View clinical trials related to Lung Injury.
Filter by:In 2008 a new ventilation strategy termed variable Pressure Support ventilation (PSV) was introduced, which is able to increase the variability of the respiratory pattern independent from the inspiratory effort. In experimental lung injury, variable PSV was found to improve gas exchange and decrease the inspiratory effort, while reducing alveolar edema and inflammatory infiltration compared to conventional(non-variable) PSV. Importantly, variable PSV reduced peak airway pressure and respiratory system elastance in a variability dependent manner.In addition, preliminary observations suggest that variable PSV can reduce the work of breathing and improve patient comfort, but it is not known whether this new ventilatory strategy is able to speed the weaning from mechanical ventilation. Since variable PSV can reduce the mean pressure support, it may lead to a faster reduction of pressure support and, therefore, a shorter weaning period than conventional PSV. The hypothesis of this study is that variable pressure support ventilation reduces the duration of mechanical ventilation to non-variable (conventional) pressure support ventilation.
A certain molecule floating in the blood may represent a risk of lung injury after a transfusion. We are determining whether detection of this molecule on a simple blood clotting test will predict the development of lung injury due to transfusion in bleeding patients with chronic liver disease.
This study evaluates the use of nebulized hypertonic saline (aerosolized salt water) as a preventive treatment for post-traumatic acute lung injury (ALI). Both animal and human research indicate that aerosolized salt water might help reduce harmful inflammation with minimal risks.
Mechanical ventilation, although life-saving, damages the lungs through what is known as ventilator-induced lung injury. High frequency oscillation ventilation has been proposed as a ventilation method that may be less injurious to the lungs than conventional mechanical ventilation and may lead to better patient outcomes. To evaluate this hypothesis, the OSCILLATE trial is comparing outcomes in patients with the acute respiratory distress syndrome randomized to high frequency oscillation ventilation vs conventional lung protective ventilation. The present study is a substudy of the OSCILLATE trial looking at biomarkers of ventilator-induced lung injury in blood samples drawn from patients enrolled in OSCILLATE. The objective is to look for biochemical evidence of decreased ventilator-induced lung injury in patients treated with high frequency oscillation ventilation relative to conventional ventilation.
The main objective of this randomized multicenter clinical trial is to test the hypothesis that further reduction of VT to 4mL/kg may enhance lung protection in patients with ARDS as compared to the conventional "ARDS-Net" ventilation. Control of PaCO2 in the ~4 ml/kg arm would be accomplished by LFPPV- ECCO2-R.
To determine whether specialized enteral nutrition support can improve oxygenation status in critically ill patients with acute lung injury (ALI) or acute respiratory distress syndrome (ARDS) comparing to a standard enteral nutritional formula.
Transfusion-related acute lung injury (TRALI) is the most common cause of transfusion-related morbidity and mortality in the United States. It is very common and often unrecognized in the critically ill with the greatest incidence occurring in bleeding patients with liver disease. Plasma is the most blood component associated with this deadly complication and therefore patients with liver disease who frequently receive transfused plasma are at increased risk. The optimal plasma transfusion strategy for bleeding patients with liver disease is unknown and the investigators will evaluate this clinical question in a small pilot randomized controlled trial. The invstigators hypothesize that targetting a more restrictive INR Target (2.5) vs. an INR Target (1.8) will result in less hypoxemia, a TRALI surrogate without increasing bleeding complications.
Acute lung injury (ALI) and the acute respiratory distress syndrome (ARDS) represent a spectrum of clinical syndromes of rapid respiratory system deterioration that are associated with both pulmonary and systemic illness. These syndromes are associated with 30-40% mortality with our current standard of care and are responsible for approximately 75,000 deaths in the US yearly. Current evidence-based care of ALI consists of a strategy of mechanical ventilation utilizing low lung volumes (ARDSNet ventilation) intended to limit further stretch-induced lung injury exacerbated by the ventilator. However, this strategy has been shown to be associated with increased lung injury in a subset of patients and still is associated with about a 30% mortality rate. Airway pressure release ventilation (APRV) is a different, non-experimental strategy of mechanical ventilation currently in routine clinical use. APRV is a pressure-cycled ventilator mode that allows a patient a greater degree of autonomy in controlling his or her breathing pattern than ARDSNet ventilation. Use of APRV has been associated with better oxygenation, less sedative usage, and less ventilator-associated pneumonia in small studies compared with other ventilator modes. However, debate exists over whether APRV might result in decreased or increased ventilator-associated lung injury when compared with ARDSNet ventilation. We intend to implement a randomized, cross over study looking at biomarkers of lung injury in patients with acute lung injury during ventilation with APRV and using the ARDSNet protocol. Our hypothesis is that airway pressure release ventilation is associated with lower levels of lung injury biomarkers than ARDSNet ventilation.
Objective: assess the efficacy and safety of oral rosuvastatin in patients with sepsis-induced Acute Lung Injury (ALI). Hypothesis: Rosuvastatin therapy will improve mortality in patients with sepsis-induced ALI.
Acute lung injury (ALI) and acute respiratory distress syndrome (ARDS) are similar conditions in which the lungs are critically injured by another inflammatory process in the body. Together they affect more than 150,000 people per year in the United States, with mortality approaching 50% and a financial burden estimated to exceed $5 billion. Fluid overload, weight gain, and reduced oncotic pressure (low blood proteins) are associated with prolonged need for mechanical ventilation and mortality in patients with ALI/ARDS. Historical studies have provided conflicting evidence for benefits with colloid or diuretic therapy in ALI/ARDS, but recent clinical trials have demonstrated significant improvements in blood oxygen levels. The mechanisms of these benefits are not yet certain, but appear to relate to albumin's (a protein medicine) specific ability to influence injury and inflammation in the lungs, thus improving the ability for the lung to repair and exchange oxygen. The purpose of this project is to determine the effects of therapies that affect blood proteins on their ability to change the way the lungs and cardiovascular system (heart and blood vessels) function. Special measurements will be taken to understand how these protein medicines change the ability of the lung and whole body to recover from widespread injury, with additional measures of specific heart and lung function. This clinical trial randomizes ALI/ARDS patients with low blood protein levels to receive albumin (a natural blood protein that is known to influence inflammation) or hetastarch (a synthetic blood protein) with diuretic therapy targeted to improve respiratory function. Therapeutic effects on respiratory function and blood oxygen levels, extravascular lung water, oncotic pressure, lung fluid removal, and heart function will be characterized. This trial will advance our understanding of treatment of ALI/ARDS and the factors that affect fluid balance in the lungs of these patients. Funding Source - FDA OOPD