View clinical trials related to Acute Lung Injury.
Filter by:The purpose of this study in patients suffering from acute lung injury is to determine whether positive end-expiratory pressure (PEEP) setting guided by electrical impedance tomography (EIT) influences pulmonary gas exchange, lung mechanics, ventilation/perfusion matching and homogeneity of regional ventilation when compared to other PEEP setting strategies such as the open lung concept or the ARDSnet protocol.
Elective open aortic aneurysm repair has an overall reported 30 day mortality of 2-6 percent, but in patients more than 65-70 years the mortality is reported to be more than 10 percent. The phenomenon of acute lung injury (ALI)/adult respiratory distress syndrome (ARDS) after infra renal abdominal aneurysm repair caused by ischemia-reperfusion is well established. The degree of disability varies from a light degree of acute respiratory failure to mortality for patients with the same profile of risk. Primary aim is to develop a model that monitors inflammatory marker molecules collected from the bronchial epithelial lining fluid by microdialysis. The method with examination of the bronchial epithelial lining fluid by microdialysis and analysis of multiple inflammation markers as previously done by the investigators group.
Patients with severe lung conditions occasionally require support with a special ventilator (breathing machine) called the High Frequency Oscillator (HFO). Effective ventilation requires that the pressure generated by the ventilator be as high as possible but not too high as this can damage the lungs. In patients on HFO, there is not a well defined way to measure this pressure. We will insert a small probe into the esophagus of patients on HFO to see if this is an accurate way to measure lung pressures for these patients. A better understanding of these pressures could lead to improved patient care.
The aim of the study is to compare, in patients with acute respiratory failure/acute lung injury the efficacy of three different methods of oxygenation to prevent endotracheal intubation : 1. conventional oxygen therapy (O2 conventional) 2. high flow nasal oxygen therapy (O2-HFN) 3. association of high flow nasal oxygen therapy with non invasive positive pressure ventilation (O2-HFN/NPPV).
This study aims to test the effectiveness of a single intravenous (IV, through the vein) dose of the study drug, bevacizumab (Avastin), in preventing/reducing the development of Acute Respiratory Distress Syndrome (ARDS), in patients with severe sepsis, who are at high risk for developing ARDS. ARDS is a lung disease caused by a lung injury that leads to lung function impairment. The condition the patient has,severe sepsis, is a medical condition associated with an infection characterized as an immune system inflammatory response throughout your whole body that can lead to organ dysfunction, low blood pressure or insufficient blood flow to one or more of your organs.
Term and near term newborns can present acute respiratory distress syndrome (RDS). Surfactant treatment has been shown effective in reducing mechanical ventilation and oxygen treatment durations in the preterm newborn. Whether surfactant treatment is beneficial for term and near term newborns is unknown. The purpose of this study is to compare surfactant treatment vs. nasal continuous positive airways pressure in the newborn between 35 and 41 weeks of gestation with RDS within the first 24 hours of life. The study's primary endpoint is "survival with no oxygen treatment at 72 hours of life". The secondary endpoints are: death, surfactant treatment, pneumothorax, secondary infections, pulmonary hypertension, inhaled nitric oxide treatment, fluid loading treatment, vasopressive amines treatment, mechanical ventilation duration, nCPAP treatment duration, Oxygen treatment duration, Oxygen treatment at 28 days of life, hospitalization duration and treatment strategy cost.
Identify pediatric oncologic patients with ALI/ARDS at GRAACC/IOP's Pediatric Intensive Care Unit and evaluate the mechanical ventilation practice in these subjects for a 48mo period.
During the past two decades, there current concept has evolved significantly that ventilator-induced lung injury (VILI) may not only impose a direct mechanical stress and subsequent injury to the lungs, but may also induce local as well as systemic inflammation responses, generally referred as biotrauma.1 Patients with ARDS often die of severe systemic inflammatory response syndrome (SIRS) and multiorgan dysfunction2 rather than refractory hypoxemia. Ranieri et al found that patients with less severe ARDS, i.e., a lung injury score of 2.5 or less, receiving ventilation with lung protective strategy involving low tidal volume (7.5 mL/kg PBW) and high PEEP could attenuate the pulmonary and systemic cytokine response compared with conventional ventilation with high tidal volume.3 Stuber et al found an increase in pro-inflammatory cytokines in the lung and plasma of patients with ARDS within 1 hour after switching the patients from a protective to non-protective ventilator strategy.4 The receptor for advanced glycation end-products (RAGE) was recently identified as a marker of injury to the alveolar type I epithelial cells5. Clinical studies showed that the plasma level of RAGE was associated with severity of lung injury and clinical outcome, and low tidal volume strategy ventilation accelerated the decline in plasma RAGE levels. These results suggest plasma RAGE level might be a reliable biomarker of alveolar epithelial injury in acute lung injury and may associated with ventilator induced lung injury6. Although, current approach to mechanical ventilation of a patient with ARDS emphasizes the use of lower tidal volumes with lower plateau pressures to avoid causing lung overdistension and ventilator associated lung injury (VILI)7; however, in the real world, some studies showed that strictly reduction of tidal volume to 6ml/kg PBW was modest in modern time, and was noticed only in patients with greater lung injury scores8. The benefit of VT strictly reduction to 6ml/kgPBW and its effect on VILI in patients with less severe ARDS whose Pplat are already below 30 cmH2O are controversy9. One of the possible solutions is to look at the biomarkers of injury to alveolar epithelial cells. Of these potentially promising markers, the receptor for advanced glycation end-product (RAGE) is of great interest. We hypothesize that a strategy with strict low tidal volume in less severe ARDS and ALI patients with good compliance may be beneficial to this patient population. Therefore, we wish to propose a prospective single-center study to investigate the effect of mechanical ventilation strategy on the plasma level of RAGE in patients with less severe ARDS and acute lung injury.
The purpose of this study is to demonstrate that mechanical ventilation guided by the diaphragm EMG signal (also know as neurally adjusted ventilatory assist [NAVA]) is superior compared to pressure support and pressure control ventilation.
Severe sepsis/septic shock is a serious condition associated with high mortality rate. Hydrocortisone has been recommended as a useful treatment to decrease mortality in hemodynamically unstable septic shock patients, not response to fluid and moderate dose of vasopressor. During the progression of severe sepsis/septic shock, multi-organ dysfunction can develop. Acute lung injury (ALI) and its more severe form, acute respiratory syndrome (ARDS) is one of the common organ dysfunction associated with septic shock. Information from a meta-analysis suggested that moderate dose of hydrocortisone may improve the ARDS patients' outcome. Whether hydrocortisone can effectively prevent disease progression and death in severe sepsis/septic shock patients who complicated with ALI/ARDS has not been proven.