View clinical trials related to Respiratory Distress Syndrome.
Filter by:In this study, 120 patients with Acute Respiratory Distress Syndrome (ARDS) will be included on a two years-period in an intensive care unit (Assistance Publique des Hôpitaux de Marseille, France). Those patients will benefit from a blood test at inclusion in order to measure several coagulation biomarkers, including EV-TF. Subsequently, these patients will be treated according to the usual practices of the department, following recommendations. Patients who received an injected CT scan between Day 5 and Day 28 will be divided into two groups based on the presence or absence of a pulmonary embolism on imaging. The measured values of EV-TF levels and other studied biomarkers will be compared between these two groups in order to detect a possible association between them and the diagnosis of pulmonary embolism. It should be noted that patients receiving an injected CT-scan between Day 5 and Day 7 will be included in the main analysis while those receiving it between Day 8 and Day 28 will be included in the secondary analysis. Others will be excluded from any analysis. At the same time, several collections of clinical data will be carried out: on Day 1, Day 7, Day 28, and on the day of the CT scan if it is performed at another time.
This study focuses on patients who are at risk of developing a serious, life-threatening respiratory disease called Acute Respiratory Distress Syndrome (ARDS), which severely disrupts the function of their lungs. Preclinical studies have shown that the use of a volatile anesthetic agent such as Sevoflurane could be beneficial in the treatment and prevention of this respiratory condition. By improving gas exchange and attenuating pulmonary inflammation in particular, this agent would make it possible to prevent deterioration or to restore pulmonary function more rapidly. Half of the patients will receive inhaled sedation with sevoflurane and the other half will receive intravenous sedation already routinely used in participating ICUs (typically propofol, dexmedetomidine or a benzodiazepine, i.e. drugs approved for sedation). The aim of this study is to assess whether the use of Sevoflurane could be beneficial in the prevention of ARDS.
Acute respiratory distress syndrome (ARDS) is a condition associated with hypoxemia due to noncardiogenic causes and results in high mortality. However, the epidemiology and treatment strategy for ARDS may have changed significantly due to the accumulation of a large body of knowledge, following the two-year pandemic of the novel coronavirus (SARS-CoV-2) of which the primary manifestation is ARDS. To improve the quality of ICU care that patients receive after admission to the ICU, a variety of academic societies, including the Japanese Society of Intensive Care Medicine and the Society of Critical Care Medicine, are currently developing evidence-based guidelines and consensus guidelines and statements regarding ABCDEF bundles, nutritional therapy, ICU diary. The ABCDEF bundle, nutritional therapy, and ICU diary have been developed and are being promoted for implementation in hospitals around the world. The implementation of evidence-based ICU care is strongly recommended, especially for patients with acute respiratory distress syndrome who frequently require ventilators to maintain their lives, because their patient outcomes are worse than those who were admitted to ICU with other causes. However, there is still little evidence on how the quality of ICU care (compliance rate) correlates with patient prognosis and outcomes, and there are currently no clear goals or indicators for the ICU care we should develop. This study aims to investigate the epidemiology and treatments given to the patients and evaluate the implementation of evidence-based ICU care and its association with the outcomes of patients with acute respiratory distress syndrome admitted to the ICU. The contents of mechanical ventilation settings, respiratory conditions, and the evidence-based ICU care, such as analgesia, sedation, rehabilitation, and nutrition, given to the patients will be collected in a daily basis. Aim 1: Epidemiology Aim 2: Treatments Aim 3: Evidence-based ICU care Aim 4: ARDS related Post Intensive Care Syndrome
The goal of this clinical trial is to compare dexamethasone in late preterm deliveries. The main questions it aims to answer are: Does antenatal dexamethasone reduce the need for respiratory support in late preterm infants? Does antenatal dexamethasone reduce neonatal morbidities and mortality? Does antenatal dexamethasone reduce admission to Neonatal Intensive Care Unit and length of hospital stay? Participants will be allocated into 2 groups: intervention with dexamethasone IM and control (standard care). Investigators will compare these two groups to see if antenatal dexamethasone reduces the need for respiratory support in late preterm infants, neonatal morbidities and mortality, admission to NICU and length of hospital stay.
Ventilator-induced diaphragmatic dysfunction and intensive care unit (ICU)-acquired weakness are two consequences of prolonged mechanical ventilation and critical illness in patients with acute respiratory distress syndrome (ARDS). Both complicate the process of withdrawing mechanical ventilation, increase hospital mortality and cause chronic disability in survivors. During transition from controlled to spontaneous breathing, these complications of critical illness favor an abnormal respiratory pattern and recruit accessory respiratory muscles which may promote additional lung and muscle injury. The type of ventilatory support and positioning may affect the muscle dysfunction and patient-self-inflicted lung injury at spontaneous breathing onset. In that regard, ARDS patients with ventilator-induced diaphragmatic dysfunction and ICU-acquired weakness who are transitioning from controlled to partial ventilatory support probably present an abnormal respiratory pattern which exacerbates lung and muscle injury. Physiological-oriented ventilatory approaches based on prone positioning or semi recumbent positioning with abdominal binding at spontaneous breathing onset, could decrease lung and muscle injury by favoring a better neuromuscular efficiency, and preventing intense inspiratory efforts and high transpulmonary driving pressures, as well as high-magnitude pendelluft. In the current project, in addition to perform a multimodal description of the severity of ventilator-induced diaphragmatic dysfunction and ICU-acquired weakness in prolonged mechanically ventilated ARDS patients, prone positioning and supine plus thoracoabdominal binding at spontaneous breathing onset will be evaluated.
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.
Acute Respiratory Distress Syndrome (ARDS) is a syndrome characterized by respiratory distress and refractory hypoxemia caused by pulmonary and extra-pulmonary factors. Despite improvements in diagnosis and treatment in recent years, the mortality rate of severe ARDS is still around 40%. The distribution of lung lesions in ARDS patients is significantly gravity-dependent. Even with lung-protective ventilation strategies, tidal volume is concentrated in the ventral lung region, leading to ventilator-associated lung injury. Prone position ventilation can increase ventilation to the dorsal lung tissue and improve the ventilation-perfusion ratio, thus improving oxygenation. During prone position ventilation in ARDS patients, lung-protective ventilation strategies should be maintained, but with different respiratory mechanics from the supine position, requiring adjustment of ventilator parameters. Electrical Impedance Tomography (EIT) technology can be used for bedside monitoring of mechanically ventilated patients, providing real-time feedback on the patient's ventilation status and having great potential for clinical applications. Investigators believes that EIT monitoring during prone position ventilation in ARDS patients can individualize lung-protective ventilation strategies, minimize alveolar overdistension and collapse, improve the weaning success rate of invasive ventilation, and ultimately improve patient prognosis.
The high incidence of barotrauma in patients with COVID-19-related acute respiratory distress syndrome (ARDS) (16.1%, with a mortality rate >60%) provides rationale for considering COVID-19 ARDS a paradigm for lung frailty. The investigators recently discovered that the Macklin effect is an impressive radiological predictor of barotrauma in COVID-19 ARDS. Since lung frailty is a major issue also in non-COVID-19 ARDS (6% barotrauma, with a mortality rate of 46% ) the investigators want to confirm the importance of Macklin effect in non-COVID-19 ARDS. Using artificial intelligence-based approaches the investigators also want to identify imaging biomarkers to non-invasively assess lung frailty in a mixed cohort of COVID-19/non-COVID-19 ARDS patients. Furthermore, the investigators want to prospectively validate these biomarkers in a cohort of ARDS patients. This will provide a therapeutic algorithm for ARDS patients at high-risk for barotrauma, identifying those most likely to benefit from hyper protective strategies.
The goal of this clinical trial is to determine whether one of the two oxygenation or ventilation strategies (NIV and/or HFNO) is superior to standard oxygen to reduce 28-day mortality rate in hypoxemic acute respiratory failure (ARF) patients.
Acute respiratory distress syndrome (ARDS) is when a person's lungs become inflamed, which can be caused by infection, trauma, surgery, blood transfusion, or burn. ARDS often leads to a situation where the person cannot breathe independently and needs machines' help. Once the lungs are inflamed, the small air sacs responsible for exchanging gases (i.e., ventilation) and the blood flow in the lungs (i.e., perfusion) can be affected. In the past, most research focused on studying ventilation physiology and how to help people breathe with machines. Less was done on perfusion because it requires imaging techniques such as computed tomography with intravenous contrast and radiation. One treatment option for low oxygen levels is inhaled nitric oxide (iNO), a gas that can dilate the lung blood vessels and improve oxygenation; however, it is not always clear whether this treatment will work. Electrical Impedance Tomography (EIT) is a bedside and accessible imaging technique that is radiation-free and non-invasive and can potentially detect changes in lung perfusion. EIT can perform multiple measurements; it is portable and accessible. This prospective interventional study aims to assess changes in regional blood perfusion in the lungs of patients with ARDS in response to iNO utilizing EIT. The main questions it aims to answer are: 1. If EIT can measure lung regional perfusion response to an iNO challenge of 20ppm for 15 minutes. 2. If EIT is comparable to dual-energy computed tomography (DECT), the gold-standard method to detect changes in regional lung perfusion. 3. If EIT can be an imaging marker to identify ARDS severity Participants will be divided into two cohorts: 1. Cohort 1 (n=60): Participants will be asked to be monitored by EIT before, during, and after the administration of iNO (20 ppm) for 15 minutes (OFF-ON-OFF) 2. Cohort 2 (N=10): Participants will be asked to be monitored by EIT and DECT before and during the administration of iNO (20 ppm) for 15 minutes (OFF-ON).