View clinical trials related to Hypoxia.
Filter by:The aim of this study is to measure the actual use time in patients receiving supplemental oxygen using a new easy-to-use electronic remote monitoring device (TeleOx™)
In ECPR, where CPR times often range from 30 to 120 minutes, only patients with good circulation during CPR survive, while non-survivors commonly suffer from anoxic brain injury. The selection process during CPR is challenging causing a general survival rate of just 2 out of 10, and the urgent need for better selection criteria has been emphasized. It it crucial to keep cardiac arrest times as short as possible, pre primed-ECMO can facilitate this. The ECMO treatment and the long CPR times of ECPR can also affect the measurements of the neurologic prognostication guidelines after cardiac arrest, making its validity uncertain in this specific cohort. Further, the long-term neuropsychological follow-up is limited to a few patients, making it uncertain if ECPR gives the survivors good long-term life satisfaction or just a prolonged life. Our overall aim is to optimize and improve the care pathway for ECPR patients by refining patient selection, assessing pre-primed ECMO, validating neurological prognostication guidelines, and understanding long-term outcomes and challenges faced by survivors. Specific Aim 1: Evaluating predictors for good neurological outcomes in ECPR and to develop an evidence-based selection tool for ECPR. Specific aim 2: To assess the sterility and function of pre-primed ECMO. Specific aim 3: To evaluate the applicability of current guidelines for neurological prognostication after cardiac arrest in ECPR patients, and to assess the predictive value of individual and combined neurological tests in this specific patient population. Specific aim 4: To determine the long-term neuropsychological outcomes, identify the problems survivors experience in daily life, and assess life satisfaction - by comprehensive follow-up visits with validated questionnaires and neuropsychology testing up to 10 years after the ECMO-treated cardiac arrest
This research study seeks to establish the effectiveness of a combination of an inhaled corticosteroid and a beta agonist compared to placebo for the prevention of acute respiratory failure (ARF) in hospitalized patients with pneumonia and hypoxemia.
Background: Inhibiting the sodium-glucose cotransporter-2 (SGLT2) has been observed to reduce risk of cardiovascular events and kidney failure in type 2 diabetes. The exact mechanisms of the beneficial effects of SGLT2 inhibition (SGLT2i) are still unknown. Kidney hypoxia has been demonstrated in diabetic kidney disease and SGLT2i is thought to relieve hypoxia in the kidneys. Mitochondrial dysfunction and autonomic dysfunction might also contribute to kidney hypoxia. Objective: The primary aim of the study is to assess the acute effects of SGLT2 inhibition on parameters reflecting oxygenation and oxygen consumption of the human kidney in persons with type 1 diabetes. Exploratory aims are to investigate acute changes in oxygen availability and oxygen access to the kidneys after SGLT2i. This include measures of peripheral blood oxygenation, mitochondrial function and autonomic function. Methods: Acute intervention study with oral dapagliflozin given in two doses each of 50 mg or matching placebo as intervention. Kidney oxygenation and perfusion parameters will be assessed by blood-oxygen-dependant level magnetic resonance imaging. Mitochondrial function will be assessed by extracellular flux analysis on lymphocytes. Autonomic function will be assessed by measuring baroreflex sensitivity. Design: Randomized, double blinded, placebo-controlled, cross-over intervention study. Study population: Fifteen healthy controls are recruited by advertisement and 15 patients with type 1 diabetes recruited from Steno Diabetes Center Copenhagen. Endpoints: Primary end-point: Renal cortical and medullary oxygenation (T2*). Exploratory end-points: Renal cortical and medullary perfusion, renal artery flow, renal oxygen consumption, peripheral capillary oxygen saturation (SpO2), arterial oxygen partial pressure (PaO2), arterial oxygen saturation (SaO2), lymphocyte mitochondrial function, baroreflex sensitivity. Timeframe: Inclusion of patients from January 2020. Last patient last visit January 2021. Data analysis completed spring 2021, presentation autumn 2021 and publications Winter 2021.
Intermittent episodes of hypoxemia and/or bradycardia, also defined as cardio-respiratory events (CRE) are very frequent in preterm infants and may result in transient hypoxia and hypoperfusion of target organs, with possible clinical implications. The hemodynamic instability that characterizes the first 72 hours of life, also called as transitional period, place preterm infants at high risk of complications and may contribute to enhance fluctuations in end-organ perfusion and oxygenation induced by CRE. In this study we aimed to explore cardiovascular and cerebrovascular changes determined by different CRE types in preterm infants during the transitional period.
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. Studies of automated control have shown that infants spend more time within their intended target oxygen saturation range. These have not included measurements of transcutaneous oxygen. The investigators aim to show the transcutaneous oxygen levels as well as the oxygen saturation levels when babies have their oxygen adjusted manually or automatically.
The aim of this study to evaluate the patients who underwent controlled hypotensive anesthesia under standardized depth of anesthesia; preoperative and postoperative blood HIF 1a, TAS, TOS measurement and cerebral perfusion evaluation with NIRS and to investigate tissue hypoxia secondary to hypotensive anesthesia and the changes of the mediators at the tissue level and which blood pressure parameters are related.
This study is meant to compare the amount of oxygen required for hypoxemia relief between current standard of care (oxygen only) and oxygen with the addition of high flow air for Chronic Obstructive Pulmonary Disease (COPD), Interstitial Lung Disease (ILD), and Pulmonary Hypertension (PH) patients during rest. Subjects will be titrated from 0 L/min until they maintain 95% SpO2 for each of the following delivery methods: 1. Pulses of pure oxygen (control) 2. Constant high flow air with pulses of pure oxygen 3. Out of phase pulses of high flow air and pure oxygen
This study uses an unconventional radiotherapy schedule developed at our institute, consisting of a short course high-dose partial irradiation targeting exclusively the hypoxic segment of a bulky tumors, which in our preliminary study has shown to be capable of inducing abscopal and bystander effects. This approach is delivered by using a stereotactic radiotherapy technique so as to spare nearby organs at risk including the peritumoral immune microenvironment from irradiation as much as possible. Our approach consists of a single or up to 3 radiotherapy doses of at least 10 Gy per fraction prescribed to the 70% isodose line encompassing the hypoxic target volume. Radiotherapy will be administered at the precise timing determined specifically for each patient based on the serially mapped homeostatic immune fluctuations by monitoring the blood levels of the cytokines and inflammatory markers over the 2 weeks prior to irradiation. This is done in order to synchronize the radiation treatment with the favorable, most active anti-tumor immune system phase, so as to stimulate and increase anti-tumor immune system activity. This is a monocentric, prospective, two-arm, phase I proof of principle study in which the investigator will enroll subjects with oligometastatic and/or locally advanced (N+) cancers with at least one "bulky" lesion (maximum diameter of at least 6 cm or greater). Patients with life expectancy of at least 3 months, who are ineligible for systemic therapy or experience disease progression with systemic therapies will be included. Radiotherapy will be administered to arm 1 at an estimated "less favorable time-position in immune cycle", while the second arm will have it administered at the estimated "most favorable time-position in immune cycle". The primary endpoint will be the response rate of the non-targeted effects both bystander (local, at the level of the partially treated bulky tumor) and abscopal (distant, at the non-treated metastatic sites), defined as a tumor regression of at least 30%. Secondary endpoints will be safety, survival and analysis of the best timing for the administration of radiotherapy.
the study is conducted on hypoxic adult patients underwent open heart surgery after arrival to the intensive care unit and stabilization of patients' hemodynamics to assess the efficacy of transalveolar pressure measurement as an index for lung recruitment.