View clinical trials related to ARDS.
Filter by:A prospective physiologic study, in participants with COVID-19 related or non-COVID-19 related acute respiratory distress syndrome (ARDS) requiring mechanical ventilation less than 48 hours. The investigators assessed the effect of different tidal volume guided by different levels of driving pressure on ventilation inhomogeneity and ventilation/perfusion mismatch by electrical impedance tomography (EIT) in supine and/or prone position.
Retrospective study in COVID-19 ARDS patients hospitalised in the ICU. Investigators aim to explore the effects of prone positioning on oxygenation, dead space ventilation and mortality.
In December 2019, a new pandemic emerged, the COVID-19 disease caused by a SARS-Cov-2 virus. One of the most common symptoms of COVID-19 is mainly respiratory failure and patients requires assistance by mechanical ventilation. Ventilator-associated pneumonia (VAP) is a risk of this assistance. Since the beginning of the pandemic, Standard of care have evolved with new data. The prevalence of these VAPs seems significantly higher in the population of patients with ARDS COVID-19 (40-50%) and their ecology seems to have evolved over time, particularly in terms of bacterial resistance. Investigators want to describe and compare this evolution of bacterial and fungal ecology as well as identify potential risk factors that may be associated with these changes in ecology during different waves.
Objective: Veno-venous ECMO has been used as a rescue therapy for patients with severe ARDS associated to influenza A H1N1 and COVID19 viral pneumonia. Little is known about outcome of these patients who required extracorporeal support. Research question: To compare outcome of patients who required VV ECMO for Covid19 and H1N1 associated ARDS
Ventilator Associated Pneumonia (VAPs) are a very common side effect in intensive care units. They are the leading causes of nosocomial infections and excess mortality in intensive care units: associated with a controversial death rate of around 13%. VAPs complicate about 40-50% of COVID-19 acute respiratory distress syndrome (ARDS) and the mortality would be twice higher. Thus, in this context of the COVID-19 pandemic, this represents a considerable rate of patients. Unfortunately, the risk factors for VAPs are poorly understood and the bacterial ecology varies around the world. Also, facing a high prevalence of multi-resistant bacteria in this population, the choice of probabilistic antibiotic therapy is complex and represents a considerable impact for care. New microbiological rapid diagnostic techniques have appeared in recent years, among them the FilmArray® seems to present interesting diagnostic performances with the ability to detects resistance to antibiotics. This technique has been studied in acute community pneumonia but has not been validated in VAP and even less during the COVID-19 period. Investigators decide to conduct this study to investigate if the early identification of the pathogens and their mechanism of resistance using FilmArray® would improve the relevance of the antibiotic treatment. The aim of this project is to evaluate the contribution of a rapid diagnostic technique to the management of Ventilator Associated Pneumonia during COVID-19 acute respiratory distress syndrome before an interventional study.
This study aims to establish whether tocilizumab has any significant effect on procalcitonin levels on patients diagnosed with COVID-19 pneumonia requiring intensive care admission. The effects on other biochemical and clinical markers are also considered.
The OMELETTE study is a randomised, controlled, unicentric, open-label study to prove the noninferiority of reduced prone position (PP) sessions (more tan 16 hours) versus prolonged PP (48 hours).
This is a monocentric, prospective, observational study that will be conducted in the general ICU of San Gerardo Hospital (Monza, Italy). Study protocol will be started when NMBAs infusion will be stopped for clinical reason until regain of spontaneous breathing activity. Patients will be enrolled at the moment of NMBAs infusion interruption ("baseline" phase). Clinical data will be collected: hemodynamics, ventilation parameters and respiratory mechanics, arterial blood gas analysis, drugs used for sedation and their dosages. An EIT belt will be positioned around the patient's chest when clinical signs of spontaneous breathing activity will be detectable (unstable flow curve on the ventilator, deflection in airway pressure during an expiratory pause). In this phase ("NMBA interruption") same clinical data will be collected as at baseline. Patients will be ventilated in the same ventilation mode as before (Volume Controlled mechanical ventilation), but the inspiratory trigger on the ventilator will be turned on to reduce patient-ventilator asynchronies. When an EIT trace lasting at least 10 minutes will be recorded, an NMBA bolus (as prescribed by the treating physician) will be administered and a continuous infusion will be restarted. Clinical data will be collected again in this phase ("NMBA restart").
Since the beginning of the SARS CoV 2 pandemia, the SARS CoV 2 was frequently compared with the seasonal influenza virus. However, few studies compared patients presenting acute respiratory distress syndrome (ARDS) induced by these viruses, with results being discordant. Our study means to compare mortality and morbidity of patients hospitalized in an intensive care unit (ICU) with ARDS induced by SARS CoV-2 and seasonal influenza.
Transpulmonary pressure may be higher in ARDS patients due to decreased respiratory system compliance. The hypothesis is that tidal volumes which are generated by Intellivent- Adaptive support ventilation (ASV) are safe range by transpulmonary pressure.