View clinical trials related to Narcolepsy Type 1.
Filter by:Mind wandering is a state in which attention turns away from the external environment or current task to focus on internal thoughts (past experiences, future events, planned actions...). Humans are thought to spend at least one third of their waking lives in this state. Mind wandering can be assessed experimentally by investigating mental content during well-controlled tasks. In this case, task-unrelated thoughts likely to arise during tasks of varying cognitive demand are studied. Mind wandering (=task-unrelated thoughts) has a deleterious effect on cognitive performance in most paradigms, particularly those requiring sustained attention and executive control. However, this phenomenon could also have cognitive benefits, although knowledge on this issue remains limited. For example, it has been suggested that mind wandering could promote creativity, anticipation of future scenarios and prospective memory. In a recent behavioural study, we investigated the cost and benefit of mind wandering in an implicit visual-motor probabilistic learning task (ASRT - Alternating Serial Reaction Time Task). ASRT distinguishes between two fundamental processes: visuomotor performance and implicit statistical learning. While the former reflects visuo-spatial discrimination efficiency, the latter refers to the unintentional acquisition of probabilistic regularities of external inputs. Reduced visuo-spatial accuracy and faster but less accurate responses have been observed during periods of mind-wandering. On the other hand, mind-wandering was associated with enhanced statistical learning reflecting improved predictive processing. Whereas the study of the neural correlates of mind-wandering is constantly growing, the mechanisms triggering mind-wandering are far from being unravelled, but may involve sleep pressure. Thus, the frequency of mind wandering tends to increase after sleep deprivation or during attention-demanding cognitive tasks, during which neurophysiological markers of local sleep appear. These markers of sleep during wakefulness are frequently observed in hypersomnolence disorders. They are generally defined by the appearance of slow waves (typical of slow wave sleep, SWS). Nevertheless, sleep intrusions during wakefulness may not be limited to non-rapid-eye-movement (NREM) sleep but also concern REM sleep. REM sleep is the sleep state when the most intense forms of dreaming occur, and could therefore be phenomenologically similar to the reverie of mind wandering. Thus, daytime mental wandering could be triggered by intrusions of REM sleep during wakefulness. Patients with narcolepsy type 1 (NT1) exhibit frequent REM sleep onset during daytime wakefulness. The study of ASRT in this population therefore offers a unique opportunity to investigate the role of REM sleep intrusions in mind wandering. The hypothesis is that mind wandering would be observed more frequently during the ASRT task in NT1 patients (with REM sleep intrusions during wakefulness) than in patients with idiopathic hypersomnia (IH) (with NREM sleep intrusions during wakefulness) and patients with subjective hypersomnolence (little or no sleep intrusion). Furthermore, it could be possible that REM sleep-related mind wandering would be associated with impaired visuomotor performance in terms of accuracy, but improved predictive processing (probabilistic learning) compared to NREM sleep intrusions or no sleep intrusion during the task.
The purpose of this clinical trial is learn whether a behavioral (non-medication) treatment can reduce nightmares in adults with narcolepsy. All participants will receive the treatment and will complete three assessments. Half of the participants will receive the treatment after the first assessment, and half will receive it after the second assessment.
Narcolepsy type 1 (NT1) is a rare disease characterized by severe drowsiness, cataplexy, hypnagogic hallucinations, sleep paralysis, poor night sleep, and often obesity. NT1 is caused by irreversible loss of orexin (ORX)/hypocretin neurons in the lateral hypothalamus with decreased ORX levels in the cerebrospinal fluid (CSF). Although the underlying process leading to this destruction remains unclear; an autoimmune origin is suspected. The study authors recently compared the bacterial communities of the fecal microbiota of NT1 patients and control subjects. Initial results demonstrated a difference in overall bacterial community structure in NT1 compared to controls, as assessed by beta diversity, even after adjusting for body mass index (BMI). The Shannon biodiversity index was also correlated with the duration of NT1 disease. However, no association was found between the structure of the microbial community and the clinical characteristics of NT1 patients. In 2022, a second study from the SOMNOBANK cohort on a larger population confirmed these results, showing dysbiosis between NT1 patients and the control population. The altered intestinal microbial diversity supports the important role of the environment in the development and pathogenesis of NT1. Other studies have established a link between dysbiosis, intestinal permeability and inflammation in other neuroimmune pathologies. Currently, no study has focused on these phenomena of bacterial translocation, intestinal permeability and immune activation linked to the microbiota in type 1 narcolepsy patients. The study hypothesis is that NT1 patients with dysbiosis in their intestinal microbiota also present a bacterial translocation with an intestinal origin, leading to a systemic inflammatory syndrome favoring an autoimmune damage destroying hypocretin neurons in the hypothalamus. The study authors suspect that microbial elements (DNA) involved in the autoimmune process could be detected in the CSF. This bacterial translocation could vary over time depending on: i) the progression of the disease and its management; ii) changing dysbiosis and: iii) the increase in intestinal permeability and inflammation.
The goal of this pilot observational study is to assess the ability of continuous 'home' EEG to accurately diagnose Narcolepsy in children and young people with hypersomnia. The main question[s]it aims to answer are: - can ambulatory home monitoring using a Dreem headband with a 'life as usual' unrestricted protocol allow accurate diagnosis of Narcolepsy, compared to gold standard in-patient PSG and MSLT - which EEG derived sleep parameters and study duration yield most diagnostic accuracy Participants undergoing investigation for hypersomnia will additionally be asked to wear a Dream Headband at night for weeknights, then continuously for 48 hours over the weekend. The data from the headband will then be analysed to see if it can predict the results of the polysomnography and MSLT that form routine clinical care.
The goal of this clinical trial is to see how NLS-2 (mazindol extended-release) works on symptoms of narcolepsy, including cataplexy and excessive daytime sleepiness. Approximately 48 participants will take part in the study across the United States. The study treatment (NLS-2 or placebo) will be administered for 8 weeks. After this treatment period, the participant may have the option to participate in a separate long-term extension study during which all participants will be treated with NLS-2.