View clinical trials related to Hypoxia.
Filter by:Positive end-expiratory pressure (PEEP) has become an essential component of the care of critically ill patients who require ventilatory support. In 1975, several investigators published the effects of PEEP in 15 mechanically ventilated patients with acute respiratory failure (ARF) supported by mechanical ventilation. FiO2 ranged between 21% to 75% and the tidal volume between 13 to 15 mL/kg. PEEP was increased in 3 cmH2O steps until cardiac output fell. The aim was to identify the "optimum" PEEP level. "Best" PEEP was associated simultaneously with the best static compliance of the respiratory system, the greatest oxygen transport, and the lowest dead space fraction. That study established the basis for the use of PEEP in patients with ARF worldwide. Although currently patients with ARF are ventilated with much lower tidal volumes, that study has never been validated. It is unknow whether their findings are currently valid, generalizable, and reproducible.
This study is designed to answer questions related to safety and preliminary efficacy of Acute Intermittent Hypoxia (AIH) in Traumatic Brain Injury (TBI) survivors. First, we aim to establish whether brief reductions in inhaled oxygen concentration can be safely tolerated in TBI survivors. Second, we aim to establish whether there are any effects of AIH on memory, cognition, and motor control. Participants will be monitored closely for any adverse events during these experiments. Data will be analyzed to determine if there is an improvement in key outcomes at any dose level.
The overall purpose of this study is to evaluate maternal-fetal tissue light scattering properties. The objectives of the study are: (i) integrate established mathematical principles of oxygen saturation to model with increasing accuracy the "body in a body" problem of fetus in mother; similar to existing pulse oximeters, the calculations will be integrated into software in the final commercial product; (ii) obtain human measurements against which both computational models and animal data can be compared.
Most premature babies require oxygen therapy. There is uncertainty about what oxygen levels are the best. The oxygen levels in the blood are measured using a monitor called a saturation monitor and the oxygen the baby breathes is adjusted to keep the level in a target range. Although there is evidence that lower oxygen levels maybe harmful, it is not known how high they need to be for maximum benefit. Very high levels are also harmful. Saturation monitors are not very good for checking for high oxygen levels. For this a different kind of monitor, called a transcutaneous monitor, is better. Keeping oxygen levels stable is usually done by nurses adjusting the oxygen levels by hand (manual control). There is also equipment available that can do this automatically (servo control). It is not known which is best. Research suggests that different automated devices control oxygen effectively as measured by the readings from their internal oxygen saturation monitoring systems. When compared to free-standing saturation monitors there appears to be variations in measured oxygen levels between devices. This could have important clinical implications. This study aims to show the different achieved oxygen levels when babies are targeted to a set target range. Babies in the study will have both a saturation monitor and a transcutaneous oxygen monitor at the same time. Both types of monitor have been in long term use in neonatal units. For a period of 12 hours, each baby will have their oxygen adjusted automatically using two different internal oxygen monitoring technologies (6 hours respectively). The investigators will compare the range of oxygen levels that are seen between the two oxygen saturation monitoring technologies. The investigators will study babies born at less than 30 weeks gestation, who are at least 2 days old, on nasal high flow and still require added oxygen.
This is a Phase I trial evaluating the safety of personalized radiation therapy based on levels of hypoxia identified on FMISO-PET and MRI. All patients will receive a baseline FMISO positron emission tomography (PET) and MRI to identify levels of hypoxia. Patients with tumor hypoxia will receive a higher dose of radiation therapy. Subjects who do not have hypoxic tumors will be treated with the standard-of-care radiation regimen. After fraction 10 of radiation therapy, an additional MRI will be performed. If this interim MRI demonstrates little or no response (as defined in Section 6), an optional boost radiation dose can be administered. Trial enrollment will be conducted in two parts. In Part 1, eight patients will be enrolled. After all eight patients have completed the 30 day dose-limiting toxicity (DLT) period, enrollment will be placed on hold and safety will be evaluated. During the interim analysis, one additional patient will be allowed to be enrolled in the trial. If the trial meets stopping rules as described in Section 11.3, the trial will be re-evaluated by the Data and Safety Monitoring Committee (DSMC) and the Principal Investigator. However, if the rate of DLTs remains below the unacceptable toxicity rate, enrollment will open to the enrollment of eight more patients.
Establish a pulmonary hypertension registry and biorepository to lead towards a further understanding of the disease.
Inhaled nitric oxide is a widely accepted standard of care for pulmonary hypertension, and has been studied in the context of cardiac surgery. CPB during cardiac surgery induces systemic inflammatory response and ischemic-reperfusion injury of many organs. Nitric oxide added to the bypass circuit may have anti-inflammatory effect and has shown the potential to ameliorate organs' injury . There is evidence that the delivery of nitric oxide to the oxygenator gas flow during pediatric CPB is accompanied by a reduction in myocardial injury markers' levels in the postoperative period. In adults, NO supply to the CPB circuit during CABG exerted a cardioprotective effect and was associated with a lower level of inotropic support and cardio-specific blood markers . To our knowledge, this is the first trial to assess whether artificial nitric oxide supplementation to the CPB-system reduces the incidence of hypoxemia after cardiac surgery.
The oximeter is used to monitor intensive care patients undergoing oxygen therapy. It indicates pulsed oxygen saturation (SpO2), a reflection of arterial oxygen saturation (SaO2) which enables detection of hypoxemia and hyperoxia, both deleterious state. Current SpO2 recommendations aim to reduce both risk of hypoxemia and hyperoxia. SpO2 is considered the 5th vital sign. Current recommendations for SpO2 targets do not consider the variability of oximeters used in clinical practice. This variability and lack of specification represent an obstacle to an optimal practice of oxygen therapy. Thus, this study aims to compare the SpO2 values of different oximeters (Nonin, Masimo, Philips, Nellcor) used in clinical practice with the SaO2 reference value obtained by an arterial gas in order to specify the precision and the systematic biases of the oximeters studied. This data will also make it possible to refine the recommendations concerning optimal oxygenation
The purpose of the study is to assess whether lung ultrasound is able to detect lung injury after lung resection surgery.
In this randomized controlled trial (RCT), severe cases of COVID-19 infection will be treated with secretome of hypoxia-mesenchymal stem cells. The improvement in clinical, laboratory, and radiological manifestations will be evaluated in treated patients compared with the control group.