View clinical trials related to Acute Lung Injury.
Filter by:The diaphragm is a fine striated muscle with both extra respiratory and respiratory functions. It does most of the breathing work in interaction with the accessory respiratory muscles, the rib cage and the abdomen. Its activity can be measured by the transdiaphragmatic pressure generated by the magnetic stimulation of phrenic nerves (gold standard). It has been shown in the literature that diaphragmatic ultrasound, via the measurement of diaphragmatic excursion and especially the thickening fraction, is an easily accessible, non-invasive, reproducible and relevant technique for evaluating acute diaphragmatic dysfunction in resuscitation patients. The objective of this project is to evaluate the prevalence of diaphragmatic dysfunction at admission in patients hospitalized in intensive care / respiratory intensive care unit for hypercapnic and/or hypoxic acute respiratory distress and requiring ventilatory support by non-invasive ventilation or high flow oxygen therapy. A subgroup analysis will then be carried out on 3 populations: - Hypercapnic exacerbation of chronic obstructive pulmonary disease - Hypoxic acute respiratory distress on infectious lung disease - Acute pulmonary edema
The acute respiratory distress syndrome (ARDS) is a severe form of respiratory failure with a mortality rate of approximately 40%. Despite advances in its supportive treatment such as lung protective ventilation or restrictive fluid management, no effective pharmacotherapy exists to treat ARDS. Emerging preclinical data indicates that excessive activation of the inflammasome-Caspase 1 pathway plays a key role in the development of ARDS. Tetracycline has anti-inflammatory properties via inhibiting inflammasome-caspase-1 activation. Since not much is known about the activation of the inflammasome in clinical ARDS, the purpose of this study is i) to investigate the the inflammasome-caspase-1 activation in clinical ARDS and ii) inhibit the innate immune response of alveolar leucocytes obtained by tetracycline from patients with ARDS
With the birth of Mechanical Ventilation in the 1950s came the ventilation induced lung injuries (VILI). Numerous works have since then shown the benefit of "protective ventilation", notably by controlling the delivered tidal volume and pressures. However, as the respiratory condition improves and the weaning is started by shifting to Pressure Support Ventilation (PSV), these parameters stop being tightly controlled. This study aims to determine whether there is a relationship between the driving pressure measured in PSV and the weaning time.
Treatment of patients with Hypoxemic respiratory failure (HRF) and Acute Respiratory Distress Syndrome (ARDS) is complex. Therapies that have been shown to save the lives of patients with HRF and ARDS are available but they are not always provided. To reduce practice variation and improve adherence to evidence-informed therapies, the investigators developed the Treatment of Hypoxemic Respiratory Failure (HRF) and ARDS with Protection, Paralysis, and Proning (TheraPPP) Pathway. The purpose of this pilot study is to test the feasibility and acceptability of the TheraPPP Pathway. To assess feasibility, the investigators will test the ability to measure adherence to the pathway as well as patient and economic outcomes. To assess perceptions about the acceptability of the TheraPPP Pathway, the investigators will conduct a survey to clinicians who used the Pathway.
Mortality rates in children with pediatric acute respiratory distress syndrome (PARDS) are higher in Asia compared to other regions. In adults with acute respiratory distress syndrome, the only therapy that improves mortality rates is a lung protective ventilation strategy. The pediatric ventilation recommendations are extrapolated from evidence in adults, including ventilation with low tidal volume, low peak/plateau pressures and high-end expiratory pressure. A recent retrospective study of ventilation practices in Asia showed varying practices with regards to pulmonary and non-pulmonary therapies, including ventilation. This study aims to determine the prevalence and outcomes of PARDS in the Pediatric Acute and Critical Care Medicine Asian Network (PACCMAN). This study will also determine the use of pulmonary (mechanical ventilation, steroids, neuromuscular blockade, surfactant, pulmonary vasodilators, prone positioning) and non-pulmonary (nutrition, sedation, fluid management, transfusion) PARDS therapies. To achieve this aim, a prospective observational study which involves systematic screening of all pediatric intensive care unit (PICU) admissions and collection of pertinent clinical data will be conducted. Recruitment will be consecutive and follow up will continue to intensive care discharge.
The purpose of this study is to show that inhaled steroids in patient with PARDS can decrease the days on mechanical ventilator measured by ventilator-free days,to improve the oxygenation index (OI) or oxygenation saturation index (OSI) in patients receiving inhaled steroids and to show the relevance and feasibility of a larger study by assessing the hypothesis in a small cohort of patients. Patient will be treated for a maximum of 10 days. Secondary objectives are to reduce the length of stay (LOS) in the pediatric intensive care unit (PICU) and hospital admissions; to show less inflammation in the patients receiving inhaled steroids by measuring inflammatory markers from tracheal aspirates like Interleukin (IL6, IL8, tumor necrosis factor (TNF) α, matrix metalloproteinase8 (MMP8) and matrix metalloproteinase9 (MMP9). Lastly, to show that inhaled steroids can improve residual lung disease evaluated by Pulmonary Function Test (PFTs) and Impulse Oscillometry (IOS).
Ventilator-induced lung injury is a common complication. The latest and most noticeable theory of its pathogenesis is called 'ergotrauma' by Gattinoni in 2016. The theory uses ventilator-imposed 'energy' or 'power' to encompass several known forms of injury-inducing factors such as pressure,volume, flow, rate, etc. However, to quantify power imposed by ventilator is no easy task in clinical practice. So, Gattinoni proposed a mathematical formula for easy power calculation. However, Gattinoni did not compare the difference between various etiologies of acute lung injury. We will enroll 100 patients (50 with acute respiratory distress syndrome and 50 with normal lung). The ventilator-imposed power at various tidal volume (6, 8, 10 ml/Kg) and positive end-expiratory pressure (5, 10 cmH2O) will be calculated by the formula. The area enclosed by hysteresis of pressure-volume curve, and hence the work it implies, will be measured as a standard. Our study will aim to compare the formula in different patient groups and in Taiwanese people.
Extracorporeal membrane oxygenation (ECMO) had been used to treat refractory hypoxemia associated with acute respiratory distress syndrome (ARDS). There were reported good outcome associated with ECMO for ARDS caused by influenza infection from several ECMO centers. However, the outcome of ECMO support in lower ECMO experience center had not been evaluated. This study aimed to evaluate the outcome of ECMO, comparing with conventional treatment among severe hypoxemic ARDS patients who were admitted in limited ECMO experience hospital.
Pulmonary recruitment maneuvers open these lung areas and appropriate adjustment of positive expiratory pressure (PEP) helps to stabilize recruitment and reduce the stress associated with alveolar opening and closing. Its beneficial effects in the lung affected by Acute Respiratory Distress Syndrome (ARDS) remain unclear. The hypothesis is that there is a heterogeneous effect of the recruitment maneuver according to the phenotype of ARDS. It is important to be able to define responder patients from non-responders to this recruiting maneuver.
The main objective of this study is to compare the pharmacokinetic models of sevoflurane-induced sedation during ARDS depending on the lung imaging phenotype (focal vs nonfocal phenotypes) The authors hypothesized that sevoflurane used for inhaled sedation could have distinct pharmacokinetic profiles depending on lung imaging phenotypes (focal vs nonfocal) during ARDS in ICU patients.