View clinical trials related to Apnea.
Filter by:The HYPNOS study is an acute feasibility study to validate a new device for automatic detection and treatment of sleep apnea syndrome. The system is known as the PASITHEA system and it will perform the following tasks: - Detect apneas and hypopneas in real time, based on physiological signals acquired with a cardiorespiratory holter (nasal air flow, heart rate and blood oxygen saturation (SaO2)) - Upon detection of apnea or hypopnea events, trigger kinesthetic stimulation of mechanoreceptors of the skin close to the mastoid bone The primary objective is to verify that the PASITHEA system is able to detect apneas and hypopneas reliably. The main secondary objective of the study is to assess the effect of kinesthetic stimulation on reducing the number of sleep respiratory disorders. Another objective of the study is to verify the safety of the PASITHEA system.
The study design of this research project involves orthodontic patients registered at the Harvard School of Dental Medicine who are deemed eligible to undergo orthodontic treatment and who have been provided with sufficient information to make informed consent to join the sleep study. These patients will be provided with the Medibyte sleep monitor and instructed on the proper manner in which it should be set up and worn for the one night study period. This process will be carried out twice throughout the course of the study, once before any orthodontic appliance has been cemented and once after the required amount of tooth movement has been attained with the orthodontic appliance still in place. The de-identified data from the Medibyte monitor will be downloaded using the Braebon software and analyzed.
Nowadays,caffein is commonly used for AOP, and it reduces the intubation rate in preterm infants. However, intubation is needed in about 20%-50% of partial neonates. How to reduce the intubation rate effectively is a challenge for neonatologists.
The purpose of this study is to determine whether nasal intermittent positive pressure ventilation (NIPPV) reduces the need for endotracheal intubation in very low birth weight infants with persistent apnea who fail nasal continuous positive airway pressure (NCPAP).
The sleep apnea-hypopnea syndrome (SAHS) is a respiratory disorder characterized by frequent breathing cessations (apneas) or partial collapses (hypopneas) during sleep. SAHS is linked with the most important causes of death in adults from industrialized countries. Metabolic deregulation and cardiovascular and cerebrovascular diseases, such as atrial fibrillation, stroke, myocardial infarction and sudden cardiac death, could affect people having untreated SAHS. The gold standard method for SAHS diagnosis is in-hospital, technician-attended nocturnal polysomnography (PSG). Nevertheless, this methodology is labor-intensive, time-consuming, and relatively unavailable, especially in low-resource settings. These drawbacks have led to large waiting lists, which delay diagnosis and treatment and limits its effectiveness as single diagnostic method for SAHS. Blood oxygen saturation (SpO2) and pulse rate (PR) from nocturnal pulse oximetry (NPO) provide relevant and essential information to detect apneas. In addition, it is significantly less intrusive for patients and it can be easily recorded at patients' home. In the same way, automated signal processing and pattern recognition techniques have demonstrated to provide accurate tools able to detect and effectively use this information. Therefore, the investigators hypothesize that automated pattern recognition of at-home NPO recordings could provide reliable and efficient tools able to simplify the management of SAHS. The aim of this study is two-fold: 1) to prospectively assess the reliability and effectiveness of at-home NPO in the context of adult SAHS; 2) to design, optimize and extensively assess the diagnostic performance of automated NPO-based screening tools for SAHS. In order to achieve these goals, both PSG and NPO recordings are carried out ambulatory and simultaneously at patient's home. A portable polysomnograph (Embletta MPR, Natus) is used for standard PSG at home, whereas a portable wrist-worn pulse oximeter (WristOX2 3150, Nonin) is used for ambulatory NPO. In addition, conventional in-lab PSG and attended pulse oximetry are also performed simultaneously in the hospital facilities.
During routine clinical practice, it is observed that patients with suspected obstructive sleep apnea (OSA) often reported waking up with a dry mouth during the night or in the morning. This 9 week, cross-over group, randomized, single center, study will evaluate the efficacy of a proprietary formulation in comforting dry mouth in Sleep Apnea patients.
This study will investigate Obstructive Sleep Apnea (OSA) and an automatically Adjusting Positive Airway Pressure (APAP) device with new technology called SensAwake™. This requires experimental confirmation in a randomised controlled trial with crossover design, comparing compliance on standard APAP with compliance using APAP modified by the addition of the SensAwake™ modification on consecutive nights in participants with moderate−to−severe OSA.
In this study, submental ultrasound during awake and simultaneous under Drug-induced sleep endoscopy is applied in the diagnostic workup of obstructive sleep apnea patients. The aim is to assess the tongue base thickness during awake and sleep with different head positions. By correlation with Drug-induced sleep endoscopy findings, more parameters could be used for evaluation and management of upper airway collapse in obstructive sleep apnea patients.
Apnea test (AT) is the most important clinical test performed usually at the end of brain death (BD) diagnosis procedure. Traditional insufflation apnea test (I-AT) cannot be completed in patients with extremely compromised lung function due to rapid blood desaturation and circulatory disturbances. Therefore the investigators decided to verify alternative AT options such as continuous positive airway pressure apnea test (CPAP-AT) in patients with good and poor baseline oxygenation, before implementing them in currently reviewed Polish BD criteria.
Obstructive Sleep Apnea (OSA) is a common and under-diagnosed breathing disorder characterized by recurrent partial or complete collapse of the upper airway (tongue, soft palate) during sleep. It causes recurrent episodes of asphyxia (suffocation) resulting in fragmented sleep, low blood oxygen levels (hypoxemia), and high carbon dioxide concentrations. Untreated OSA is associated with serious heart/lung and metabolic diseases including strokes, diabetes, and heart attacks. When a patient with OSA undergoes surgery, the symptoms of OSA are exacerbated afterwards due to the effects of anesthesia and related medications such as those used for pain control. This puts patients at higher risk for complications and necessitates nursing care and monitoring that are resource intensive. In many hospitals, patients with an OSA diagnosis are monitored after surgery in "high acuity" wards where the nurse to patient ratio is higher than usual. These high acuity/monitored beds are often in high demand, and their unavailability may sometimes mean cancellation of surgery or prolonged patient stay in the Post-operative Recovery Room, further causing operating room backlog. Another serious issue is that many patients do not know they actually have the OSA condition. It is estimated that up to 20% (1) of people in the general public have OSA and that 75% (2) of them are not diagnosed. When someone with OSA goes for surgery without previously being diagnosed, special precautions in care and monitoring may not be in place, until a complication develops. For this reason, this population - those most susceptible to have OSA, but with no previous formal testing for the condition - is the most at risk for complications, and is the target group for this trial. We plan to identify the study population by screening for OSA using the STOP-BANG questionnaire. Those who score high on this 8 item screening test have high likelihood of actually having OSA if they were to undergo formal testing and diagnosis in a Sleep Lab. We will identify cardio-respiratory complications by conducting a chart review and determine whether admission to a "high acuity" bed had any impact. As OSA patients are at higher risk for cardiovascular complications at baseline and around the time of surgery, blood test for troponin will be performed on post-op day 1 and 2 to investigate the rate of myocardial injury. With the rate of MINS (myocardial injury after non-cardiac surgery) reported to be 8% with almost 10% 30 day mortality (per VISION trial), this pilot project which focuses on arthroplasty patients with suspected OSA, will inform us of the arthroplasty surgery specific MINS risk for comparison.