View clinical trials related to Hypoxia.
Filter by:The purpose of this study is to determine if, in preterm infants < 37 weeks' gestation at birth receiving oxygen without ventilatory/CPAP support, oxygen environment (OE) compared with nasal cannula oxygen (NC), will decrease the number of episodes with oxygen saturations less than 85% of ≥10 seconds in a 48 hour cross over period on either intervention. This is a randomized cross-over pilot study with a 1:1 parallel allocation of infants to oxygen environment or nasal cannula oxygen using stratified permuted block design. Following a 24 hour period on the first intervention, infants will cross over to a 24 hour period on the second (alternative) intervention before crossing back to the first intervention for a further 24 hours and then back again to the second (alternative) intervention for a further 24 hours.
This project will consist of two studies, each investigating resting and exercise cardio-respiratory responses during exposure to hypoxia in individuals born prematurely and individuals born at full term of two different age groups: Kids (10-14 yrs) and Adults (18-22 yrs).Additional study will be performed on a preterm adult cohort (15 participants) that will investigate potential differences between hypobaric and normobaric hypoxia as outlined in the following section.
The objective of this research is to assess the effects of acetazolamide and methazolamide on respiratory and limb muscle fatigue development. A fatiguing protocol will be conducted for the respiratory and plantar flexor muscles and the difference in pressure/torque produced by supramaximal nerve stimulation used to assess muscle fatigue between conditions.
Maternal oxygen administration for concerning fetal heart rate tracing (FHT) patterns is common practice on Labor and Delivery units in the United States. Despite the broad use of oxygen, it is unclear if this practice is beneficial for the fetus. The purpose of this study is to compare oxygen to room air in patients with Category II fetal heart tracings with regard to neonatal acid-base status, subsequent tracings, and production of reactive oxygen species
The investigators hypothesized that heated humidified high-flow nasal cannula oxygen(HFNC) along with high quality of sleep, in comparison with noninvasive positive pressure ventilation (NIV), could reduce the release of inflammatory marker C-reactive protein(CRP), which as independent predictor of atrial fibrillation(AF), further lower the incidence of new-onset AF following coronary artery bypass grafting(CABG).
Time to stable reading of oxygen saturation at the delivery room will be compared between two different devices.
This is a Phase I, open-label, single center trial to evaluate the feasibility and safety of low concentration CO2 gas mixture (5% CO2 + 95% air) inhalation in asphyxiated, cooled, mechanically ventilated newborns at risk of hypocapnia with The hypothesis is that hypocapnia, which is driven by hyperventilation in the presence of metabolic acidosis, is deleterious to the injured brain and can be safely avoided with low concentration CO2 inhalation.
The aim of this study is to determine whether High Flow nasal cannula (HFNC) oxygen is more efficient than the standard High Flow face mask (HFFM) for preoxygenation before orotracheal intubation after crash induction in non severely hypoxemic patients
Comparison of the preoxygenation efficacy of tidal volume breathing using three different preoxygenation techniques which are available to providers in the prehospital environment.
The aim of this study is to assess whether an auto-titrating oxygen system can maintain constant oxygen saturations (SpO2) in patients who are on long-term oxygen therapy (LTOT) during activities of daily living. Currently LTOT is provided at a constant fixed-flow rate e.g. 2 litres per minute all the time after appropriate assessment. The flow rate is not changed during usual household activities but is increased for walking. A number of studies have investigated the SpO2 of patients on LTOT during the daytime in patients' homes. The results have shown that patients' SpO2 decreases intermittently whilst they are doing activities of daily living such as watching television, putting away the shopping, having a shower or bath and dressing and undressing. This is a problem as it can lead to breathlessness, increased stress on the heart and affect brain function. In order to correct the drop in SpO2 that patients experience during everyday activities, the investigators have developed an oxygen system, which can automatically change the amount of oxygen delivered depending on a patients' oxygen saturations - an auto-titrating oxygen system. In this study, patients on LTOT will be asked to simulate a series of activities of daily living twice: once whilst on their usual fixed-flow oxygen therapy and once on the auto-titrating oxygen system. The activities will be carried out in a hospital setting. During the activities, SpO2 will be recorded continuously. The main outcome of interest from the study will be the SpO2 throughout the study on fixed-flow oxygen and the auto-titrating oxygen system.