View clinical trials related to ARDS, Human.
Filter by:The most feared complication of COVID-19 infection is the occurrence of an acute respiratory distress syndrome (ARDS) that requires ICU admission and prolonged mechanical ventilation in more than 2% of the affected patients. Establishing the correct time to extubate mechanically ventilated patients is a crucial issue in the critical care practice. Delayed extubation has several consequences such as patient's mortality, health-care-related complications, neuropsychological adverse events. The aim of the INVICTUS study is to evaluate whether a CTUS-based MV weaning strategy could reduce the duration of mechanical ventilation of ARDS COVID-19 ICU patients by 72 hours, compared with usual medical care.
In the last 10 years, severe acute respiratory infection (SARI) was responsible of multiple outbreaks putting a strain on the public health worldwide. Indeed, SARI had a relevant role in the development of pandemic and epidemic with terrible consequences such as the 2009 H1N1 pandemic which led to more than 200.000 respiratory deaths globally. In late December 2019, in Wuhan, Hubei, China, a new respiratory syndrome emerged with clinical signs of viral pneumonia and person-to-person transmission. Tests showed the appearance of a novel coronavirus, namely the 2019 novel coronavirus (COVID-19). Two other strains, the severe acute respiratory syndrome coronavirus (SARS-CoV) and Middle East respiratory syndrome coronavirus (MERS-CoV) have caused severe respiratory illnesses, sometimes fatal. In particular, the mortality rate associated with SARS-CoV and MERS-CoV, was of 10% and 37% respectively. Even though COVID-19 appeared from the first time in China, quickly it spread worldwide and cases have been described in other countries such as Thailand, Japan, South Korea, Germany, Italy, France, Iran, USA and many other countries. An early paper reported 41 patients with laboratory-confirmed COVID-19 infection in Wuhan. The median age of the patients was 49 years and mostly men (73%). Among those, 32% were admitted to the ICU because of the severe hypoxemia. The most associated comorbidities were diabetes (20%), hypertension (15%), and cardiovascular diseases (15%). On admission, 98% of the patients had bilateral multiple lobular and sub-segmental areas of consolidation. Importantly, acute respiratory distress syndrome (ARDS) developed in 29% of the patients, while acute cardiac injury in 12%, and secondary infection in 10%. Invasive mechanical ventilation was required in 10% of those patients, and two of these patients (5%) had refractory hypoxemia and received extracorporeal membrane oxygenation (ECMO). In a later retrospective report by Wang and collaborators, clinical characteristics of 138 patients with COVID-19 infection were described. ICU admission was required in 26.1% of the patients for acute respiratory distress syndrome (61.1%), arrhythmia (44.4%), and shock (30.6%). ECMO support was needed in 11% of the patients admitted to the ICU. During the period of follow-up, overall mortality was 4.3%. The use of ECMO in COVID-19 infection is increasing due to the high transmission rate of the infection and the respiratory-related mortality. Therefore, the investigators believe that ECMO in case of severe interstitial pneumonia caused by COVID could represent a valid solution in order to avoid lung injuries related to prolonged treatment with non-invasive and invasive mechanical ventilation. In addition, ECMO could have a role for the systemic complications such as septic and cardiogenic shock as well myocarditis scenarios. Potential clinical effects and outcomes of the ECMO support in the novel coronavirus pandemic will be recorded and analyzed in our project. The researchers hypothesize that a significant percentage of patients with COVID-19 infection will require the utilize of ECMO for refactory hypoxemia, cardiogenic shock or septic shock. This study seeks to prove this hypothesis by conducting an observational retrospective/prospective study of patients in the ICU who underwent ECMO support and describe clinical features, severity of pulmonary dysfunction and risk factors of COVID-patients who need ECMO support, the incidence of ECMO use, ECMO technical characteristics, duration of ECMO, complications and outcomes of COVID-patients requiring ECMO support.
The purpose of this study is to evaluate the efficacy and safety of ruxolitinib in the treatment of patients with COVID-19 severe pneumonia.
This study uses the AirGo band to monitor changes in tidal ventilation in spontaneously breathing patients with COVID-19 associated respiratory failure. It aims to recognize patterns of ventilation associated with worsening respiratory failure in this patient population. If successful, this study will lead to the development of new robust methods for real-time, continuous monitoring of respiratory function in patients with respiratory failure. In turn, such monitoring methods may enable improvements in the medical management of respiratory failure and timing of interventions.
The purpose of this trial is to study the effect of initial temporary sevoflurane sedation on mortality and persistent organ dysfunction (POD) in survivors at day 28 after ICU admission in the population of patients suffering from COVID-19 ARDS.
The purpose of this research study is to learn about the safety and efficacy of human umbilical cord derived Mesenchymal Stem Cells (UC-MSC) for treatment of COVID-19 Patients with Severe Complications of Acute Lung Injury/Acute Respiratory Distress Syndrome (ALI/ARDS).
End-tidal CO2 measurements in children will be assessed for their accuracy with arterial CO2 measurements.
Prone positioning (PP) is an effective first-line intervention to treat moderate-severe acute respiratory distress syndrome (ARDS) patients receiving invasive mechanical ventilation, as it improves gas exchanges and lowers mortality.The use of PP in awake self-ventilating patients with (e.g. COVID-19 induced) ARDS could improve gas exchange and reduce the need for invasive mechanical ventilation, but has not been studied outside of case series.The investigators will conduct a randomized controlled study of patients with COVID-19 induced respiratory failure to determine if prone positioning reduces the need for mechanical ventilation compared to standard management.
This protocol proposes to use IC14, a recombinant chimeric monoclonal antibody (mAb) recognizing human CD14, to block CD14-mediated cellular activation in patients early in the development of ARDS. The binding of IC14 to human CD14 prevents CD14 from participating in the recognition of PAMPs and DAMPs due to SARS-CoV-2 infection. The putative mechanism of action of IC14 in ARDS is blockade of PAMP and DAMP interactions with CD14, thus attenuating the inflammatory cascade that leads to increased endothelial and epithelial permeability and injury resulting in alveolar injury and fluid accumulation characteristic of ARDS. IC14 is a chimeric monoclonal antibody that binds to CD14 with high affinity and inhibits signaling via membrane and soluble CD14. Blocking CD14 with IC14 treatment in normal volunteers strongly inhibits systemic inflammation in response to bacterial endotoxin (LPS). University of Washington conducted a small NIH-funded pilot trial of IC14 treatment in 13 patients with ARDS, which suggested that IC14 treatment reduced alveolar inflammation and decreased BAL cytokines. IC14 was also the subject of IND 105803 for a phase 2 study of ARDS from all causes which we propose to revise for the COVID-19 indication. A dosing regimen for IC14 with favorable pharmacokinetics supporting once daily intravenous dosing has been defined, making this an acceptable treatment for hospitalized patients. Two pharmacodynamic biomarkers can be used that are related to CD14, measurements of sCD14 (serum at baseline; urine at baseline and follow up) as well as a CD14 fragment (sCD14-ST; presepsin). A CD14 target engagement assay is available. Therefore, because of the central role of CD14 in the amplification of lung inflammatory responses leading to severe lung injury and the safety record of IC14 in humans, we propose to have an open-label protocol to test the safety and potential efficacy of IC14 treatment in preventing the progression of severe respiratory disease in patients hospitalized with COVID-19.
Experimental intervention: Insertion of Extracorporal Membrane Oxygenation (ECMO) within 24 hours of referral to an Intensive Care Unit. Control intervention: Insertion of Extracorporal Membrane Oxygenation (ECMO) as rescue therapy following failure of conventional therapy for ARDS. This conventional therapy will be standardized to reduce bias. Duration of intervention per patient: varies, depending on severity of pulmonary compromise Follow-up per patient: Until hospital discharge Accompanying measures: Serum Samples and bronchoscopy samples of patients included into the trial for secondary analysis of inflammatory parameters and potential biomarkers