View clinical trials related to Sleep Apnea Syndromes.
Filter by:The purpose of this study is to evaluate the safety and effectiveness of the SleepFlex program for treatment of mild to moderate OSA
Central sleep apnea (CSA) is a common condition and its treatment remains elusive. The focus of this proposal is to identify the role of the physiologic path involving cortical arousals in CSA by decreasing arousal frequency using the pharmacological agent zolpidem. The goal is to identify the acute effects of administering zolpidem on sleep and respiratory outcomes, and subsequently, its effect on the severity of CSA and propensity to develop CSA. This study will shed light on the mechanisms underlying CSA that involve cortical arousals and will guide future therapeutic interventions for CSA.
Non-compliance rates estimated at 50% pose a major issue for CPAP therapy, the primary treatment for OSA. Negative external pressure, applied over the anterior neck under the mandible, has shown encouraging results as an alternative therapy. This study assessed a variety of sizes and shapes of collars and a range of pressures for variable negative external pressure (vNEP) treatment in subjects having moderate OSA to identify combinations that improve the efficacy and comfort of this emerging therapy. Observations made in this study may be used to plan a more definitive follow-on investigation.
Researchers are looking for a better way to treat people with obstructive sleep apnea (OSA). In people with OSA, the upper airways can narrow or close repetitively while sleeping. These breathing interruptions lead to reduction of oxygen in the blood or short arousals from sleep. Before a treatment can be approved for people to take, researchers do clinical trials to better understand its safety and how well it works. In this trial, the researchers want to learn more about how well BAY2586116 works in a small number of participants with OSA. The trial will include about 160 men and women who have OSA and are at least 18 years old. Women can only be included in this trial if they are not able to have children naturally. In this trial, the participants will take BAY2586116 and a placebo. A placebo looks like a treatment but does not have any medicine in it. All of the participants will take BAY2586116 through a nasal spray. They will also take the placebo as a nasal spray. This will be a crossover trial. This means all the participants will take both trial treatments one after the other, but in a different order. The participants will take each treatment once a day for 7 days. The researchers will use a measurement called the apnea-hypopnea-index (AHI) to measure the severity of the participants' OSA. The researchers will then compare the participants' AHI scores when they take BAY2586116 and when they take the placebo. During study, the participants will visit their trial site 5 times. At these visits the doctors will take blood samples, do physical examinations and check the participants' heart health using an electrocardiogram (ECG). They will also ask the participants questions about how they are feeling and if they have any medical problems. At 3 of the visits, the participants will stay at the trial site overnight. At these visits, the doctors will calculate the number of times the participants stop breathing per hour of sleep. After treatment, the participants will have a final visit 7 days later so the doctors can check their health.
The aim of this trial is to assess the effect of two automated beds on severity of POSA as well as the feasibility of these beds as POSA treatment. These beds are equipped with sensors detecting apnoeas and hypopnoeas from physiological measurements - such as chest movement or breathing sound -, and coherently reacting by actively changing the user position whenever an apnoeic event occurs. Thereby we will investigate a possible treatment alternative to already established OSA therapies, either as a valuable add-on for patients eligible to the currently available therapies or as primary treatment option.
The primary objective of this study is to determine whether the effect of continuous positive airway pressure (CPAP) therapy on 24-hour mean blood pressure (BP) in patients with obstructive sleep apnea (OSA) varies between symptom phenotypes.
Nocturnal reduction in blood oxygen is expected independently associated with the development of worsened glycemic control in individuals with type 2 diabetes mellitus. The aim of the present study is to assess the correlation between nocturnal oxygen desaturation assessed by overnight pulse oximetry and glycemic control in diabetic patients with obstructive sleep apnea.
The meta-analysis "sleep apnea syndrome and arterial stiffness" includes data from 893 patients initially included in 9 studies conducted by the EFCR Department of the CHUGA between 2006 and 2015, presenting a sleep apnea syndrome (SAS) with exploration of their arterial stiffness via the measurement of pulse wave velocity (PWV). Currently, we do not have long-term follow-up data for these patients. The first objective of the "PWV Follow-up" project is to collect cardiovascular events in these patients through telephone interviews and a structured questionnaire to determine the prevalence of these events. The prevalence of metabolic events, incident cancers and deaths will be also determined as secondary objectives through the same questionnaire. Others secondary objectives are to evaluate the impact of continuous positive airway pressure (CPAP, the reference treatment for OSA) on the occurrence of cardiovascular and metabolic events and incident cancers, as this is still discussed in the literature.
A multicentre, randomized controlled trial (RCT) design.The control group followed the usual treatment, while the intervention group (PIMA) followed the treatment with an adapted and flexible care plan depending on socio-demographic, clinical and psychological variables. The treatment plan includes different channels (home, telephone, care center), a continuous evaluation, and the use of the motivational interview in each of the interventions with the patient. The main outcome was adherence. Secondary outcomes were quality of life, emotional state, activities, social relationships, perceived competence and motivation.
Continuous positive airway pressure and non-invasive ventilation are common treatment modalities for obstructive sleep apnea, central sleep apnea, and chronic alveolar hypoventilation from a variety of causes. Use of positive airway pressure (PAP) requires use of an interface, commonly referred to as a "mask." There are a range of mask options available, differing in configuration and sizing, including masks that fit into the nostrils (nasal pillows, NP), cover the nose (nasal masks, NM), cover both the nose and the mouth (oronasal masks, ONM), and rarely those that fit into the mouth (oral masks, OM) or over the entire face. The variety of masks, sizes, and materials result from the wide variety of facial configurations and patient preferences along with requirements to provide a good seal for varying pressure requirements. Failure to find a good match for a given patient may result in significant side effects, such as eye irritation owing to leak into the eyes, skin pressure sores, noise generation, and inadequate therapy when air leaks are extreme. Pressure sores, mask dislodgement, claustrophobic complaints, air leaks, and sore eyes occur in 20-50% of patients with OSA receiving PAP, and these effects negatively correlate with PAP compliance. Furthermore, several trials point to differences in compliance related to which types of masks are utilized. In a randomized cross-over trial, compliance was 1 hour more per night in patients using NM compared to those using ONM.1 In another, NPs were associated with fewer adverse effects and better subjective sleep quality than NMs.2 Therefore, failure to find an acceptable mask results in lower or non-compliance, and therefore treatment failure. Currently, finding a right mask is performed either using crude templates, or via an iterative process, variably guided by experts in mask fitting. There are no standard certifications or algorithms to guide mask fitting. Given the above, it would be very desirable to find a reliable method to reduce the errors in mask fitting so that the costs, inconvenience, and suffering are all reduced.