Active clinical trials for "Acute Lung Injury"

We propose that as low tidal volume ventilation has proven to be beneficial in patients with established ARDS it may have a role in preventing the onset of acute lung injury in the cardiac surgical population. Institution of low tidal volume ventilation in the operating room may reduce the release of the cytokines and interleukins that have been known to contribute to the development of acute lung injury. In this study, we propose that the institution of low tidal volume ventilation in the operating room will reduce the incidence of acute lung injury. Measurement of PaO2 to FiO2 ratio twenty four and forty eight hours post operatively will help determine if there is a difference in oxygenation between the two groups. Chest X-ray findings, time to extubation and length of ICU stay will also determine if there is a role for low tidal volume ventilation in the operating room. We will also attempt to establish a causative mechanism by measuring plasma levels of cytokines known to be associated with the development of ARDS.

COVID-19 is an infectious disease caused by severe acute respiratory syndrome coronavirus 2. COVID-19 causes life threatening complications known as Cytokine Release Syndrome or Cytokine Storm and Acute Respiratory Distress Syndrome. These complications are the main causes of death in this global pandemic. Over 1000 clinical trials are on-going worldwide to diagnose, treat, and improve the aggressive clinical course of COVID-19. The investigators propose the first, and so far, only gene therapy solution that has the potential to address this urgent unmet medical need. Rationale There are striking similarities between the damaged lung environment of COVID-19 induced ARDS and the tumor microenvironment (exposed collagen from tissue destruction by invading tumor or by the virus-induced immune response, and presence of activated proliferative cells (cancer cells and tumor associated fibroblasts or activated T cells, macrophages and pulmonary fibroblasts in COVID-19); DeltaRex-G is a disease-seeking retrovector encoding a cytocidal dominant negative human cyclin G1 as genetic payload). When injected intravenously, the DeltaRex-G nanoparticles has a navigational system that targets exposed collagenous proteins (XC proteins) in injured tissues (e.g. inflamed lung, kidney, etc.), thus increasing the effective drug concentration at the sites of injury, in the vicinity of activated/proliferative T cells evoked by COVID-19. Our hypothesis is that DeltaRex-G then enters the rapidly dividing T cells and kills them by arresting the G1cell division cycle, hence, reducing cytokine release and ARDS; Intravenous DeltaRex-G has minimal systemic toxicity due to its navigational system (targeting properties) that limits the biodistribution of DeltaRex-G only to areas of injury where exposed collagenous (XC) proteins are abnormally found; and DeltaRex-G is currently available in FDA approved "Right to Try" or Expanded Access Program for Stage 4 cancers for an intermediate size population. To gain this approval, FDA requires DeltaRex-G to have demonstrated safety and efficacy in early clinical trials.

Patients with Acute Respiratory Distress Syndrome (ARDS) residing in the intensive care unit (ICU) often require support for their breathing from a mechanical ventilator to provide adequate gas exchange, and although it is life-saving in this setting, it is also known to contribute to the morbidity and mortality in the condition. Mechanical ventilation delivers a volume and pressure of gas for each breath and can vary oxygen levels. Selecting the correct oxygen, pressure and volume levels is important, as incorrect levels can harm the patient, and result in an increased time connected to the ventilator. Recently, a system has been developed (the Beacon Caresystem) which advises the healthcare practitioner by the bedside as to how to best set the ventilator. This system is based on mathematics which describes the patients disease and may therefore provide ventilator settings which better suit the individual. The purpose of this study is to compare mechanical ventilation in ARDS patients following advice from the Beacon Caresystem to that of standard care to investigate whether the use of the system results in improved ventilation in all severities and phases of ARDS and thus reducing morbidity in ARDS. The investigators plan to recruit 110 patients (50 in the UK and 30 in each of the other 2 sites). The study also aims to examine the biological and physiological factors that determine the worsening of ARDS and the processes involved in recovery from ARDS with the aim to develop new therapies to help detect the condition and improve recovery. The investigators will utilise all raw data will be collected from the Beacon Caresystem to physiologically characterise the progression and resolution phases of ARDS. Additionally blood and Urine samples will be taken from healthy volunteers (100 in total) as a control comparison group for the biological analyses carried out in the DeVENT study.

The main objective of our study is to determine whether asymptomatic influenza virus carriage is associated with an increased risk of post-operative Acute Respiratory Distress Syndrome (ARDS) after cardiac surgery. Cardiac surgery patients are particularly at risk of developing ARDS with an estimated incidence of 5-10% based on the most recent data.

The aim of this study will test the safety, tolerability, and efficacy of RLS-0071 for approximately 28 days in comparison to a placebo control in patients with acute lung injury due to COVID-19 pneumonia in early respiratory failure. Patients will be randomized and double-blinded for two parts, a single-ascending dose (SAD) part and a multiple-ascending dose (MAD) part. The name of the study drug involved in this study is: RLS-0071.

At the beginning COVID-associated lung injury was considered as typical ARDS, hence respiratory and nonrespiratory treatments were delivered according to general principles for this kind of illness. There is hypothesis that in predisposed individuals, alveolar viral damage is followed by an inflammatory reaction and by microvascular pulmonary thrombosis. The investigators suggest that thrombolytic therapy may be beneficial when compared to standard care in patients with SARS-CoV-2 and severe respiratory failure.

Remote Ischemic Preconditioning(RIPC) and remote ischemic postconditioning(RIPoC) seems to have a protective effect during ischemic period. Using cardiopulmonary bypass(CPB) during open heart surgery reduces pulmonary blood flow and may cause ischemic damage to lung tissue. The investigators anticipate that RIPC and RIPoC may reduce lung injury after CPB.

The purpose of this study is to determine whether N-acetylcysteine given intravenously 1 day pre-operatively is effective in preventing inflammation in the lungs, as measured by tests on blood, breath and lung specimens, in patients undergoing surgery to remove a portion of lung.

Chronic thromboembolic pulmonary hypertension (CTEPH) is caused by unresolved thromboemboli in the pulmonary arteries, which lead to pulmonary hypertension and, left untreated, right heart failure. This disease can be potentially cured by performing a pulmonary thromboendarterectomy (PTE) to remove the blood clots. The surgery is not without risk and the most worrisome complication is the development of a form of acute lung injury called reperfusion lung injury, which occurs in about 40 percent of patients. The landmark publication of the ARDSNET study demonstrated that a low tidal volume strategy of mechanical ventilation, decreased morbidity and mortality in patients who had acute respiratory distress syndrome (ARDS). Since then there have been some studies examining the role of a low tidal volume strategy in all patients who are mechanically ventilated. Some studies have demonstrated a decreased incidence of acute lung injury while others have failed to do the same. In patients at high risk for developing acute lung injury, such as patients undergoing PTE, there may be a benefit to using low tidal volumes to reduce the incidence of reperfusion lung injury. To assess the efficacy of a low tidal volume ventilation strategy in patients undergoing PTE, 134 patients will be randomized at the time of surgery to either low tidal volumes (6ml/kg of ideal body weight), or standard tidal volumes (10ml/kg of ideal body weight). Patients will be followed clinically to assess for the development of reperfusion lung injury. This will be defined as the development of hypoxemia (PaO2/FiO2 ratio less than 300) and chest infiltrates in the area of reperfused lung with no other identifiable etiology within the first 72 hours of surgery. Patients will also be assessed for other factors known to contribute to acute lung injury including: plateau pressures, peak inspiratory pressures, fluid balance, and number of transfusions received. Secondary endpoints of the study will be: time to successful spontaneous breathing trial, ventilator free days, ICU free days, hospital free days, and mortality.

Lung units that participate in gas exchange are known as 'recruited' lung. Patients with lung injury suffer from a proportion of units that do not participate in gas exchange (i.e. the derecruited lung), which results in impaired gas exchange and induces an inflammatory cascade. The level of PEEP is often coupled to indices of oxygenation such as PaO2, PaO2 to FIO2 ratio, or oxygen index. Currently, two strategies are widely accepted and considered equivocal, one strategy using a lower PEEP level coupled to a certain oxygen requirement, the other using a higher PEEP level. The primary purpose of this study is to demonstrate the safety and efficacy of an electrical impedance tomography (EIT) PEEP titration protocol designed to recruit collapsed lung in children with ARDS and properly maintain lung volumes by setting an optimal PEEP level. A safety system has been developed using the ARDSnet FIO2/PEEP High (upper threshold limit) and Low (lower threshold limit) algorithm. Efficacy will be defined as an improvement in lung volume as assessed by electrical impedance tomography, lung compliance and by an improvement in markers of gas exchange. Safety will be defined as the incidence of barotrauma and hemodynamic consequences that occur during the protocol. Those results will be compared to incidences of barotrauma and hemodynamic compromise within the ARDS literature. Knowledge gained from this pilot will be instrumental in developing an EIT imagine guided protocol which will allow us to conduct future RCTs utilizing EIT technology