Active clinical trials for "Respiratory Distress Syndrome"

The purpose of this study is to compare a specific mode of artificial ventilation (help from a breathing machine) with other modes. This specific mode is called Neurally Adjusted Ventilatory Assist (NAVA) and is different from other modes as it uses direct signals from the diaphragm (breathing muscle) to help patients breathe. The investigators believe that using these signals, NAVA can determine the exact timing for patients' spontaneous breathing effort and delivers the artificial breath at the same time (in synchrony) with their own breath. Other modes (breathing methods) may cause asynchrony between the patient and the ventilator while delivering artificial breaths because of the way they operate. Asyncrony between patient and ventilator is a risk factor for increasing the length of artificial ventilation and number of related complications. The investigators would like to find out if NAVA performs better in establishing synchrony between patient and ventilator and as a result decreasing time for artificial ventilation and increasing better outcomes.

This international multicenter, randomized, open trial will evaluate the impact of Extracorporeal Membrane Oxygenation (ECMO), instituted early after the diagnosis of acute respiratory distress syndrome (ARDS) not evolving favorably after 3-6 hours under optimal ventilatory management and maximum medical treatment, on the morbidity and mortality associated with this disease.

Perfusion index may vary according to type of surfactant during the treatment of respiratory distress syndrome.

The purpose of this study is to demonstrate that mechanical ventilation guided by the diaphragm EMG signal (also know as neurally adjusted ventilatory assist [NAVA]) is superior compared to pressure support and pressure control ventilation.

Acute respiratory distress syndrome (ARDS) is a common scenario in intensive care unit. Discussions about it is exponentially growing up due its high mortality rates all over the world and low quality of life among survivors. Mechanical ventilation is recognized to play an important role in treatment of patients with ARDS. However, mechanical ventilation itself has the potential to produce or worsen alveolar injury if inadequate strategies are chosen. Several studies compared different mechanical ventilation strategies in ARDS but the results remain uncertain regarding their influence on survival in patients with ARDS. Thus, this is a multicentric randomized controlled trial, with allocation concealment and intention to treat analysis to investigate if maximum alveolar recruitment maneuver in association to Positive end-expiratory pressure (PEEP) titrated by static compliance of respiratory system (ART strategy) is able to increase 28 days survival in patients with moderate to severe ARDS compared to conventional strategy proposed by the ARDS Clinical Network (ARDSNet strategy). Patients considered to this trial are those in mechanical ventilation with diagnosis of moderate to severe ARDS less than 72hours. Patients included will be randomized to receive ART strategy or ARDSNet strategy and will be followed until hospital discharge, 28 days and 6 months.

Prone positioning is one of the few therapies known to improve mortality in ARDS. Traditionally, patients are proned for 16 hours per 24 hour period. Some retrospective data suggests improvement may persist beyond 16 hours. We aim to perform a pilot study comparing traditional prone positioning to prolonged prone positioning in patients with COVID-induced ARDS.

Mechanical ventilation and ECMO are both technologies interacting on gas exchange. Nevertheless, besides a consensus paper, no evidence-based guidelines regarding protective lung ventilation on ECMO exist to date. Mechanical Ventilation with Intellivent-ASV, an algorithm driven, closed loop system, provides an opportunity to standardize ventilation on ECMO. We propose and validate lung protective ventilation with a closed loop ventilation mode in patients with ECMO.

This was a multi-center prospective study. All consecutive severe cases of COVID-19 whose PO2/FiO2<300mmHg with invasive ventilation admitted to 5 fixed-point receive COVID-19 patients hospitals in Wuhan from 5 March to 15 March 2020 were included. Epidemiological, clinical data, lung mechanics, artery blood gas test and hemodynamics at three methods to titrate PEEP, optimizing oxygenation, optimizing compliance, ARDSnet. The study was approved by the Ethics Committee of Zhongda Hsopital, Southeast University.

This proposal will test the feasibility of implementing an assist volume control ventilation protocol in patients receiving mechanical ventilation in the medical intensive care unit. The trial will consist of a before-and-after trial design of block assignment to either adaptive pressure control (baseline) or assist volume control . This is a feasibility study looking at the management of patients in the ventilator.

Non-invasive ventilation (NIV, delivered via a mask or cannulas) permits to reduce the need for tracheal intubation in infants who needs a ventilatory support. NIV can be delivered with nasal CPAP (continuous positive airway pressure) or NIPPV (nasal intermittent positive pressure ventilation). The synchronization of the respiratory support according to the patient's demand is very difficult to obtain in infants with the conventional ventilatory modes. In all these ventilatory modes, the end-expiratory pressure (PEEP) is fixed and set by the clinician. However, since infants are prone to alveolar collapse and must compensate for a non-compliant chest wall, an active and ongoing management of PEEP is very important to prevent the lung de-recruitment. A new respiratory support system (NeuroPAP) has been developed to address these issues of synchronization and control of PEEP. This new system uses diaphragmatic tonic activity (Edi) that reflects the patient's efforts to increase lung recruitment and therefore it continuously controls the delivery of assist continuously both during inspiration (like NAVA) and during expiration, allowing a unique neural control of PEEP. A new device, the NeuroBOX, permits to deliver NIV with NeuroPAP, CPAP, or NIPPV, and also to serve as a cardio-respiratory monitor, tracking and displaying cardiac and respiratory signals, trends, and cardio-vascular events. The two main objectives of this study are: 1- To evaluate the clinical impact of NeuroPAP in infants with high tonic Edi; 2- To characterize the cardio-respiratory pattern and its relationship with cerebral perfusion of infants with noninvasive support, using the monitoring capacity of the NeuroBOX. The investigators expect that NeuroPAP will permit to improve the efficiency of NIV in infants, through the better synchronization and the personalization of the expiratory pressure level in response to the patient needs. This study will be conducted in two subgroups of patients at high risk of elevated tonic Edi and of cardio-respiratory events: a subgroup of premature infants and a subgroup of infants with bronchiolitis.