Safety and Efficacy of USB002 for Respiratory Distress Due to COVID-19
2019 Novel Coronavirus InfectionCOVID-19 Virus Infection5 moreThis trial will study the use of USB002 given as an intravenous infusion in patients with respiratory distress due to infection with COVID-19.
Maintaining Optimal HVNI Delivery Using Automatic Titration of Oxygen in Preterm Infants
InfantPremature3 moreOxygen treatment is common in management of preterm babies requiring intensive care. Delivery of too much or too little oxygen increase the risk of damage to eyes and lungs, and contributes to death and disability. Oxygen control in preterm infants requires frequent adjustments in the amount of oxygen delivered to the baby. This is generally performed manually by a clinician attending the baby, and generally directed to maintaining a specific range of blood oxygen saturation. The manual control often results in only half of the time in the specified range, with the baby experiencing high and low blood oxygen saturations. The technology being studied is designed to assist the clinician in maintaining blood oxygen saturation within target range by measuring oxygen saturation and automatically adjusting the amount of oxygen delivered for babies receiving high velocity nasal insufflation (an advanced form of high flow oxygen therapy). The proposed study will evaluate the efficacy and safety of the automatic control of oxygen by the new technology, as compared to manual control, among babies receiving high velocity therapy in a neonatal intensive care unit.
Comparison of High Flow Nasal Cannula (HFNC), Face-mask Non-Invasive Ventilation (NIV) & Helmet...
Acute Respiratory Distress Syndrome Caused by COVID-19Objective: To determine whether NIV delivered through helmet interface reduces intubation rate among patients with COVID-19 ARDS compared to face-mask NIV and HFNC. Design, setting & participants: Two-center randomized clinical trial of 360 patients with mild to moderate ARDS and confirmed COVID-19 requiring non-invasive ventilation between August 2020 to January 2021. The patients with respiratory rate (RR) more than 30/min or oxygen saturation (SpO2) less than 90% or PaO2/FiO2 ratio less than 300 despite standard oxygen therapy by face mask (<15 L/min) who present to Royal hospital or Sultan Qaboos University Hospital (SQUH) emergency department, medical wards or intensive care unit (ICU). Intervention: Patients will be randomly assigned (block randomization) to either face-mask NIV, HFNC or Helmet NIV. The helmet is a transparent hood that covers the entire head of the patient and has a rubber collar neck seal. Main outcome and measures: The primary outcome is the rate of endotracheal intubation at 28-days. Secondary outcomes include hospital mortality at 28 and 90 days, NIV free days, invasive ventilator free days and hospital length of stay. Expected results: We assume the failure rate of Helmet NIV to be 30%, failure rate of HFNC to be 40% and failure rate of face-mask NIV to be 50%. A sample size of 360 patients (120/group) will achieve a power of 0.90 at a significance level of 0.05. To account for 10% dropout rate, the total sample required is 396 subjects(132/group).
Dexamethasone Treatment for Severe Acute Respiratory Distress Syndrome Induced by COVID-19
Respiratory Distress SyndromeAdult1 moreSingle blind randomized clinical trial designed to evaluate the efficacy of the combination of hydroxychloroquine and dexamethasone as treatment for severe Acute Respiratory Distress Syndrome (ARDS) related to coronavirus disease 19 (COVID-19). We hypothesize that dexamethasone (20 mg for 5 days followed by 10 mg for 5 days) combined with 600 mg per day dose of hydroxychloroquine for 10 days will reduce the 28-day mortality compared to hydroxychloroquine alone in patients with severe ARDS related COVID-19.
Dexamethasone for COVID-19 Related ARDS: a Multicenter, Randomized Clinical Trial
Respiratory Distress SyndromeAdult1 moreThere is compelling data indicating that there is an excessive inflammatory response in some patients with COVID-19 leading them to develop ARDS that can be severe with a very poor prognosis. Many of these patients require very long mechanical ventilation times to survive, which have led to the collapse of the health system in some regions of the world. The current evidence for the treatment of these severe forms is inconsistent and most scientific societies and governmental or international organizations recommend evaluating treatments with randomized clinical trials. Corticosteroids, being non-specific anti-inflammatory drugs, could shorten the duration of respiratory failure and improve the prognosis. Due to the lack of solid data available regarding this serious disease, our objective is to randomly evaluate the efficacy and safety of the use of dexamethasone, a parenteral corticosteroid approved in Argentina, in patients with ARDS with confirmed respiratory infection due to SARS-CoV-2 (COVID-19). After RECOVERY trial prepublication, low dose (6 mg QD for 10 days) dexamethasone was recommended as the usual care treatment for severe COVID-19. At this time only 3 patients had been included in the trial. Thus, we updated our recommendations for centers and decided to compare two different doses of this glucocorticoid for the treatment of ADRS due to COVID-19.
Poractant Alfa (Curosurf®)) -- Effect in Adult Patients Diagnosed With 2019 Novel Coronavirus (SARS-COV-19;...
Acute Respiratory Distress SyndromeThe purpose of this study was to evaluate the efficacy and safety of poractant alfa (Curosurf®), administered by endotracheal (ET) instillation in hospitalized adult patients diagnosed with SARS-COV-19 acute respiratory distress syndrome (ARDS).
ASpirin as a Treatment for ARDS (STAR): a Phase 2 Randomised Control Trial
Acute Respiratory Distress SyndromeAcute Respiratory Distress Syndrome (ARDS) causes the lungs to fail due to the collection of fluid in the lungs (pulmonary oedema). ARDS is common in severely ill patients in Intensive Care Units and is associated with a high mortality and a high morbidity in those who survive. There is a large economic burden with direct healthcare costs, but also indirectly due to the impact on the carer and patient through their inability to return to full time employment. There is little evidence for effective drug (pharmacological) treatment for ARDS. Blood cells called platelets have increasingly been recognized to play a key role in the development of ARDS. There is increasing information that aspirin, a drug which is widely used to treat heart disease, might be important in treating ARDS. We plan to test if aspirin will help in the treatment of ARDS. To do this we will divide patients suffering from ARDS into two groups, one of which will get aspirin and the other a harmless dummy (or placebo) tablet who will then be followed up to determine if lung function improves. If effective this may lead to further research to determine if aspirin is effective in patients with ARDS. This project will also provide new information about mechanisms in the development of ARDS leading, potentially, to other new treatments.
A Multi-centre Trial of an Open Lung Strategy Including Permissive Hypercapnia, Alveolar Recruitment...
Acute Respiratory Distress SyndromeSome people develop the condition called acute respiratory distress syndrome (ARDS). This is a condition where the lungs have become injured from one of a number of various causes, and do not work as they normally do to provide oxygen and remove carbon dioxide from the body. This can lead to a reduced amount of oxygen in the patient's bloodstream. Patients with ARDS are admitted to the intensive care unit (ICU) and need help with their breathing by being connected to a ventilator (breathing machine). ARDS can lead to injury in other organs of the body causing other problems but also death. Over the past few years, reducing the size of each breath delivered by the ventilator in conjunction with the use of an occasional sustained deep breath called a "recruitment manoeuvre" have been used to try to prevent further damage to the lungs in people with ARDS. This ventilator strategy (termed the PHARLAP strategy) has been shown in a small research study to have some beneficial effects without causing any obvious harm, when compared to a current best practice ventilator strategy. The main beneficial effects of the PHARLAP strategy were to increase the amount of oxygen in the blood and to reduce markers of inflammation (the body reacting to a disease process) in the body. This study was too small to make a strong conclusion, so this study will be much larger and will assess whether patients who have developed ARDS are better off when we use the PHARLAP strategy. Three hundred and forty patients will be enrolled into this study in multiple ICUs across Australia and New Zealand. The study hypothesis is that the PHARLAP strategy group will have a higher number of ventilator free days at day 28 than the control group.
Acute Lung Injury Ventilator Evaluation (ALIVE)
Acute Lung InjuryAdult Respiratory Distress SyndromeThis study will compare two ventilator modes in mechanically ventilated patients with acute lung injury. Acute lung injury (ALI) is a condition in which the lungs are badly injured and are not able to absorb oxygen the way healthy lungs do. About 25% of patients who are ventilated get ALI. ALI causes 75,000 deaths in the US each year. Ventilators can be set to work in different ways, called modes. One mode, called ARDSNet, pumps a small amount of air into the patient's lungs and then most of the air is released prior to the next breath. Another mode, called Airway pressure release ventilation (APRV), keeps air in the lungs longer between breaths. Both of these modes are currently used at this hospital. The investigators think APRV may help patients with ALI, but we do not know for sure.
A Study in Preterm Neonates With RDS to Compare CUROSURF® Administration Through LISA and Conventional...
Respiratory Distress SyndromeNewbornThis study will compare the administration of porcine surfactant (poractant alfa, Curosurf®) through a less invasive method (LISA) using a thin catheter, CHF 6440 (LISACATH®), during non-invasive ventilation (CPAP, NIPPV, BiPAP) with an approved conventional surfactant administration during invasive ventilation followed by rapid extubation in terms of short term and mid-term safety and efficacy in spontaneously breathing preterm neonates with clinical signs of respiratory distress syndrome (RDS).