Active clinical trials for "Acute Lung Injury"

The main objective of this study is to show that "diaphragmatic excursion measures upon emergency admission" (CDA values) on patients with acute respiratory failure are predictive of the need to use mechanical ventilation (invasive or non-) in the first four hours.

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.

A new artificial lung device has been developed that potentially provides added support to mechanical ventilation for severely damaged lungs. The Hattler Respiratory Assist Catheter is designed to provide gas exchange (deliver oxygen and remove carbon dioxide) for a period of up to 7 days, providing more time for the lungs to improve. Extrapolating from large animal data, the hypothesis is that the Hattler Catheter will be capable of providing 30% to 40% of the basal requirements of carbon dioxide exchange in a manner that is dependable and reproducible.

The purpose of this protocol is to perform serial physiological measurements and blood testing on mechanically ventilated patients comparing conditions of eucapnia and hypercapnia in the same patient. We will be testing two hypotheses: (1) while administering inspired carbon dioxide (CO2), eucapnia achieved by high respiratory rate (EHR) significantly decreases pulmonary artery pressures compared to hypercapnia with a lower respiratory rate (HLR), and (2) that EHR decreases myocardial strain compared to HLR.

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.

The prevalence of severe dyspnoea among terminally ill patients has been reported as 70% and 90% for lung cancer and chronic obstructive pulmonary disease (COPD) patients, respectively. Current management to dyspnoea includes opioids, psychotropic drugs, inhaled frusemide, Heliox 28 and oxygen. Conventional oxygen supplementation is often used in these patients, but it may be inadequate, especially if they require high flows (from 30L/min to 120L/min in acute respiratory failure). High-flow oxygen nasal cannula (HFONC) is a new technological device in high-flow oxygen system that consists of an air-oxygen blender (allowing from 21% to 100% FiO2) which generates the gas flow rate up to 55 L/min and a heated humidification system. This technology may have an important role in reducing respiratory distress in do-not-intubate patients. Some HFONC's beneficial effects are the washout of the nasopharyngeal dead space reducing rebreathing of CO2 and improvement oxygenation through greater alveolar oxygen concentration; a better matching between patient's inspiratory demand and oxygen flow; generation of a certain level of positive pressure (PEEP) contributing to the pulmonary distending pressure and recruitment; improvement of lung and airway mucociliary clearance due to the heated and humidified oxygen; and patient's comfort because of the nasal interface allowing feeding and speech. The investigators hypothesize that patients supported with HFONC need less opioids to decrease dyspnoea.

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

Prone positioning has been widely used in critical care medicine to improve oxygenation in patients with acute respiratory distress syndrome (ARDS). This study aimed to compare the effect of pronation on lung ventilation-perfusion matching between COVID19-associated acute respiratory distress syndrome (CARDS) and ARDS from other etiologies (non-CARDS) using electrical impedance tomography (EIT).

This is study 1 of 3 - of the overall project: The ProneTection Quality Improvement Project. The three aims of this study, study 1 are: to establish the training needs critical care clinicians have regarding prone positioning, to investigate the conditions for effective implementation as in an intensive care setting, to develop an education and training package (The ProneTection package) for an interdisciplinary team of clinicians on skin damage prevention of patients in the prone position

RAGE (the receptor for advanced glycation end-products) is a marker of alveolar type I cell injury and a pivotal mediator of acute inflammation and innate immunity. RAGE pathway is highly regulated; the interaction of the transmembrane receptor with its various ligands (e.g. HMGB1, S100A12) ultimately leads to NF-kB activation and RAGE upregulation itself, but precise RAGE functions and intracellular pathways remain underexplored. During ARDS, monocyte and macrophage activation could modulate alveolar inflammation and repair. As RAGE is also expressed at the surface of monocytes/macrophages, we hypothesize that alveolar monocyte/macrophage activation may be mediated through a RAGE-TXNIP (thioredoxin interacting protein)-NLRP3/inflammasome intracellular pathway. The purpose of this observational prospective study is to compare alveolar monocyte/macrophage activation profiles (as assessed by Fluorescence-Activated Cell Sorting (FACS)) in mechanically ventilated patients with or without ARDS.