View clinical trials related to Apnea.
Filter by:This study is a prospective, multi-center, single-arm, open-label study evaluating the safety and effectiveness of therapy with the ProSomnus EVO Sleep and Snore Device in individuals with severe obstructive sleep apnea.
To verify the effect of orofacial myofunctional therapy in patients with OSA during the use of CPAP with a nasal mask, on the frequency and leak flow. In addition, the impact on mouth opening frequency, sleep quality, perception of excessive daytime sleepiness, and CPAP adherence will be evaluated.
Apneic oxygenation describes the process of continuous oxygenation of the blood without breathing efforts. This anesthesia technique has been described in the literature for more than 100 years and is sometimes used under general anesthesia, e.g. during surgery of the vocal chords. Although this technique usually provides marked prolongation of the apneic period because of excellent oxygenation, it is limited by the absence of ventilation and the corresponding accumulation of carbon dioxide in the blood. This will lead to worsening respiratory acidosis and associated complications, such as cardiac arrythmias. In 2015 it was reported that apneic oxygenation with high-flow nasal oxygen delivery systems (HFNO), a device that provides heated humidified oxygen at high flow rates (usually 30-70 L/min), resulted in less carbon dioxide accumulation compared with historical controls. This specific technique of apneic oxygenation was termed transnasal humidified rapid-insufflation ventilation exchange (THRIVE). To date, the impact on different flow rates on blood carbon dioxide accumulation during THRIVE is unknown. Specifically, very high flow rates, exceeding 70 L/min have not been investigated. Therefore, the aim of this trial is therefore to study the rate of accumulation of carbon dioxide during THRIVE at two different flow rates: 40 and 100 L/min.
Over the last decades, research in cardiopulmonary resuscitation was primarily focused on uninterrupted chest compressions to restore sufficient circulation. Ventilation during ongoing chest compressions was regarded as potentially deleterious and thus not given any major scientific focus. Current guidelines advise that ventilation be monitored by end-tidal CO2 and emphasize that hyperventilation be avoided. Recent findings from arterial blood gas analyses showed high levels of arterial pCO2, resulting in a frequent occurrence of hypercapnic acidosis, which may be caused by iatrogenic hypoventilation. Ventilation during ongoing chest compressions can be hard to achieve, as nearly every breath may be terminated by simultaneous chest compressions. In case of bag ventilation the applied tidal volumes have not yet been measured und mechanical ventilators so far were not able to ventilate during chest compressions, because pressure limit settings induced termination of inspiration. The aim of this study is to provide patients with the best possible ventilation, even under ongoing chest compressions. Patients are ventilated with a new turbine-driven ventilator (Monnal T60, Air Liquide, France), which can deliver adequate tidal volumes within a very short inspiratory phase due to the inspiratory flow of > 200l/min. Thus, in deviation from the current recommendations, the ventilation rate can be doubled to 20/min, so that inspiration coincides with cardiac massage less often. The study compares effective ventilation volumes applied by two regimes, 10 breaths/min and 20/min.
The purpose of the study is to see if metformin improves metabolism in patients with obstructive sleep apnea (OSA) using positive airway pressure (PAP) therapy. Metformin is approved by the Food and Drug Administration (FDA) for the treatment and prevention of diabetes. It is not approved for use in patients with OSA.
The proposed study is a randomized cross over trial assessing the efficacy of two different positional therapies for positional obstructive sleep apnea (POSA). The effectiveness of the two different therapeutic devices (Positional pillow and vibrating belt) in reducing the time spent sleeping supine, and therefore at risk of apnoeas, will be evaluated consecutively in 52 subjects with a de novo diagnosis of positional sleep apnoea. The subjective quality of sleep will also be evaluated prior to treatment and following the use of each separate device by means of a "Quality of sleep questionnaire"
This study aims to evaluate the effect of high-flow nasal oxygenation on safe apnea time for children undergoing general anesthesia, with their mouth open.
Comparison of the NightBalance Sleep Position Trainer (SPT) to Positive Airway Pressure (PAP) for the Treatment of Positional Obstructive Sleep Apnea (POSA). Primary Objective: Efficacy and Adherence of the SPT over 3 months of use compared to PAP for the treatment of POSA. The study is run from centers in France, the UK and Germany.
This study aims to evaluate the association between obstructive sleep apnea (OSA) and fetal growth restriction (FGR) and to assess the role of auto-titrated positive airway pressure (aPAP) as antenatal therapy in these patients. Pregnant patients with diagnosed FGR will be screened for OSA first by screening questionnaire and then by home sleep monitor. Of those patients diagnosed with OSA, half will be assigned to use aPAP each night when sleeping and half will not (standard care).
The aim of this study is to evaluate the efficacy of a combination of Continuous Positive Airway Pressure (CPAP) and a Mandibular Advancement Device (MAD) on nocturnal Blood Pressure control in hypertensive patients in obstructive sleep apnea low CPAP compliers (less than 4 hours per night). Hypertensive patients demonstrating low CPAP adherence will be selected during a screening visit; they will be then randomized to one of the three following arms: Education to CPAP ("CPAP only"), Treatment by a MAD ("MAD only") or a combination of both CPAP and MAD ("CPAP+MAD"). Mean systolic, diastolic, diurnal and nocturnal blood pressure will be assessed during 24-h Ambulatory Blood Pressure monitoring, before and after a 3-month treatment intervention. Biological laboratory parameters, patients reported outcomes (daytime sleepiness and Quality of Life), will also be evaluated before and after 3 months of treatment.