Active clinical trials for "Respiratory Distress Syndrome"

The investigators are planning to investigate the effect of each 5% slope time change on mechanical power and SPO2 of the patients with Covid 19 ARDS diagnosis which are on mechanical ventilation PCV mode support.

The purpose of this clinical study is to determine the effectiveness and safety of Infasurf® administered through the InfasurfAero™, a novel oral airway delivery device specifically designed to give Infasurf in a less complicated way and without the need for a breathing tube or interrupting nasal respiratory support.

In the past many neonates with respiratory distress syndrome would require intubation, but over the years these rates have declined as the capabilities of non-invasive ventilation (NIV) have vastly improved. Despite these improvements, the decrease in pressure transmission due to factors such as resistance from tubing or air leaks around the nostrils and mouth, continues to be one of the major drawbacks when using nasal NIV. Current ventilators measure the set pressures at the circuit but do not capture the delivered pressure at the patient's nares. Recently, Medtronic PB980 ventilators feature NIV plus and leak sync software that can be calibrated to measure the pressures provided at the nostrils. Optimum pressures received at the nostrils to provide safe and effective therapy in neonates is currently unknown. In the prospective portion of the study, we aim to evaluate safety and efficacy of the software by comparing the average pressure difference between the circuit and delivery pressure at the nares, the incidence of apnea, bradycardia, desaturations as well as escalation and de-escalation of ventilator support in newborns who are receiving NIV admitted to NICU

BTI-203 is a randomized, double-blind, placebo-controlled, multicenter, Phase 2 proof-of-concept (POC) study to evaluate the efficacy and safety of rhu-pGSN plus standard of care (SOC) in subjects with moderate-to-severe ARDS (P/F ratio ≤200) due to pneumonia or other infections. Potential subjects hospitalized with pneumonia or other infections are to be screened within 24 hours of diagnosis of ARDS.

Acute respiratory distress syndrome (ARDS) is a life-threatening condition that causes high mortality (41% to 58%). Previous studies have reported that biomarkers can facilitate phenotypic diagnosis of ARDS, enabling precision treatment of ARDS. Although there were many studies that found some potential therapeutic targets for ARDS, no pharmacotherapies have been validated to treat ARDS. The development of biomarkers to predict the prognosis and monitor the response to treatment would be of interest for selecting patients for specific therapeutic trials. Many recent studies have shown that immune metabolic changes are involved in the pathogenesis of ARDS and may become a new therapeutic target for them. We aimed to identify a panel of immunometabolic and lipidomic biomarkers derived from blood and bronchoalveolar lavage fluid (BALF) which may help differentiate the ARDS endotypes.

Acute lung injury and ARDS (acute respiratory distress syndrome) are characterized by lung inhomogeneity, leading to a different distribution of the tidal volume (and pressure) within the lung. The quasi-static PV curve is a useful bedside tool to set mechanical ventilation, but it reflects a global behaviour of the lung. The electrical impedance tomography (EIT) is a non-invasive and radiation-free tool, monitoring dynamic changes in gas distribution. Images from EIT can be divided in several regions of interest, allowing to measure regional changes in compliance. The regional derived-EIT PV curve could provide valuable information on airway closure and AOP (airway opening pressure). Recent studies suggest that AOP measured by the ventilator seems to correspond to the AOP of the lowest injured lung. The investigators will perform one pressure-volume (PV) curve with a low-flow insufflation of 5 L/min starting from 0 cmH2O to a maximal airway pressure corresponding to the plateau pressure. During the low-flow insufflation, both ventilator and EIT-derived PV curves will be recorded. All PV curves will be analysed offline by the investigator to detect complete and regional airway closures, and measure AOPs.

To evaluate the efficacy of less invasive surfactant administration（LISA ）technique in the treatment of neonatal respiratory distress syndrome（NRDS） by comparing with the traditional Intubate-Surfactant-Extubate（INSURE） technique.

Although mechanical ventilation remains the cornerstone of ARDS treatment, several experimental and clinical studies have undoubtedly demonstrated that it can contribute to high mortality through the developing of ventilator induced lung injury even in patients with plateau pressure <30 cmH2O. Since now there are no studies exploring the application of low flow extracorporeal CO2 removal and ultraprotective ventilation to reduce mechanical power, a composite index of VILI, independently from the value of plateau pressure or the severity of hypercapnia.

This is a phase 1/2a study including 2 parts, phase 1 and phase 2a. The phase 1 part is an open-label, single-arm, dose-escalating study to evaluate the safety and explore the dose limiting toxicity and maximum tolerated dose of a human umbilical cord derived mesenchymal stem cell product (BX-U001) in severe COVID-19 pneumonia patients with acute respiratory distress syndrome (ARDS). Qualified subjects after the screening will be divided into low, medium, or high dose groups to receive a single intravenous infusion of BX-U001 at the dose of 0.5×10^6, 1.0×10^6, or 1.5×10^6 cells/kg of body weight, respectively. The Phase 2a part is a randomized, placebo-controlled, double-blind clinical trial examining the safety and biological effects of BX-U001 at the appropriate dose selected from phase 1 for severe COVID-19 pneumonia patients with the same inclusion/exclusion criteria as the phase 1 part.

Acute respiratory distress syndrome (ARDS) is often complicated by right ventricular dysfunction (RVD), Acute cor pulmonale is the most serious form of ARDS complicated with RVD.Levosimendan is indicated for short-term treatment of acute decompensated heart failure that is not responding well to conventional therapy and requires increased myocardial contractile force.In 2016, the European Society of Cardiology issued recommendations for the management of acute right heart failure, stating that levosimendan can improve right ventriculo-pulmonary artery coupling by both increasing right heart contractility and reducing pulmonary vascular resistance.However, the clinical application of levosimendan in the treatment of ARDS right heart dysfunction is insufficient.Therefore, this study intends to use transesophageal ultrasound to evaluate right ventricular function, reduce the limitation of poor right ventricular window in transthoracic echocardiography, and conduct a multi-center randomized controlled study to further explore the effects of levosimendan on right ventricular function in ARDS patients, such as tricuspid ring systolic displacement (TAPSE) and tricuspid ring systolic displacement velocity (S '). Effects of right ventricular area change fraction (RV FAC), right ventricular end-diastolic area/left ventricular end-diastolic area (RVEDA/LVEDA), pulmonary circulation resistance (PVR), hemodynamics and mortality.