Active clinical trials for "Amyotrophic Lateral Sclerosis"

The HEALEY ALS Platform Trial is a perpetual multi-center, multi-regimen clinical trial evaluating the safety and efficacy of investigational products for the treatment of ALS. Regimen F will evaluate the safety and efficacy of a single study drug, ABBV-CLS-7262, in participants with ALS.

The primary objective of this study is to document and describe the effects of a personalized rehabilitation program for patients with SOD1 ALS participating in the tofersen expanded access program. Participants currently receiving tofersen treatment will be referred to outpatient physical and/or occupational therapy. Participants will have an initial assessment performed and an individualized rehabilitation program will be prescribed. Each participant is encouraged to follow the prescribed recommendations that will include scheduled outpatient therapy sessions, functional assessments, and/or a home-based rehabilitation program. Functional assessments will be done at a minimum of every three months.

Amyotrophic lateral sclerosis (ALS) is a disabling and rapidly progressive neurodegenerative disorder. There is no treatment that significantly slows progression. Our project aims to find new biomarkers in MRI at three levels: cerebral, medullary and muscular. These markers could allow an earlier diagnosis of the disease by showing more specific lesions of ALS and to quantify these lesions to measure the progression of the disease. This study will use advanced Magnetic Resonance Imaging (MRI) techniques High field (3T) and very high field (7T) MRI. Results from neurological and electrophysiological tests will be compared to the MRI. Subjects will be recruited from ALS center of Marseille, France. MRI will be done on ALS patients at baseline, at 3 month and at 6 month intervals.

The primary objective is to evaluate the safety and tolerability of AMX0035 over 108 weeks of open label treatment for participants previously enrolled in Study A35-004 (PHOENIX).

Determine if Telehealth intervention can allow/empower a caregiver (who is untrained) to effectively implement and utilize a Brain-Computer Interface for communication with a participant who is "Locked in" following progression of Amyotrophic Lateral Sclerosis and other conditions.

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.

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease that affects central and peripheral motor neurons. None of the clinical trials conducted have been clearly successful and the disease remains incurable, putting patients' vital prognosis at risk in the medium term. An alteration of the basal metabolism leading to hypermetabolism has been described in several articles in the literature. The causes of this hypermetabolism and the precise exploration of the metabolic pathways involved are still poorly understood. The fibroblasts of ALS patients may be the site of some metabolic disturbances in this disease with a hypothetical specific basal metabolic profile. These cells are adapted to different metabolic explorations such as omnic approaches. Superficial skin biopsy followed by fibroblast culture can provide a considerable biobank. This cellular richness will allow us, in ALS patients and their controls, to perform metabolomic and lipidomic approaches, as well as the quantification transcriptomic approach."

The Synchron motor neuroprosthesis (MNP) is intended to be used in subjects with severe motor impairment, unresponsive to medical or rehabilitative therapy and a persistent functioning motor cortex. The purpose of this research is to evaluate safety and feasibility. The MNP is a type of implantable brain computer interface which bypasses dysfunctional motor neurons. The device is designed to restore the transmission of neural signal from the cerebral cortex utilized for neuromuscular control of digital devices, resulting in a successful execution of non-mechanical digital commands.

The purpose of this study is to obtain preliminary device safety information and demonstrate proof of principle (feasibility) of the ability of people with tetraplegia to control a computer cursor and other assistive devices with their thoughts.

Individuals suffering from tetraplegia as a result of cervical spinal cord injury, brainstem stroke, or amyotrophic lateral sclerosis (ALS) cannot independently perform tasks of daily living. In many cases, these conditions do not have effective therapies and the only intervention is the provision of assistive devices to increase independence and quality of life. However, currently available devices suffer from usability issues and are limiting for both the patient and caregiver. One of the most progressive alternative strategies for assistive devices is the use of brain-computer interface (BCI) technology to translate intention signals directly from sensors in the brain into computer or device action. Preclinical primate research and recent human clinical pilot studies have demonstrated success in restoring function to disabled individuals using sensors implanted directly in motor regions of the brain. Other preclinical primate research has demonstrated effective intention translation from sensors implemented in cognitive regions of the brain and that this information complements information from the motor regions. The current proposal seeks to build on these studies and to test the safety aspects related to implanting two sensors, each a microelectrode array, into both the motor and cognitive regions of the brain in motor impaired humans. Secondary objectives include feasibility evaluation of the complementary sensors in their ability to support effective assistive communication.