Active clinical trials for "Huntington Disease"

Huntington disease (HD, 1.3/10 000) is an autosomal dominant disease due to an abnormal expansion of CAG triplets in HTT gene. Several pathophysiological mechanisms have been evoked, including an alteration of the signaling pathway of the Brain Derived Neurotrophic Factor (BDNF), a neurotrophic factor involved in the survival of neurons (striatal and hippocampal) and synaptic plasticity. BDNF is synthesized at the level of cortical neurons and transported, through the axonal transport in which the Htt is involved, to the nerve endings; it's then secreted in response to excitatory synaptic activity, especially at the level of glutamatergic synapses. Besides, at the postsynaptic level it binds with great specificity to TrkB receptors (tropomyosin-related kinase receptors B) with a neuroprotective effect on dendritic and axonal growth and an increase in synaptic plasticity, especially at the level of the striatum and the hippocampus. BDNF is decreased in the brain of animal models, as well as in patients with HD; the alteration of this pathway would occur in the early stages of the disease. In the context of concomitant multiple treatments, the BNDF pathway may be one of the therapeutic targets of HD. Moreover, in HD it remains essential to detect biological markers representative of the different pathogenic pathways that can be tested in vivo in humans to confirm the hypotheses developed at the level of basic research; these biomarkers could subsequently become biomarkers of disease progression and/or biomarkers of therapeutic efficacy of potential targeted treatments. Therefore, this study aims to characterize potential biomarkers of the BNDF pathway in plasma and CSF in subjects with HD and to confirm the importance of this pathogenic mechanism in vivo in humans.

A Phase I/II Dose-Finding Study to Evaluate Striatal Administration of AB-1001 (previously BV-101) in Adults with Early Manifest Huntington's Disease

The proposed study is to evaluate the effectiveness of ExAblate Transcranial MRgFUS as a tool for creating a unilateral lesion in the Vim thalamus or the globus pallidus (GPi) in patients with treatment-refractory symptoms of movement disorders.

Mild cognitive impairment associated with movement disorders occurs in up to one third of patients in early stages of the disease, and confers an increased risk of developing dementia. Non-pharmacological interventions to improve cognition have so far been based on computer-based cognitive stimulation and rehabilitation programs. These interventions base their mechanism of action on neuroplasticity and how improvements in cognitive function will generalize to functional improvement. Despite having shown certain indicators of efficacy in previous exploratory studies and clinical trials, cognitive rehabilitation continues to show insufficient evidence and requires further study. To date, there are no previous studies using immersive virtual reality (IVR) to improve cognition. Both IVR and cognitive stimulation are based on the premise that they allow the simulation of ecological environments for rehabilitation than conventional rehabilitation, as well as being more efficient by allowing control of extraneous variables and providing safe spaces for patients. The only PD rehabilitation studies that have been conducted using IVR aimed to improve gait and balance disturbances compared to conventional physiotherapy treatment or non-immersive virtual reality (NIVR). We hypothesize that a cognitive rehabilitation program using IVR or computer-mediated cognitive stimulation could have a greater beneficial effect on the cognitive status of patients with cognitive impairment associated with movement disorders compared to other modalities such as music therapy, delaying the worsening of cognitive functions.

This is the first study of branaplam in adults with Huntington's Disease (HD) to determine the correct dose required to lower mutant huntingtin protein (mHTT) levels in the cerebrospinal fluid (CSF) to a degree expected to be efficacious over longer periods of time.

Cellavita-HD is a stem-cell therapy for Huntington's Disease. Open label, single treatment, extension study for long-term safety and efficacy evaluation of Cellavita-HD intravenous administration in Huntington's disease patients who participated of ADORE-DH trial.

This study will evaluate the efficacy and safety of pridopidine 45mg twice daily (BID) in patients with early stage manifest Huntington Disease (HD).

The purpose of this study is conduct a pilot open trial of a web-based cognitive bias modification intervention to reduce anxiety symptoms in persons with Huntington's disease and persons with Parkinson's disease.

Time processing is fundamental to survival and goal reaching in humans. Different time scales (seconds, minutes, and beyond) are processed through specific cognitive processes involving different neural representations. It is generally agreed that time scale in seconds-to-minutes range named "interval timing" would be anatomically linked to the striatum. Indeed, it is possible to demonstrate a deficit of interval timing processes in patients suffering from striatal damage (Huntington's disease). However, recent findings show involvement of a second brain structure, the hippocampus, in interval timing processing in the minutes range, suggesting an interaction between the striatum and hippocampus. Presumably, patients with hippocampal damage (Alzheimer's disease) would specifically show a decrease in performance for this minutes-range time scale. This study aims to provide a better understanding of the role of the striatum in the treatment of time and its interactions with other brain structures such as the hippocampus. More specifically, it is unclear whether the striatum plays a platform role that would always be involved regardless of the time scale, as suggested by the unified model of time or whether different brain structures is solicited according to the time scale, as suggested by the modular system model. In order to elucidate these issues, a potential double dissociation between brain structures and time scales will be tested.

NAC-preHD is a phase II randomized placebo controlled study of oral NAC among premanifest HD gene expansion carriers, with clinical and radiological outcome at three years.