Clinical Research Directory

Quantification of Phosphorylated Alpha-synuclein in Cutaneous Biopsies as a Prospective Biomarker in Parkinson's Disease

This study aims to assess the levels of phosphorylated alpha-synuclein (P-SYN) in patients with Parkinson's disease and REM Behavior Disorder using a minimally invasive skin punch biopsy. It seeks to understand the natural progression of P-SYN deposition over time to explore the potential of P-SYN quantification as a biomarker for disease progression.

INSIGHT: Insomnia, Nightmares, and Sympathetic Hyperactivity Intervention

The INSIGHT study is a multi-site clinical research program designed to examine how insomnia and symptoms of sympathetic hyperactivity impair sleep, cognition, and physiological restoration in warfighters, and to evaluate whether a wearable therapeutic device can improve these outcomes. Warfighters with a history of traumatic brain injury, post-traumatic stress disorder, or chronic operational stress commonly report disrupted sleep accompanied by manifestations of nocturnal sympathetic activation such as diaphoresis, palpitations, hyperarousal, and nightmares. These symptoms erode sleep quality, reduce cognitive performance, and undermine psychological resilience and operational readiness. Insomnia is two to three times more common in military populations than in civilians, and both TBI and PTSD independently elevate the risk for dysregulated autonomic tone. Excessive sympathetic activity during REM sleep disrupts the normally quiescent locus coeruleus state required for adaptive emotional processing and may contribute to the genesis of nightmares. Excessive sympathetic tone may also interfere with deep NREM-dependent glymphatic clearance, a recently discovered mechanism that supports cognitive restoration and metabolic waste removal. Yet, no study has comprehensively linked these physiological processes in warfighters or evaluated whether wearable-derived autonomic measures can meaningfully stratify insomnia phenotypes. The INSIGHT protocol addresses this gap through a two-phase design integrating multimodal biomarker collection, wearable technology validation, advanced imaging, and a randomized controlled intervention. Phase 1 enrolls 250 participants (50 healthy controls and 200 poor sleepers with or without PTSD and TBI) who undergo structured screening, cognitive testing, and detailed baseline assessments before completing a 2-week at-home data collection period. During this period, participants wear a suite of devices, including EEG headbands, ECG patches, PPG-based sensors, accelerometry rings, blood pressure devices, temperature sensors, and smartwatches, to capture autonomic activity, sleep architecture, cardiovascular and respiratory variability, movement, sudomotor activity, and circadian body temperature patterns. Ecological momentary assessments administered three times daily track fluctuations in sleep quality, mood, PTSD symptoms, and daytime functioning, while urine samples collected on the final three days allow for biochemical analysis of hormonal and sympathetic biomarkers. After the at-home period, all participants complete an overnight in-lab polysomnogram combined with fNIRS to measure sleep stages, autonomic dynamics, cerebral hemodynamics, and glymphatic signatures. A subset of participants also completes an optional overnight MRI with simultaneous EEG following controlled sleep deprivation, enabling state-of-the-art imaging of human glymphatic activity using the MAGNUS MRI platform. This optional visit provides unprecedented insight into how TBI, PTSD, and insomnia alter the physiology of sleep-dependent brain fluid dynamics. In Phase 2, all poor sleepers enter a double-blind, sham-controlled, 30-day randomized trial testing the therapeutic potential of the NightWare smartwatch. NightWare detects sympathetic surges during sleep through heart rate elevations and movement patterns and delivers brief haptic vibrations aimed at interrupting escalating autonomic arousal. Although originally cleared for nightmare treatment, its mechanism is well suited for SNH-related insomnia more broadly. Participants use the device daily while continuing EMA surveys, wearable monitoring, and cognitive assessments, generating rich physiological and behavioral data throughout the intervention. The primary goal is to determine whether reducing nocturnal sympathetic spikes leads to measurable improvements in sleep quality, autonomic stability, daytime functioning, and symptom burden. In parallel, Phase 2 data enable development of the Multi-Organ Autonomic Index of Sleep, an integrated biomarker model that combines neurological, cardiovascular, respiratory, and dermal signals to predict treatment response and classify insomnia subtypes. The INSIGHT study will produce the most comprehensive dataset to date linking autonomic physiology, glymphatic function, sleep architecture, wearable-derived biomarkers, cognition, and clinical outcomes in warfighters. By identifying physiological signatures of sympathetic hyperarousal and determining whether a non-pharmacological wearable intervention can meaningfully improve sleep, INSIGHT directly supports Department of Defense priorities to enhance readiness, resilience, and long-term neurological health in service members. Wearable tools capable of monitoring and improving sleep outside the laboratory have the potential to transform both clinical care and operational performance, offering scalable and accessible approaches to restoring sleep and optimizing recovery.

Evaluating the Efficacy and Safety of PROSOMNIA Sleep Therapy™ in Patients With Sleep Deprivation and Chronic Insomnia

This clinical trial aims to evaluate the safety and efficacy of PROSOMNIA Sleep Therapy (PSTx) for individuals suffering from chronic insomnia, sleep deprivation, and REM sleep disorders. Chronic insomnia, characterized by difficulty falling or staying asleep, significantly affects patients and quality of life, mood, and cognitive function. REM sleep disorders, in which the body struggles to enter or maintain restful REM sleep, can worsen these issues. The trial introduces a novel therapy using anesthesia-induced sleep, targeting sleep homeostasis and improving sleep architecture. Objectives: The primary goals of the trial are to determine: 1. Whether PROSOMNIA Sleep Therapy increases the quality of REM sleep. 2. Whether PSTx increases the duration of REM and/or NREM sleep. 3. Whether PSTx decreases the time it takes participants to fall asleep (sleep onset latency). Participants will receive ONE (1) PROSOMNIA Sleep Therapy session lasting between 60-120 minutes. Each session uses Diprivan/Propofol to induce sleep, and is monitored via an EEG to ensure proper sleep stages, particularly REM sleep. Participant Criteria: Inclusion: Adults aged 18-65 with diagnosed or undiagnosed chronic insomnia or sleep deprivation. Exclusion: Patients with severe obesity, significant cardiovascular, neurological, or psychiatric conditions, or those with an ASA status above II. Study Design: This trial is non-randomized, single-arm and open-label, with all participants receiving the PSTx. The trial does not include a comparison group, as the focus is on evaluating the immediate, direct effects of the therapy. Participants will undergo continuous EEG monitoring during therapy sessions, allowing researchers to track brain activity and sleep stages in real-time. This method ensures that sleep cycles, particularly REM sleep, are optimized for therapeutic benefit. Therapy Methodology: PROSOMNIA Sleep Therapy leverages anesthesia to mimic natural sleep patterns and enhance the efficiency of REM sleep. Diprivan/Propofol is used to induce REM sleep, while EEG monitoring tracks and maintains proper sleep architecture throughout the session. The therapy promotes the clearance of adenosine, a compound that builds up during wakefulness and drives the need for sleep. Adenosine is cleared during REM sleep, reducing sleep pressure and improving cognitive function. Outcome Measures: Primary Outcomes: Researchers will measure the increase in REM sleep duration, improvement in sleep quality (via self-reported questionnaires), and a reduction in sleep onset latency. Secondary Outcomes: These include changes in mood, cognitive function, and blood serum uric acid levels. Patient-reported outcomes will also be tracked through tools like the PROSOMNIA Sleep Quiz, which is specifically designed for PSTx. Significance: Chronic insomnia and REM sleep disorders affect millions globally, leading to cognitive impairment, mood disturbances, and poor overall health. Traditional treatments, including pharmacological approaches and Cognitive Behavioral Therapy for Insomnia (CBT-I), often provide suboptimal results for many individuals. PSTx offers a novel, therapeutic approach to restoring sleep balance and enhancing the overall quality of sleep, particularly for those who have not responded to conventional treatments. Study Process: Recruitment and Baseline Assessments: Participants undergo a comprehensive sleep assessment, including sleep questionnaires and polysomnography, to establish a baseline for sleep quality and duration. Blood serum uric acid levels will also be measured to track any biochemical changes due to therapy. Therapy Sessions: Only one (1) PROSOMNIA Sleep Therapy session will be administered, with the session lasting between 60-120 minutes. Diprivan/Propofol is used to induce sleep, and EEG will monitor brain activity to ensure the proper balance of sleep stages. Post-Therapy Follow-up: Follow-up assessments will occur at 24 hours, 7 days, and 30 days post-treatment. Researchers will analyze the therapy effects on REM sleep, mood, cognitive function, and other health indicators. Potential Implications: If successful, this trial could revolutionize how we treat sleep disorders by targeting the underlying mechanisms of sleep pressure and REM sleep disruption. PROSOMNIA Sleep Therapy may offer a safe, effective, and immediate alternative for patients who have exhausted other treatment options. Key Concepts: Homeostatic sleep drive, (Process S), caused by adenosine buildup during wakefulness, is disrupted by chronic insomnia. This impacts cognitive function health and recovery. Anesthesia-induced REM sleep via PSTx helps regulate this homeostatic sleep stage, offering deeper and more restorative sleep compared to other sleep therapies. The study uses statistical methods like ANOVA and Chi-square to measure outcomes.

Prodromal Model of Parkinson's Disease Confined to The Peripheral Nervous System

Description of a method to detect Parkinson's disease or Parkinson's-like disease at an early stage (Prodromal Parkinson's Disease) where damage is still confined to the peripheral nervous system damage. Simultaneous collection of biological material to establish a biobank for use as prognostic biomarkers for the development of Parkinson's disease and other neurodegenerative diseases in which pathological alpha-synuclein deposits accumulate.

Subcortical Oscillations in Human Sleep Dysregulation

Sleep problems are common in the United States (US) adult population (\>50 million), and have a negative impact on quality of life, productivity, and healthcare. A major obstacle to understanding how the brain is involved in human sleep disorders has been the lack of recordings of human brain function, from inside the brain, during the known sleep states.

Mainz Register of Patients With Sleep Disorders

Prospective longitudinal observational registry study of all patients with sleep disorders treated in the Mainz Comprehensive Epilepsy and Sleep Medicine Center with the focus on the course of the disease and quality of life.