View clinical trials related to ARDS.
Filter by:This study is meant to assess the lung mechanics in SARS-CoV-2 induced acute respiratory failure. A precise characterisation of lung mechanics and heart-lung-interactions might allow a better understanding of SARS-CoV-2 induced acute respiratory failure and thus lead to better mechanical ventilation strategies. This monocentric, observational study of critically ill COVID-19 patients in the ICU, will employ impedance tomography, right-heart catheterization, oesophageal pressure measurements, indirect calorimetry as well as classic mechanical ventilation parameters to characterise the mechanical characteristics of the lung as well as the heart-lung interactions in SARS-CoV-2 induced acute respiratory failure.
An estimated 22% of the global population is at an increased risk of a severe form of COVID-19, while one in four coronavirus patients admitted to intensive care unit will develop a pulmonary embolism. A major public health question remains to be investigated: why COVID-19 is mild for some, critically severe for others and why only a percentage of COVID-19 patients develop thrombosis, despite the disease's proven hypercoagulable state? Patients' intrinsic characteristics might be responsible for the deep variety of disease forms. Our study aims to assess the validity of the hypothesis according to which underlining genetic variations might be responsible for different degrees of severity and thrombotic events risks in the novel coronavirus disease. Moreover, we suspect that prothrombotic genotypes occuring in the genes that encode angiotensin-converting enzyme (ACE-DEL/INS) and angiotensinogen (AGT M235T) are involved in the unpredictable evolution of COVID-19, both in terms of severity and thrombotic events, due to the strong interactions of SARS-CoV-2 with the renin-angiotensin-aldosterone system (RAAS). Therefore, we also aim to assess the validity of the theory according to which there is a pre-existing atypical modulation of RAAS in COVID-19 patients that develop severe forms and/or thrombosis. Our hypothesis is based on various observations. Firstly, there is a substantial similarity with a reasonably related condition such as sepsis, for which there is a validated theory stating that thrombophilic mutations affect patients' clinical response. Secondly, racial and ethnic genetic differences are responsible for significant dissimilar thrombotic risks among various nations. Thirdly, an increase in stroke incidence has been reported in young patients with COVID-19, without essential thrombosis risk factors, favoring the idea that a genetic predisposition could contribute to increase the thrombotic and thromboembolic risk. Fourthly, the plasminogen activator inhibitor (PAI)-1 4G/5G inherited mutation was found to be responsible for a thrombotic state causing post-SARS osteonecrosis.
PEEP titration is a recommended during invasive mechanical ventilation of ICU patients. However, little is known about the right way to conduct this titration. PEEP titration can be conducted by a stepwise increase in PEEP level, or following an ARM and a consecutive stepwise decrease in PEEP level. Those 2 methods will be explored in intubated ICU patients either with healthy lung or ARDS lungs. Physiological exploration will include end-expiratory lung volume measurements, driving pressure, compliance and electro-impedance tomography at each PEEP level.
A randomized clinical trial designed and intended to evaluate the efficacy of Dexamethasone and Methylprednisolone as a treatment for severe Acute Respiratory Distress Syndrome (ARDS) caused by coronavirus disease 19 (COVID-19). Our aim is to find the best option for the treatment and management of ARDS in COVID-19 patients.
To assess the prognostic performance of an early global LUS score with respect to the mortality in ICU and duration of ventilation.
The study will follow COVID-19 patients who required intensive care after 3-6 months and one year after discharge from the ICU with functional level as well as organ function to assess recovery after COVID-19. Blood and urine will be collected for biobanking.
In light of the rapidly emerging pandemic of SARS-CoV-2 infections, the global population and health care systems are facing unprecedented challenges through the combination of transmission and the potential for severe disease. Acute respiratory distress syndrome (ARDS) has been found with unusual clinical features dominated by substantial alveolar fluid load. It is unknown whether this is primarily caused by endothelial dysfunction leading to capillary leakage or direct virus induced damage. This knowledge gap is significant because the initial balance between fluid management and circulatory support appear to be decisive. On progression of the disease, bacterial superinfection facilitated by inflammation and virus related damage, has been identified as the main factor for patient outcome, but the role of the host versus the environment microbiome remains unclear. The overarching aim of the present research proposal is to improve therapeutic strategies in critically ill patients with ARDS due to SARS-CoV-2 infection by advancing the pathophysiological understanding of this novel disease. This research thus focuses on inflammation, microcirculatory dysfunction and superinfection, aiming to elucidate risk factors (RF) for the development of severe ARDS in SARS-CoV-2 infected patients and contribute to the rationale for therapeutic strategies. The hypotheses are that (I) the primary damage to the lung in SARS-CoV-2 ARDS is mediated through an exaggerated pro-inflammatory response causing primary endothelial dysfunction, and subsequently acting two-fold on the degradation of the lung parenchyma - through the primary cytokine response, and through recruitment of the inflammatory-monocyte-lymphocyte-neutrophil axis. The pronounced inflammation and primary damage to the lung disrupts the pulmonary microbiome, leading secondarily to pulmonary superinfections. (II) Pulmonary bacterial superinfections are a significant cause of morbidity and mortality in COVID-19 patients. Pathogen colonization main Risk Factor for lower respiratory tract infections. To establish colonization, pathogens have to interact with the local microbiota (a.k.a. microbiome) and certain microbiome profiles will be more resistant to pathogen invasion. Finally, (III) Handheld devices used in clinical routine are a potential reservoir and carrier of both, SARS-CoV-2, as well as bacteria causing nosocomial pneumonia.
COVID 19 is a novel and severe disease. One of the problems is that the virus disturbs the lungs and cause water accumulation in lungs alveolus (ARDS). Today, a chest X-ray is the only practical way to check the degree of lung accumulation. However, X-Ray has many limitations and disadvantages. Lung impedance technology allows simple lung fluid monitoring, and found to be effective in HF patients who suffer from a similar problem. The study's aim is to establish a correlation between lung fluid assessed by impedance technique and x-ray examinations. To find a correlation between lung fluid assessment by impedance and clinical parameters of COVID 19 patients.
The purpose of this trial is to determine whether Prone Positioning (PP) improves outcomes for non-intubated hospitalized patients with hypoxemic respiratory failure due to COVID-19, who are not candidates for mechanical ventilation in the ICU. The investigators hypothesize that PP will reduce in-hospital mortality or discharge to hospice, compared with usual care for non-intubated patients with do-not-intubate goals of care with hypoxemic respiratory failure due to probable COVID-19.
COVID-19 patients who develop severe disease often develop acute respiratory distress syndrome (ARDS) as a result of a dysregulated immune response. This in turn stimulates a pro-inflammatory cascade ("cytokine storm") as well as emergency myelopoiesis. This proinflammatory cascade is activated when viral-mediated cell damage occurs in the lungs, resulting in the release of damage-signaling alarmin molecules such as S100A8/A9 (Calprotectin), HMGB1, Resistin, and oxidized phospholipids. These damage-associated molecular patterns (DAMPs) are recognized by the pattern recognition receptor Toll-Like Receptor 4 (TLR4) found on macrophages, dendritic cells and other innate immune cells and result in additional release of pro-inflammatory molecules. Several recent studies have shown that S100A8/A9 serum levels in hospitalized COVID-19 patients positively correlate with both neutrophil count and disease severity. Taken together the DAMP-TLR4 interaction forms a central axis in the innate immune system and is a key driver of the pathological inflammation observed in COVID-19. We hypothesis that targeting the initial step in the signalling pathways of these DAMPs in innate immunity offers the best hope for controlling the exaggerated host response to SARS-CoV-2 infection. EB05 has demonstrated safety in two clinical studies (>120 patients) and was able to block LPS-induced (TLR4 agonist) IL-6 release in humans. Given, this extensive body of evidence we believe EB05 could ameliorate ARDS due to COVID-19, significantly reducing ventilation rates and mortality.