View clinical trials related to Acute Lung Injury.
Filter by:Current clinical prediction scores for acute respiratory distress syndrome (ARDS) have limited positive predictive value. No studies have evaluated predictive kinetics of plasma biomarkers and receptor for advanced glycation end products (RAGE) polymorphisms in a broad population of critically ill patients or as an adjunct to clinical prediction scores. The main objective of the investigators study is to evaluate the predictive values of plasma soluble RAGE levels for the onset of ARDS in a high risk population of patients admitted to the intensive care unit (ICU). One of the investigators goals is to improve early identification of patients at risk for ARDS in order to better implement preventive stategies prior to ARDS development. The primary outcome is the occurrence of ARDS during the first week after admission to the ICU.
Acute respiratory distress syndrome (ARDS) is characterized by acute bilateral pulmonary infiltrates and impairment of oxygen uptake. For example, pneumonia can cause the development of ARDS. Despite modern intensive care treatment, mortality in ARDS patients remains high (40%). Invasive mechanical ventilation (MV) is the mainstay of ARDS treatment. Controlled MV is the conventional ventilation strategy to ensure lung protective ventilation (low tidal volumes) and recovery of the lungs. However, among disadvantages of controlled MV are the development of respiratory muscle atrophy (due to disuse) and the need for high dose sedatives to prevent patient-ventilator asynchrony. The use of high doses of sedatives and respiratory muscle weakness are associated with increased morbidity, worse clinical outcomes and prolonged MV. Besides controlled MV, a patient can be ventilated with supported ventilation. Supported MV decreases the likelihood to develop muscle atrophy, improves oxygenation and hemodynamics, and lowers consumption of sedatives. However potential disadvantages of supported ventilation include generation of too high tidal volumes, especially in patients with high respiratory drive. A previous study in healthy subjects has shown that titration of neuromuscular blocking agent (NMBA) can decrease activity of inspiratory muscles, while maintaining adequate ventilation. It is hypothesized that low dose NMBA may enable supported MV with adequate tidal volumes, in patients with high respiratory drive.
In modern anesthesia practice, the application of cricoid pressure during intubation is not infrequently used with the goal of preventing gastric-to-pulmonary aspiration. The evidence to support this practice is very scarce, and there have recently been many reports in the literature questioning the safety of cricoid pressure during intubation. Therefore, the goal of this study will be to randomize those at risk for microaspiration to receive cricoid pressure versus no cricoid pressure during intubation. We will specifically exclude those patients thought to be at the highest risk of aspiration (it is considered standard of care to perform cricoid pressure during intubation of this population). We will include those patients with some risk factors for aspiration (it is not considered standard of care to apply cricoid pressure during intubation of this population).
The purpose of this study has two major goals: 1) to measure the amount of two specific hormones interleukin (IL)-10 and interleukin (IL)-12p70 in mucous and blood; and 2) compare the hormone levels in two specific areas of the lung called the trachea (upper airway) and the bronchioles (lower airway). The hormones IL-10 and IL-12p70 are cytokines, special hormones cells use to communicate with each other during inflammation or infection. Cytokines can be measured in mucous and blood. The balance of one cytokine compared to another help doctors to understand how people respond differently to infection. Unfortunately, the amount of IL-10 and IL-12p70 is not known in children, especially children with a lung infection. In addition, we do not know if the balance of these cytokines differ in various regions of the lung. We believe the balance of IL-10 and IL-12p70 is similar whether measured in the upper or lower airways.
Aim: The purpose of this study is to evaluate the use feasibility of FreeO2 so as to deliver automatically oxygen in the emergency department in a patient population admitted for acute respiratory failure. Hypothesis: The principal hypothesis is that FreeO2 is possible and well-accepted by nurses and medical personnel and there are advantages to use this system. In comparison with the common oxygen delivery (the rotameter), the hypothesis is that FreeO2 system will make for a better control of the oxygen saturation in function of designed target, reducing the desaturation time and hyperoxia. We think that oxygen weaning will be faster than classical way if it is automated. In addition, FreeO2 could reduce the number of intervention by nurse personnel.
Recent data from large trials of high-frequency high frequency oscillation (HFO) without a cuff leak vs, lung-protective conventional ventialtion (CMV) failed to show any HFO-related benefit with respect to outcome. A possible explanation is that HFO increases the probability of right ventricular dysfunction due to the combination of high mean airway pressures (mPaws) and hypercapnia. In contrast, available preliminary data on low-frequency HFO-tracheal gas insufflation (TGI) with cuff leak vs. CMV are suggestive of an HFO-TGI related benefit. Low-frequency HFO-TGI with a cuff leak is associated with relatively low mean tracheal pressures and adequate control of PaCO2. Thus, the investigators intend to test the hypothesis that low frequency HFO +/- TGI with a cuff leak is associated with better right ventricular function relative to high-frequency HFO without a cuff leak.
In a recent experimental study, the investigators showed that the growth factor Activin A is expressed in the lungs of rats with the acute respiratory distress syndrome (ARDS) at levels that are comparable with those determined in the bronchoalveolar (BAL) lavage fluid from patients with ARDS. In the same study, the administration of the Activin A inhibitor Folistatin resulted in attenuation of the histological damage of the ARDS-afflicted rat lung. The precise role of Activin A/Folistatin in acute respiratory failure associated with acute lung inflammatory pathology has not been elucidated yet. Therefore, the purpose of the present, observational study is to investigate the role of Activin A/Folistatin in respiratory failure due to ARDS and/or ventilator-associated pneumonia (VAP), also in relation with other biochemical markers, such as cytokines and surfactant-related proteins.
We wish to prospectively assess the burden of, management and therapeutic approaches to, and outcomes from acute hypoxaemic respiratory failure requiring ventilatory support, during the winter months in both the northern and southern hemispheres. We wish to specifically examine the contribution of ARDS as defined by the Berlin Definition to the burden of hypoxaemic respiratory failure. Why? The purpose of this study is to provide new and current data on the disease burden of acute hypoxemic respiratory failure and ARDS. It will answer the following questions: - What is the frequency and disease burden of acute hypoxaemic respiratory failure in winter? - What are the aetiologies of acute hypoxaemic respiratory failure requiring ventilatory support? - What is the incidence of ARDS based on the Berlin definition within this patient cohort? - What is the mortality from ARDS within this cohort, and how does this vary based on ARDS severity? - What is the natural history of ARDS? - What are the key patterns of therapeutic resource utilization, particularly approaches to sustain gas exchange, in these patients? When? The study is performed over a 4 week period between February 1st and March 31st 2014 in the Northern Hemisphere and June 1st to August 31st in the Southern Hemisphere. What data is required? A basic dataset is collected on all patients admitted with acute acute hypoxaemic respiratory failure requiring ventilatory support, with a more detailed dataset collected on patients diagnosed with ARDS.
The objective is determine the strain measured at the bedside could be a dynamic prognostic marker of during Acute respiratory Distress Syndrome (ARDS).
With the perception that lung protective ventilation with regard to low tidal volume ventilation and limiting airway pressures improves outcome in ARDS (acute respiratory distress syndrome) and that the development of new technical devices of extracorporeal lung assist systems with lower complication rates support establishment of lung protective ventilation strategies these systems are more and more frequently used. All critically ill patients with and without ECLA (extracorporeal lung assist)/ECMO (extracorporeal membrane oxygenation) treatment are on high risk for muscle wasting, leading to more comorbidity and higher mortality risk. Besides inflammation malnutrition is known as one of the main risk factors. Over and underfeeding should be prevented. However nutritional aspects of patients on extracorporeal lung assist are hardly investigated. Up to now changes in metabolic rates induced by ECLA/ECMO are poorly described. Factors like work of breathing, changes in cardiac output and septic state are influencing energy metabolism but until now there is no tool for measuring energy expenditure in clinical routine for patients on ECLA/ECMO. Indirect calorimetry is a simple device only for patients without ECLA/ECMO system. Oxygenation and CO2 (carbon dioxide) elimination by the lung assist system can be calculated but is not implemented to clinical routine. The combination of indirect calorimetry and calculation of lung assist function at the same time would give us the chance to adapt nutrition rates to energy expenditure. This may prevent muscle wasting and weakness. This pilot study will include 40 participating patients during 8 month investigating nutritional therapy adapted to energy expenditure calculated by O2 and CO2 turnover rates in patients on ECLA or ECMO systems. The investigators aim is to describe a calculation to set nutrition targets in ECMO patients. Second the investigators will describe level of nutritional needs under consideration of different mechanical ventilation states. Third O2 consumption and CO2 elimination will be used to estimate cardiac output.