Active clinical trials for "Respiratory Distress Syndrome"

This multicenter trial tested whether inhaled nitric oxide would reduce death or the need for oxygen in preterm infants (less than 34 weeks gestational age) with severe lung disease.

This multicenter clinical trial tested whether minimal ventilation decreases death or BPD. Infants with birth weight 501g to 1000g and mechanically ventilated before 12 hours were randomly assigned to minimal ventilation (partial pressure of carbon dioxide [PCO(2)] target >52 mm Hg) or routine ventilation (PCO(2) target <48 mm Hg) and a tapered dexamethasone course or saline placebo for 10 days, using a 2 x 2 factorial design. The primary outcome was death or BPD at 36 weeks' postmenstrual age. Blood gases, ventilator settings, and FiO2 were recorded for 10 days; complications and outcomes were monitored to discharge. The infants' neurodevelopment was evaluated at 18-22 months corrected age.

This study will explore whether a daily supplement of glycine, a substance that has antiinflammatory, cytoprotective, and endothelium-protecting effects, can improve mortality, as well as clinical and biochemical parameters, in patients with severe COVID-19 who initiate mechanical ventilatory support.

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 study aims to compare epidemiology, management of invasive ventilation and outcomes in critically ill patients with COVID-19 ARDS and ARDS from another pulmonary infection. The investigators will use individual patient data from four recently published large observational COVID-9 studies, including the 'Practice of VENTilation in COVID-19 patients' (PRoVENT-COVID) study, the 'Epidemiology of COVID-19 patients in the ICU' (EPICCoV) study, the 'SATI-COVID-19 - Clinical Characteristics and Outcomes of Patients With COVID-19 on Mechanical Ventilation in Argentina: a Prospective, Multicenter Cohort Study' and the CIBERESUCICOVID - Personalized Risk and Prognosis Factors and Follow-up at One Year of the Patients Hospitalized in the Spanish Intensive Care Units Infected with COVID -19' study. The investigators will use the individual patient data from ARDS patients with another pulmonary infection from the 'LUNG -SAFE - Large Observational Study to UNderstand the Global Impact of Severe Acute Respiratory FailurE' study and the 'ERICC - Epidemiology of Respiratory Insufficiency in Critical Care' study.

Acute respiratory distress syndrome (ARDS) is a severe pulmonary insult responsible for major, life-threatening hypoxemia. The alteration of hematosis is secondary to alveolar edema, following damage to the alveolocapillary barrier in response to a systemic inflammatory process. The presence of fluid effusion within the alveolar sacs and the modification of type II pneumocyte activity due to the presence of numerous pro-inflammatory mediators will lead to a quantitative and qualitative alteration of the surfactant. At the same time, leukocyte infiltration will lead to an alteration of the support tissue and to the accumulation of cellular debris. All these elements will lead to a heterogeneous loss of aeration of the lung. In addition, the alveolar units are compressed by the entire lung parenchyma due to the effect of gravity on the edematous tissue. The treatment of ARDS is based on the antagonistic need to maintain hematosis and reduce parenchymal insult secondary to mechanical ventilation. Optimization of mechanical ventilation consists in reducing the volume of gas administered at each respiratory cycle and in limiting thoracic parietal stress by the use of curares. More recently, the interest of the ventral decubitus position has been demonstrated. During such a maneuver, the posterior pulmonary parenchymatous zones, usually subjected to gravity in the supine position, will be able to re-expand under the effect of the prone position and of the positive pressure induced by the ventilator. The increase in parietal elastance, due to the compression of the thorax between the posterior part of the trunk and the bed, also contributes to an improvement in the distribution of inhaled gases within the pulmonary parenchyma by limiting the loss of energy, transmitted directly to the wall. The ventral decubitus position allows to redistribute the ventilation in territories which were not aired before but which participate to the respiratory exchanges because they are still perfused and thus to improve the pulmonary compliance measured. Although described as an atypical form, SARS-CoV-2 infection can lead to ARDS with severe forms of viral pneumonia and thus require prone positioning. While this results in improved oxygenation and compliance, prone positioning is accompanied by a risk of complications such as pressure sores, described as the most frequent. In addition, the massive influx of patients and more generally the lack of personnel during pandemic peaks has made the application of prone position sometimes complex because it requires human resources. As a result, the benefit/risk ratio of the maneuver is difficult to determine because not all patients respond in the same way to prone positioning. It appeared essential to be able to predict the expected benefit of the prone position before performing the procubitus maneuver. The application of thoracic and abdominal pressures, as part of the respiratory management of patients, is a technique commonly used by physiotherapists. Investigators have demonstrated a similar change in measured lung parenchymal compliance during manual compression of a patient's chest and during prone positioning. In the context of the epidemic, investigators used this test systematically to determine which patients were most likely to benefit from prone positioning and for whom the available resources should be concentrated at any given time.

In patients with Acute Respiratory Distress Syndrome (ARDS) associated with COVID-19 inflammatory syndrome, the administration of Treg cells is a novel treatment complementary to other pharmacologic interventions that potentially can reduce lung inflammation, promote lung tissue repair, and significantly improve clinical outcomes. This trial is to evaluate the impact of a single IV dose of cePolyTregs given to ARDS patients with COVID-19 inflammatory syndrome.

Term and near term newborns can present acute respiratory distress syndrome (RDS). Surfactant treatment has been shown effective in reducing mechanical ventilation and oxygen treatment durations in the preterm newborn. Whether surfactant treatment is beneficial for term and near term newborns is unknown. The purpose of this study is to compare surfactant treatment vs. nasal continuous positive airways pressure in the newborn between 35 and 41 weeks of gestation with RDS within the first 24 hours of life. The study's primary endpoint is "survival with no oxygen treatment at 72 hours of life". The secondary endpoints are: death, surfactant treatment, pneumothorax, secondary infections, pulmonary hypertension, inhaled nitric oxide treatment, fluid loading treatment, vasopressive amines treatment, mechanical ventilation duration, nCPAP treatment duration, Oxygen treatment duration, Oxygen treatment at 28 days of life, hospitalization duration and treatment strategy cost.

Assessment of the effect of hyperoxia and hypertonic saline on survival in patients with septic shock Hyperoxia and hypertonic saline may have beneficial effects on organ perfusion and oxygenation and may reduce the organ failure occurences. To date, only scarce data are available. Side effects are not well described. Therefore we designed a randomized clinical trial in order to assess the early administration of hypertonic saline and oxygen in the very early beginning of septic shock.

In this study, newborn babies with respiratory distress syndrome (RDS), receiving oxygen via nasal continuous airway pressure (CPAP) modalities, and needing surfactant treatment will be randomized to standard delivery of surfactant via and endotracheal tube airway (inserted after pre-medication for pain with a short-acting narcotic), or to surfactant delivery via laryngeal mask airway (LMA). The intent is to remove the airways and return babies to non-invasive CPAP support, after surfactant is given. The primary outcome measure is the rate of failure of initial surfactant therapy. Standardized failure criteria are reached: a) early, if the baby is unable to be placed back on non-invasive CPAP (i.e., needs tracheal intubation and mechanical ventilation) or, b) late, if the baby requires ventilation, retreatment with surfactant within 8 hours or more than 2 doses of surfactant. The objective of this protocol is to reduce the need for endotracheal intubation and mechanical ventilation in preterm neonates with RDS needing rescue surfactant therapy by instilling surfactant though an LMA, while achieving comparable efficacy of surfactant treatment. The hypothesis is that surfactant treatment through an LMA will decrease the proportion of babies with RDS who require mechanical ventilation or subsequent intubation, when compared to standard surfactant treatment following endotracheal intubation with sedation.