Active clinical trials for "Lung Injury"

Hypothesis: In this feasibility study, hyperoxemia, as approximated by transcutaneous hemoglobin saturation with oxygen (Sp02), at the time of birth will cause sustained pulmonary oxidative stress as demonstrated by elevation of pulmonary protein carbonyl. Furthermore, this oxidative stress will be directly proportional to the imposed oxygen-burden during resuscitation at the time of birth. This study will give us information regarding the magnitude of protein carbonyl elevation in the preterm infant. With these results we will be able to 1. establish the technique for the running or protein carbonyl assays and 2. calculate an appropriate sample size for a future randomized control trial.

Randomized controlled trial comparing low inspiratory and expiratory flow during variable volume ventilation with a constant volume decelerating flow (pressure controlled volume guarantee) ventilation.

The present pilot randomized controlled clinical trial will test the hypothesis that in patients with ARDS, fixing ventilator settings to the conventional protective ventilatory strategy (VT 6 ml/kg ideal body weight and Pplat ≤ 30 cmH2O, PEEP according the PEEP/FiO2 table), control modes of mechanical ventilation will be associated to a concentration of pulmonary and systemic inflammatory mediators lower than the concentration of inflammatory mediators observed during assisted modes of mechanical ventilation.

The goal of this study is to evaluate the utilization of conventional 'thermally' polarized perfluorinated gases mixed with oxygen as an exogenous inert contrast agent to image the airway spaces in subjects with suspected lung disease, post deployment in Iraq and Afghanistan. This is an open label proof of concept study expanding on work here at Duke.

The purpose of this study is to investigate whether the use of inhaled anesthetics, compared to intravenous anesthetics, can affect the amount of lung inflammation and postoperative respiratory complications seen after cardiac surgery.

APRV mode of ventilation will result in an improved partial pressure of arterial oxygenation/ fraction of inspired oxygen (P/F ratio) on day 3 of mechanical ventilation. Sub hypotheses: APRV will be associated with a reduced amount of sedation used during the ICU stay in patients with respiratory failure. APRV will be associated with a reduction in the amount of vasoactive medication used for blood pressure support in patients with respiratory failure.

The purpose of this study is to investigate the change of extravascular lung water (EVLW), cytokine and oxygenation parameters in patients with acute lung injury (ALI) or acute respiratory distress syndrome (ARDS) after alveolar recruitment maneuver.

The primary goal of this study is to measure changes in biological markers of inflammation in critically-ill patients with acute lung injury (ALI) or acute respiratory distress syndrome (ARDS) while they are treated with different styles of lung-protective, artificial breathing assistance. Secondary goals are to measure the breathing effort of patients using different artificial breathing patterns from the breathing machine. The primary hypothesis is that volume-targeted artificial patterns will produce less inflammation. The secondary hypothesis is that volume-targeted artificial patterns will increase breathing effort compared to pressure-targeted artificial patterns.

Methamphetamine and amphetamine has various cardiovascular and central nervous system effects. Long-term use is associated with many adverse health effects including cardiomyopathy, hemorrhagic, and ischemic stroke. Death is usually caused by cardiovascular collapse and while amphetamine abuse has been considered as a potential cause of acute respiratory distress syndrome, the reports are usually anecdotal. This investigation considers reviewing individuals with few to zero medical conditions who develop acute respiratory distress syndrome and are methamphetamine positive

Mechanical ventilation is frequently used in the operating room and the intensive care settings. Although essential in many cases, mechanical ventilation can be responsible for ventilator-induced lung injury (VILI). The relationship between mechanical ventilation and VILI has been clearly demonstrated in animals and is highly suspected in humans. The putative mechanism responsible for VILI is excessive pulmonary strain or overdistension. Frequently observed in mechanically ventilated patients, the presence of a severe pre-existing pulmonary disease can increase the risk of overdistension. The development of a tool allowing early detection of pulmonary overdistension would represent a great asset in the prevention of VILI by allowing safer adjustments of mechanical ventilation parameters. Ultrasonographic imaging is a non-radiant, non-invasive technique already available in the intensive care setting. Already used for cardiac strain measurements, ultrasonography is a promising avenue to assess pulmonary strain. This pilot study will aim to create a small dataset of local pleural strain values assessed at predetermined pulmonary areas using ultrasound imaging in patients undergoing thoracic surgery requiring one-lung ventilation. This dataset will be used to help plan larger scale studies.