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disorder and therapeutic options are limited. The rho kinase (ROCK) inhibitor Fasudil was shown to be neuroprotective, induced axonal regeneration and improved survival and behavioral outcome in models of ALS and other neurodegenerative diseases. The aim of this phase IIa, multi-center and double-blind study is to analyze the safety, tolerability and efficacy of fasudil in two different doses compared to placebo in approximately 16 trial sites in Germany, France and Switzerland. Intravenous application of fasudil will be performed in 80 patients and placebo in 40 patients two times daily for 20 treatment days. The hypothesis is that fasudil is safe and well-tolerated and its application will significantly improve the clinical outcome in patients with ALS.