5 Clinical Trials for Various Conditions
The investigators hypothesis is that upper airway collapsibility (Pcrit) in patients with obstructive sleep apnea (OSA) can be measured using equipment found in the clinical sleep laboratory and these Pcrit measurements obtained using clinical sleep laboratory equipment is comparable to those obtained using research equipment. OSA is a common disease characterized by repetitive collapse of the upper airway during sleep, leading to hypoxemia and arousals, and which has important neurocognitive and cardiovascular consequences. The single most important factor in the development of OSA is upper airway collapsibility: those with a more collapsible upper airway tend to have OSA while those with a stiffer upper airway do not. The gold standard treatment for OSA is continuous positive airway pressure (CPAP), which acts by stenting open the collapsible airway. Upper airway collapsibility can be measured during sleep by changing the CPAP level and assessing the change in inspiratory flow through the upper airway. Although technically feasible, these measurements are typically only undertaken in research laboratories with specialized equipment. The purpose of this study is to measure upper airway collapsibility using clinically available (i.e. equipment found in a clinical sleep laboratory) equipment only. If successful, upper airway collapsibility could be routinely measured in clinical practice, which could help inform treatment decisions and help individualize therapy for OSA.
Obstructive sleep apnea (OSA) is common and has major health implications but treatment options are limited. OSA patients show a marked reduction in upper airway (UA) dilator muscle activity at sleep onset and this phenomenon leads to increased collapsibility of UA compared to normal participants. Until recently, the search for medicines to activate pharyngeal muscles in sleeping humans has been discouraging. However, exciting new animal research has shown that drugs with noradrenergic and antimuscarinic effects can restore pharyngeal muscle activity to waking levels. In this protocol the investigators will test the effect of desipramine (a tricyclic antidepressant with strong noradrenergic and antimuscarinic effects) on upper airway collapsibility and genioglossus muscle activity (EMG GG) during sleep in OSA patients.
The investigators hypothesized that sleeping in a 45 degrees elevated body position decreases the likelihood of upper airway vulnerability to collapse early after delivery. Furthermore, the investigators want to elucidate the anatomical and physiological risk factors that contribute in the upper airway obstruction in post-partum patients.
The investigators hypothesize that propofol, when compared to sevoflurane, causes the upper airway to collapse more easily and causes less activity in the tongue muscle. Additionally, the investigators hypothesize that, under increased carbon dioxide concentrations of the air inhaled, the upper airway will be less likely to collapse under anesthesia and there will be increased activity in the tongue muscle under both propofol and sevoflurane, when compared to breathing normal concentrations of carbon dioxide, as in room air. Furthermore the investigators hypothesize that anesthesia disrupt the breathing swallow coordination, an effect additionally altered by increased carbon dioxide through increased respiratory drive.
The current study is designed to examine underlying mechanisms of action of lingual muscles in the maintenance of airway patency during sleep. The investigators' major hypothesis is that specific tongue muscles are responsible for relieving upper airway obstruction during sleep.