Active clinical trials for "Respiratory Distress Syndrome"

Neutrophil elastase (NE) released by neutrophils play an important role in inflammatory cascade and lung tissue injury of ARDS.Inhibition of NE is expected to prevent the pathophysiological process of ARDS and alleviate lung injury. Siverestat sodium is a specific inhibitor of NE, which has been proved by basic and observational clinical studies to be effective in alleviating lung injury of ARDS, but there is a lack of prospective multi-center randomized controlled clinical trials.Therefore, this study was intended to evaluate the efficacy of sivelestat sodium in the treatment of ARDS patients with SIRS in a multicenter randomized controlled clinical trial

Anticoagulation is an essential component of all extracorporeal therapies. Currently locoregional citrate anticoagulation is the recommended technique for continuous renal replacement therapy (CRRT). However, low clearance of citrate restricts its use to blood flow up to 150 mL/min, preventing its use in ECMO. Renal replacement therapy (RRT) is commonly provided to ECMO patients with AKI. In presence of systemic heparinization for ECMO, additional anticoagulation for the CRRT circuit (i.e. RCA) is usually not employed. Nevertheless, thrombosis occurs more frequently in the CRRT circuit than the oxygenator because of the slower blood flow. The aim of this prospective, cross-over study is to assess, in patients undergoing CRRT during veno-venous ECMO (vv-ECMO), the efficacy and safety of adding regional citrate anticoagulation (RCA) for CRRT circuit anticoagulation.

The aim of this study is to investigate the use neurally adjusted ventilatory assist (NAVA) as lung protective strategy in patients with acute respiratory distress syndrome (ARDS).

Diagnosis and treatment of the hypoxic respiratory failure induced by severe atelectasis with the background of acute lung injury is challenging for the intensive care physicians. Mechanical ventilation commenced with grave hypoxemia is one of the most common organ support therapies applied in the critically ill. However, respiratory therapy can improve gas exchange until the elimination of the damaging pathomechanism and the regeneration of the lung tissue, mechanical ventilation is a double edge sword. Mechanical ventilation induced volu- and barotrauma with the cyclic shearing forces can evoke further lung injury on its own. Computer tomography (CT) of the chest is still the gold standard in the diagnostic protocols of the hypoxemic respiratory failure. However, CT can reveal scans not just about the whole bilateral lung parenchyma but also about the mediastinal organs, it requires the transportation of the critically ill and exposes the patient to extra radiation. At the same time the reproducibility of the CT is poor and it offers just a snapshot about the ongoing progression of the disease. On the contrary electric impedance tomography (EIT) provides a real time, dynamic and easily reproducible information about one lung segment at the bed side. At the same time these picture imaging techniques are supplemented by the pressure parameters and lung mechanical properties assigned and displayed by the ventilator. The latter can be ameliorated by the measurement of the intrapleural pressure. Through with this extra information transpulmonary pressure can be estimated what directly effects the alveoli. Unfortunately, parameters measured by the respirator provide only a global status about the state of the lungs. On the contrary acute lung injury is characterized by focal injuries of the lung parenchyma where undamaged alveoli take part in the gas exchange next to the impaired ones. EIT can aim the identification of these lesions by the assessment of the focal mechanical properties when parameters measured by the ventilator are also involved. The latter one can not just take a role in the diagnosis but with the support of it the effectivity of the alveolar recruitment can be estimated and optimal ventilator parameters can be determined preventing further damage caused by the mechanical stress.

Airway pressure release ventilation (APRV) is a time-cycled, pressure controlled, intermittent mandatory ventilation mode with extreme inverse I:E ratios. Currently it is considered as a non-conventional ventilatory mode. The investigators aim to compare APRV with conventional mechanical ventilation (MV) in patients with acute respiratory distress syndrome (ARDS).

Acute Respiratory Distress Syndrome (ARDS) is often complicated by Right Ventricular Dysfunction (RVD), and the incidence can be as high as 64%. The mechanism includes pulmonary vascular dysfunction and right heart systolic dysfunction. Pulmonary vascular dysfunction includes acute vascular inflammation, pulmonary vascular edema, thrombosis and pulmonary vascular remodeling. Alveolar collapse and over distension can also lead to increased pulmonary vascular resistance, Preventing the development of acute cor pulmonale in patients with acute respiratory distress. ARDS patients with RVD have a worse prognosis and a significantly increased risk of death, which is an independent risk factor for death in ARDS patients. Therefore, implementing a right heart-protective mechanical ventilation strategy may reduce the incidence of RVD. APRV is an inverse mechanical ventilation mode with transient pressure release under continuous positive airway pressure, which can effectively improve oxygenation and reduce ventilator-associated lung injury. However, its effect on right ventricular function is still controversial. Low tidal volume (LTV) is a mechanical ventilation strategy widely used in ARDS patients. Meta-analysis results showed that compared with LTV, APRV improved oxygenation more significantly, reduced the time of mechanical ventilation, and even had a tendency to improve the mortality of ARDS patients However, randomized controlled studies have shown that compared with LTV, APRV improves oxygenation more significantly and also increases the mean airway pressure. Therefore, some scholars speculate that APRV may increase the intrathoracic pressure, pulmonary circulatory resistance, and the risk of right heart dysfunction but this speculation is not supported by clinical research evidence. In addition, APRV may improve right ventricular function by correcting hypoxia and hypercapnia, promoting lung recruitment and reducing pulmonary circulation resistance. Therefore, it is very important to clarify this effect for whether APRV can be safely used and popularized in clinic.we aim to conduct a single-center randomized controlled study to further compare the effects of APRV and LTV on right ventricular function in patients with ARDS, pulmonary circulatory resistance (PVR) right ventricular-pulmonary artery coupling (RV-PA coupling), and pulmonary vascular resistance (PVR).

This will be a prospective, multi-center, two-arms,parallel, randomized, controlled trial with a superiority design,conducted in China. The investigators conduct this multi-centre, randomized, controlled trial to test the hypothesis that NHFOV is more effective than nCPAP in the treatment of respiratory distress syndrome (RDS) in infants with a gestational age of less than 28 weeks when used as a primary noninvasive ventilation (NIV) mode.

Acute respiratory distress syndrome (ARDS) is a severe form of acute lung injury and a major cause of Intensive Care Unit (ICU) admission worldwide. Despite a large number of randomized clinical trials, a specific and effective pharmacological approach for patients with ARDS is still lacking. Fibroproliferation is a crucial part of the host defence response, and severe fibrotic lung disease affects ARDS patients even years after acute phase resolution. Pirfenidone is an oral anti-fibrotic drug, approved and largely used for treatment of idiopathic pulmonary fibrosis (IPF). The effect of Pirfenidone in ARDS has been evaluated only in animal models. This is a randomized controlled study to evaluate for the first time the efficacy of Pirfenidone in ARDS.

This is a phase 3 study designed to evaluate whether the administration of ganciclovir increases ventilator-free days in immunocompetent patients with sepsis associated acute respiratory failure. Our hypothesis is that IV ganciclovir administered early in critical illness will effectively suppress CMV reactivation in CMV seropositive adults with sepsis-associated acute respiratory failure thereby leading to improved clinical outcomes

The purpose of our prospective monocentric, randomized, controlled trial is to evaluate the effects of intravenous lidocaine on gas exchange and inflammation in acute respiratory distress syndrome (ARDS) due or not to Covid-19 pneumonia. Half of the patients will receive intravenous lidocaine and the other half will receive intravenous NaCl 0,9 % as placebo.