View clinical trials related to Acute Lung Injury.
Filter by:Mortality in Acute Respiratory Distress Syndrome is high (40 to 60 %). Protective mechanical ventilation, until 2010, was the cornerstone of the ARDS therapeutic strategies. Recently, a prospective multicenter study demonstrates that a 48h continuous infusion of neuromuscular blocking agents (NMBA) have a positive impact on mortality of ARDS patients. (Papazian et al. ACURASYS Study. NEJM 2010; 363:1107-16). The mechanisms through which NMBAs could improve survival remain speculative. They are as follows: - reduction of the consumption of oxygen linked to ventilatory workload; - increase of chest wall compliance improving mechanical ventilation during ARDS and better adaptation to the protective ventilation strategy; - anti-inflammatory effect contributing to a reduction in pulmonary inflammation and improvement in oxygenation, - reduction of the variations of transpulmonary pressure (TPP) by the way of better synchronisation between patient and the ventilator. The use of NMBA could also reduce the ventilator induced lung injury by a better control of TPP.
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.
Seriously ill patients may develop a complication called acute lung injury (ALI), a form of inflammation in which lung tissue is filled by fluid containing white blood cells called neutrophils. ALI is common and is often fatal (for example in the USA it is estimated that 190,000 patients develop ALI per annum, of whom 75,000 die). No pharmacological treatment has been shown to improve ALI. Data from animal models and patients strongly suggest that neutrophils are central to disease progression. However no bedside methods exist to rapidly and accurately determine in seriously ill patients, if neutrophils are present and if they are releasing damaging enzymes such as elastase. As such, the investigating team have developed and synthesised to clinical grade, an imaging agent called NAP (Neutrophil Activation Probe) that detects activated neutrophils and also the damaging enzyme, human neutrophil elastase (HNE). The investigators have extensively tested NAP in animal models for efficacy and safety. It reliably detects activated neutrophils and is not toxic. NAP is a small molecule that is delivered in tiny doses (called microdoses) to areas of inflammation in human lungs through a bronchoscope. The activity of NAP is visualised by imaging though a tiny camera that is also introduced through the bronchoscope. This camera system is now widely used throughout the world in over 150 sites. The investigators therefore aim to test the utility and safety of NAP in an exploratory clinical study. The study involves the delivery of NAP to 6 healthy volunteers followed by delivering NAP to 3 patients in ICU with pulmonary infiltrates and 6 patients known to have bronchiectasis. In the healthy volunteers study, healthy male volunteers recruited from the University of Edinburgh will be invited to participate. In the ICU study, patients will be recruited from the ICU in the Royal Infirmary of Edinburgh. In the bronchiectasis study, patients will be recruited from the respiratory service in NHS Lothian. If the study (which is supported by the Medical Research Council) demonstrates safety and also the ability to image activated neutrophils, the investigators intention is to design future studies in patients with ALI.
PiCCO has been widely used in critical care settings for several decades. Together with pulmonary artery catheter, it is regarded as the important tool for guiding fluid management in patients with shock or acute respiratory distress syndrome. However, its effects on patients' outcome remain untested. The investigators study is a pilot study that is designed to test whether the use of PiCCO will improve patients' outcome, as compared to those without PiCCO monitoring.
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.
Neurally-Adjusted Ventilatory Assist (NAVA) is a ventilatory mode that uses the electrical activity of the diaphragm to control the mechanical ventilator, offering inspiratory assistance in proportion to respiratory effort to patients who need artificial ventilatory support. It has been shown to improve the interaction between the patient and the mechanical ventilator in several clinical situations, but no previous studies have tried to use it for patients with a severe type of respiratory insufficiency, called Acute Respiratory Distress Syndrome (ARDS). Patients with ARDS benefit from a mechanical ventilatory strategy that includes low inspiratory volumes (tidal volumes) and limited airway pressures, but the application of such strategy frequently requires high levels of sedation. The investigators' hypothesis is that NAVA can be used for patients with ARDS, and that it will not be associated with excessive tidal volumes or elevated airway pressures.
What is the effect of early high frequency oscillation (HFO) versus a lung-protective conventional ventilation (CV) strategy (using HFO only as rescue therapy), on all-cause hospital mortality among patients with severe early acute respiratory distress syndrome (ARDS)?
The purpose of this study is to determine if a protective ventilatory strategy during one-lung ventilation (OLV) based on low tidal volume, PEEP and alveolar recruitment maneuver can reduce Acute Respiratory Distress Syndrome (ARDS) and Postoperative pulmonary complications (PPCs) after major pulmonary resection. Primary endpoint: Evaluation of postoperative ARDS incidence Secondary endpoint: Evaluation od PPC incidence and postoperative outcomes (other complications, unplanned Intensive Care Admission, hospital and ICU length of stay, in-hospital mortality)
This is a multi-center, phase, phase II double-blind, placebo-controled, randomized trial of aspirin for the prevention of acute lung injury in patients identified as at risk for acute lung injury.
Metabolomics, or metabonomics, is a large-scale approach to monitoring as many as possible of the compounds involved in cellular processes in a single assay to derive metabolic profiles. Metabolomics allows for a global assessment of a cellular state within the context of the immediate environment, taking into account genetic regulation, altered kinetic activity of enzymes, and changes in metabolic reactions. Metabolomics may be useful for understanding metabolic imbalances and for diagnosis of human disease. The investigators plan to collect exhaled breath condensate from patients with acute lung injury. Metabolomic analysis in the patients may help us to explore some novel biomarkers for the disease diagnosis and outcome prediction.