Active clinical trials for "Acute Lung Injury"

The goal of this clinical trial is to compare flow-controlled ventilation (FCV) and pressure-controlled ventilation (PCV) in patients with moderate to severe acute respiratory distress syndrome on the intensive care unit. The main questions it aims to answer are: Is the mechanical power during flow-controlled ventilation lower than during pressure-controlled ventilation To gain more understanding about other physiological effects and potential benefits of flow-controlled ventilation in comparison to pressure-controlled ventilation (o.a. the end-expiratory lung volume and homogeneity of ventilation). Participants will be randomized between two ventilation mode sequences, being 90 minutes of FCV followed by 90 minutes of PCV or vice versa.

ASCEND researchers are partnering with families of children who receive extracorporeal membrane oxygenation (ECMO) after a sudden failure of breathing named pediatric acute respiratory distress syndrome (PARDS). ECMO is a life support technology that uses an artificial lung outside of the body to do the lung's work. ASCEND has two objectives. The first objective is to learn more about children's abilities and quality of life among ECMO-supported children in the year after they leave the pediatric intensive care unit. The second objective is to compare short and long-term patient outcomes in two groups of children: one group managed with a mechanical ventilation protocol that reserves the use of extracorporeal membrane oxygenation (ECMO) until protocol failure to another group supported on ECMO per usual care.

This is an observational - data and specimen collection study. There have been increasing reports of vaping-induced lung injury, including severe lung injury and rare cases of death. The mechanism by which vaping contributes to lung injury in susceptible persons is unknown, as is impact on chronic lung disease. The investigators aim to identify individuals with chronic electronic nicotine delivery device (ENDD) exposure and matched controls within our ongoing cohort of HIV+ and HIV-uninfected individuals, collect PFT data, bank respiratory and stool samples and collect clinical data for studies of clinical risk, inflammation, biomarkers, and the microbiome in the identification and modification of risk of progression to lung injury or chronic pulmonary disease.

The purpose of the study is to evaluate the efficacy of voxelotor for increasing oxygen saturation in 20 patients with hypoxemia. Specifically, the SpO2/FiO2 ratio will be compared before and after voxelotor use at rest and during exercise (ambulatory patients only). The primary study objective is to evaluate the efficacy of voxelotor for increasing oxygen saturation in patients with hypoxic hypoxemia as a result of end-stage lung disease or acute lung injury. The secondary objective is to evaluate the efficacy of voxelotor on allowing de-escalation of supplemental oxygen support.

Respiratory failure occurs when the lung fails to perform one or both of its roles in gas exchange; oxygenation and/or ventilation. Presentations of respiratory failure can be mild requiring supplemental oxygen via nasal cannula to more severe requiring invasive mechanical ventilation as see in acute respiratory distress syndrome (ARDS).It is important to provide supportive care through noninvasive respiratory support devices but also to minimize risk associated with those supportive devices such as ventilator induced lung injury (VILI) and/or patient self-inflicted lung injury (P-SILI). Central to risk minimization is decreasing mechanical stress and strain and optimizing transpulmonary pressure or the distending pressure across the lung, minimizing overdistention and collapse. Patient positioning impacts ventilation/perfusion and transpulmonary pressure. Electrical impedance tomography (EIT) is an emerging technology that offers a noninvasive, real-time, radiation free method to assess distribution of ventilation at the bedside. The investigators plan to obtain observational data regarding distribution of ventilation during routine standard of care in the ICU, with special emphasis on postural changes and effects of neuromuscular blockade, to provide insight into ventilation/perfusion matching, lung mechanics in respiratory failure, other pulmonary pathological processes.

During moderate to severe ARDS, sessions of prone positioning lead to lung and chest wall mechanics changes that modify regional ventilation, with a final redistribution of tidal volume and PEEP towards dependent lung regions: this limits ventilator-induced lung injury, increases oxygenation and convincingly improves clinical outcome. Physiological data indicate that the increase in chest wall elastance is crucial in determining the benefit by prone positioning on oxygenation. In some patients, however, prone positioning may not be feasible or safe due to particular comorbidities and/or technical issues. In the present pilot-feasibility study enrolling 15 subjects with moderate to severe ARDS in whom prone positioning is contraindicated or unfeasible, we aim at assessing whether and to what extent an artificial increase in chest wall elastance while the patient is in the supine position may yield a significant benefit to oxygenation. The increase in chest wall elastance will be achieved placing 100g/kg weight on the anterior chest wall of the patient while he/she is in the supine position: this approach previoulsy appeared safe and effective in case reports and small case series. Patient's position will be standardized (30 degrees head-up, semi seated position). This one-arm sequential study will evaluate the effects of the procedure on gas exchange, haemodynamics, lung and chest wall mechanics, alveolar recruitment (measured with the nitrogen washout-technique and multiple PV curves) and tidal volume and PEEP distribution (assessed with electrical impedance tomography).

The American European Consensus Conference (AECC) 1994 defined acute respiratory distress syndrome (ARDS) as an acute inflammatory syndrome manifesting as diffuse pulmonary edema and respiratory failure that cannot be explained by, but may co-exist with, left-sided heart failure. During the sequel Conference of the European Society of Intensive Care Medicine, in 2012 minor changes were made, and since that so-called Berlin definition of ARDS is used worldwide for the description of this severe disease. Three grades of severity were proposed to distinguish ARDS according to the level of hypoxemia with a mortality of 24% in patients with mild ARDS, rising to 48% in those with severe ones. Systemic inflammation is considered to be the main reason of ARDS. Activated neutrophils interact with the alveolar-capillary membrane causing the increasing permeability with the sequence lung edema's development. Inflammatory exudate inactivates surfactant leading to collapse and consolidation of distal airspaces with progressive loss of the lung's gas exchange surface area. Unfortunately, systemic inflammatory response syndrome (SIRS) simultaneously inhibits the mechanism of active pulmonary vasoconstriction and allows deoxygenated blood to pass through unventilated areas of the lung boosting the right-to-left shunt. Both mechanisms lead to hypoxemia, which is the main and obligatory feature of ARDS. Actually, endothelial dysfunction and transcapillary leakage seem to be one of the main steps in the development of respiratory failure during ARDS. Last decades it was found out that glycocalyx is also participating in this process too. Thus, it became clear that substances preserving endothelium and glycocalyx from SIRS-causing damage may have a beneficial effect in ARDS treatment. It seems to be crucially important so as the majority of drugs failed to demonstrate any positive effects in terms of ARDS treatment. To the moment we have some evidence, which came from experimental studies, that halogenated anesthetics can preserve glycocalyx against ischemia-reperfusion injury. The primary objective for the multicentral INVERSE Trial will be to determine the effects of inhalational (sevoflurane) versus intravenous (propofol) sedation on P/F ratio on the second day, hospital mortality and ICU (intensive care unit), and in-hospital length of stay in adults with a moderate form of ARDS.

The acute respiratory distress syndrome, formerly known as the acute lung injury (ARDS/ALI), is a critical illness with high mortality due to the lack of effective treatment. The pathogenesis of ARDS/ALI has not been fully elucidated. Nuclear factor E2-related factor 2 (Nrf2) plays a key role in regulating lung inflammation and oxidative stress which are closely related to lung injury in ARDS/ALI, but its regulatory mechanism remains unclear. The investigator's provious study shown that microRNA-27b (miR-27b) downregulated Nrf2 to aggravate lung inflammation and histological injury. Furthermore, in lipopolysaccharide (LPS)-induced cell (J774A.1) inflammation model, miR-27b was upregulated while the long non-coding RNA (lncRNA) NEAT1 was downregulated, the putative binding sites of lncRNA NEAT1 and miR-27b were successfully predicted by bioinformatics approach. Thus, the investigators propose that NEAT1 plays as a competing endogenous RNA (ceRNA) to adsorb miR-27b and liberate Nrf2, therefore, to attenuate lung inflammation and related lung injury in ARDS/ALI. This project aims to explore the role of the lncRNA NEAT1/ mir-27b /Nrf2 signal axis in the development and treatment of ARDS/ALI in patients, as well as in LPS-induced ALI animal and cell models by using bioinformatics, molecular biology, histomorphology and clinical phenotype approaches, and to clarify the new mechanism in ARDS/ALI development and to provide new therapeutic targets.

Acute respiratory distress syndrome (ARDS) is when a person's lungs become inflamed, which can be caused by infection, trauma, surgery, blood transfusion, or burn. ARDS often leads to a situation where the person cannot breathe independently and needs machines' help. Once the lungs are inflamed, the small air sacs responsible for exchanging gases (i.e., ventilation) and the blood flow in the lungs (i.e., perfusion) can be affected. In the past, most research focused on studying ventilation physiology and how to help people breathe with machines. Less was done on perfusion because it requires imaging techniques such as computed tomography with intravenous contrast and radiation. One treatment option for low oxygen levels is inhaled nitric oxide (iNO), a gas that can dilate the lung blood vessels and improve oxygenation; however, it is not always clear whether this treatment will work. Electrical Impedance Tomography (EIT) is a bedside and accessible imaging technique that is radiation-free and non-invasive and can potentially detect changes in lung perfusion. EIT can perform multiple measurements; it is portable and accessible. This prospective interventional study aims to assess changes in regional blood perfusion in the lungs of patients with ARDS in response to iNO utilizing EIT. The main questions it aims to answer are: If EIT can measure lung regional perfusion response to an iNO challenge of 20ppm for 15 minutes. If EIT is comparable to dual-energy computed tomography (DECT), the gold-standard method to detect changes in regional lung perfusion. If EIT can be an imaging marker to identify ARDS severity Participants will be divided into two cohorts: Cohort 1 (n=60): Participants will be asked to be monitored by EIT before, during, and after the administration of iNO (20 ppm) for 15 minutes (OFF-ON-OFF) Cohort 2 (N=10): Participants will be asked to be monitored by EIT and DECT before and during the administration of iNO (20 ppm) for 15 minutes (OFF-ON).

Acute respiratory distress syndrome (ARDS) is a diffuse inflammation of the lungs that occurs in a variety of diseases. According to the Berlin definition, ARDS is characterized by diffuse lung damage in patients with predisposing factors. Understanding the physiology of ARDS has led to improved ventilatory management, which must be protective to ensure adequate oxygenation and CO2 clearance. Prone position (PP) is a technique that can reduce mortality in patients with severe ARDS. PP results in a more homogeneous distribution of pulmonary stress and strain, helping to protect the lung against ventilator-induced lung injury (VILI). It also increases the PaO2/FiO2 (P/F) ratio, improves the pulmonary ventilation-perfusion ratio, decreases PaCO2 and promotes ventilation of the dorsal lung regions. This technique should be offered to all patients with severe ARDS for 16 consecutive hours, to improve survival and weaning success from mechanical ventilation. However, PP has adverse effects. A meta-analysis showed an increased risk of pressure sores, possibly linked to generalized acute inflammation associated with significant cytokine discharge and diffuse lesions of the vascular endothelium. PP also increased the risk of obstruction and displacement of the endotracheal tube. Final positioning in PP, (i.e., the position imposed on the patient for the duration of the PP session) varies from one ICU to another, and is rarely described in scientific articles. There are two main variants: prone , with arms alongside the body prone, swimmer's position The aim of our study is to show that the "swimmer" PP reduces the occurrence of stage 3 or higher pressure sores, compared with the "arms alongside the body" PP (standard care) at Day 28 post inclusion.