Active clinical trials for "Acute Lung Injury"

During surgery high concentrations of supplementary oxygen are routinely administrated. However, there is increasing evidence of potential harm with liberal oxygen therapy. The hypothesis of the present study is that oxygen therapy adjusted to a normal arterial oxygen target is feasible and will attenuate the side effects of supplementary oxygen therapy. The study design is a before-and-after study in which 25 patients will follow the standard regime with high concentrations of oxygen therapy and 25 patients will be treated with oxygen to achieve a normal value of arterial oxygenation.

The investigators present a randomised open label phase Ib/IIa trial of nebulised unfractionated heparin to evaluate the effect of nebulised unfractionated heparin on the procoagulant response in ICU patients with SARS-CoV-2 requiring advanced respiratory support. As this is one of the first studies of nebulised heparin in COVID 19 lung disease the investigators will assess safety as a co-primary outcome.

The study is a prospective, randomized, placebo-controlled, single-blind phase 2 clinical study of the efficacy and safety of AMY-101, a potent C3 inhibitor, for the management of patients with ARDS caused by SARS-CoV-2 infection. We will assess the efficacy and safety, as well as pharmacokinetics (PK), and pharmacodynamics (PD). The study will assess the impact of AMY-101 in patients with severe COVID19; specifically, it will assess the impact of AMY-101 1) on survival without ARDS and without oxygen requirement at day 21 and 2) on the clinical status of the patients at day 21.

Acute Respiratory Distress Syndrome (ARDS) is the main cause of death from COVID-19. One of the main mechanisms for ARDS is the violent storm of cytokines and chemokines, which cause uncontrolled fatal systemic inflammation by the immune system on the body, with additional multiple organ failure. Mortality in cases of severe ARDS caused by COVID 19 varies significantly between 50 and 90%, basically depending on the age of the patient and the presence of comorbidities. The plasticity of Mesenchymal Stem Cells (MSC) regulates inflammation and immunity. MSC can promote and inhibit an immune response, depending on the dynamics of inflammation and depending on the activation force of the immune system, the types of inflammatory cytokines present, and the effects of immunosuppressants. Essentially, the state of inflammation determines the immunoregulatory fate of MSC. Thus, IV application of AMSCa has been shown to control the inflammatory response in various diseases, such as the graft-versus-host reaction and the ARDS caused by H5NI. The objective of this study is to describe the clinical changes secondary to IV administration of MSC allogenic, in patients with bilateral COVID-19 pneumonia complicated by severe ARDS, with the evaluation of the PaO2 / FiO2 ratio, heart and respiratory rates, and the fever curve. Five patients, of either sex, over 18 years of age, with bilateral pneumonia caused by COVID-19 and severe SIRA that has not improved with the standard management measures used at that time in the care center, will be included in the study. This treatment will be administered after discussing it with the relatives that it is a procedure considered as rescue and will be carried out with informed consent. 1x10(6) xKg will be applied IV. The follow-up of the patient will be for three weeks. PaO2 / FiO2 data, fever, inflammatory markers and immunity will be evaluated. The results will be compared with the historical controls attended at INCMNSZ.

Background: There are no proven therapies for COVID-19 infection. COVID-19 infects the respiratory epithelium of the lower airways, causing widespread damage via cytopathic effects, resulting in severe inflammation and Pneumonitis. High local and circulating levels of cytokines, or cytokine storm, can lead to capillary leak syndrome, progressive lung injury, respiratory failure and acute respiratory distress syndrome (ARDS). Methods: This is a pilot randomized, controlled, uni-center study testing safety and efficacy of cytokine filtration on patients with severe ARDS. Eligible patients will be randomized to 72 hours filtration or no filtration on top of the standard treatment for ARDS. Indications for randomization are patients with moderate or severe ARDS with need of ventilation support (either invasive or non-invasive), with inflammatory markers. The primary outcome will be days on mechanical ventilation (MV) support. Secondary outcomes are 30-day mortality, ICU days, need for extracorporeal membrane oxygenation (ECMO) support, duration of renal replacement therapy (RRT) and catecholamine therapies, hospital length of stay, multi-organ failure. All analysis will be done according to the intention to treat principle.

Acute Lung Injury/Acute respiratory distress syndrome (ALI/ARDS) is a serious and frequently encountered entity in modern ICUs. Sepsis remains the most common cause of ALI/ARDS and carries the worst prognosis. The disease is characterized by an intense inflammatory process. This inflammation plays a major role in the development of gas exchange abnormalities seen in the course of the disease. Statins, primarily used as lipid-lowering agents, are now known to possess anti-inflammatory, antioxidant, antithrombogenic and vascular function-restoring actions. Therefore the investigators propose to determine if Simvastatin may be useful in decreasing the incidence of this deadly syndrome in critically ill patients.

The aim of this study is to assess the effects and safety of the early application of BILEVEL-APRV protocol and conventional ventilation strategy that used low tidal volume and adequate PEEP level in ARDS patients .

Using lung ultrasound re-aeration score(LUS-RAS) combined with pressure-volume curve(PVC) adjust maintain positive end-expiratory pressure(PEEP) after recruitment maneuver, to achieve real-time adjustment, reduce ventilation-associated lung injury and the purpose of effective lung recruitment.

The alveoli tend to collapse in patients with ARDS. Endotracheal aspiration may increase alveolar collapse by decreasing the end-expiratory lung volume. The hypothesis is that closed endotracheal aspiration led to less end-expiratory volume loss when compared to open endotracheal aspiration.

The use of positive end-expiratory pressure (PEEP) has been shown to prevent the cycling end-expiratory collapse during mechanical ventilation and to maintain alveolar recruitment, keeping lung portions open, increasing the resting end-expiratory volume. On the other hand PEEP may also overdistend the already open lung, increasing stress and strain. Theoretically high frequency oscillatory ventilation (HFOV) could be considered an ideal strategy in patients with ARDS for the small tidal volumes, but the expected benefits have not been shown yet. PEEP and HFOV should be tailored on individual physiology. Assuming that the esophageal pressure is a good estimation of pleural pressure, transpulmonary pressure can be estimated by the difference between airway pressure and esophageal pressure (PL= Paw - Pes). A PL of 0 cmH2O at end-expiration should keep the airways open (even if distal zones are not certainly recruited) and a PL of 15 cmH2O should produce an overall increase of lung recruitment. The investigators want to determine whether the prevention of atelectrauma by setting PEEP and mPaw to obtain 0 cmH2O of transpulmonary pressure at end expiratory volume is less injurious than lung recruitment limiting tidal overdistension by setting PEEP and mPaw at a threshold of 15 cmH2O of transpulmonary pressure. The comparison between conventional ventilation with tidal volume of 6 ml/Kg and HFOV enables us to understand the role of different tidal volumes on preventing atelectrauma and inducing lung recruitment. The use of non-invasive bedside techniques such as lung ultrasound, electrical impedance tomography, and transthoracic echocardiography are becoming necessary in ICU and may allow us to distinguish between lung recruitment and tidal overdistension at different PEEP/mPaw settings, in order to limit pulmonary and hemodynamic complications during CMV and HFOV.