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Clinical Trial Summary

At the beginning COVID-associated lung injury was considered as typical ARDS, hence respiratory and nonrespiratory treatments were delivered according to general principles for this kind of illness. There is hypothesis that in predisposed individuals, alveolar viral damage is followed by an inflammatory reaction and by microvascular pulmonary thrombosis. The investigators suggest that thrombolytic therapy may be beneficial when compared to standard care in patients with SARS-CoV-2 and severe respiratory failure.


Clinical Trial Description

COVID 19 pandemic is a serious challenge for International medical community. There is lack of knowledge about the nature and character of the lung injury caused by this kind of infection. At the beginning COVID-associated lung injury was considered as typical ARDS, hence respiratory and nonrespiratory treatments were delivered according to general principles for this kind of illness. There is hypothesis that in predisposed individuals, alveolar viral damage is followed by an inflammatory reaction and by microvascular pulmonary thrombosis. This progressive endothelial thromboinflammatory syndrome may also involve the microvascular bed of the brain and other vital organs, leading to multiple organ failure and death. Understanding the crucial role of microthrombosis in the genesis of SARS-2-CoV led to a widespread anticoagulant use. Moreover, there is evidence about a possible benefit of thrombolysis in patients with severe COVID-19 pulmonary disease. For Instance, some investigators reported about three patients with COVID 19 lung injury treated with alteplase (tPA). Authors oversaw positive changes in P/F ratio in 3/3 patients, even if in two of these patients changes lasted for a short period. Another investigators reported about the improvements in alveolar ventilation, arterial oxygenation and diminishing in vasopressor's support in 4 patients with SARS-2CoV after thrombolysis. Encouraging results were obtained also by another team in case series of 5 patients who received alteplase. Thus, there is evidence suggesting that thrombolytic therapy may be beneficial when compared to standard care in patients with SARS-CoV-2 and severe respiratory failure. This hypothesis is based on a well-established pathophysiological concept of the occurrence of pulmonary damage as a result of microthrombosis of the lung vessels. Hence, it seems crucial to conduct a randomized clinical trial to test the effectiveness of this treatment. Objective: To establish whether plasminogen activator (tPA) treatment improves alveolar ventilation P/F (PaO2/FiO2) ratio will be calculated each 6 hours during first 3 days after the end of thrombolysis procedure in patients with an Atypical Acute Respiratory Distress Syndrome (Microvascular COVID-19 Lung Vessels Obstructive Thromboinflammatory Syndrome (MicroCLOTS). Methods: Research assistants and/or clinician screen all mechanically ventilated patients for eligibility. Patients satisfying all of the Inclusion and Exclusion Criteria are classified as 'Eligible'. With informed consent from a substitute decision maker or under the decision of Concilium of three independent physicians, Eligible patients are 'Enrolled' into the study. Eligible patients Qualify for Randomization to one of the 2 groups: with or without thrombolytic therapy. In summary, patients are consented and Enrolled prior to Randomization. To enroll or randomize Eligible patients, research coordinators obtain informed consent and access the automated web-based system through Internet based program (available 24 hours/day). Each participating center has a separate computer-generated randomization schedule, with 1:1 (control to intervention) assignment, stratified by center, and using random variable block sizes. The thrombolysis procedure: In the study group, tPA (Alteplase) 25 mg i/v over 2 hours, followed by a 25 mg tPA infusion over the subsequent 22 hours. After the end of thrombolytic therapy, unfractionated heparin is administered i/v at a starting dose of 10 units / kg per hour. The target value of PTT is 40C-50C. In the control group, an equivalent amount of Ringer's solution is administered. After 24 hours, the heparin infusion gets started, similar the described for study group. In both groups patient's transfer from the heparin infusion to the introduction of low-molecular-weight heparins is performed after normalization of the D-dimer level. Statistical analysis: Primary data analysis will be based on intention to treat (ITT) analysis. Data will be analyzed also on a modified ITT approach (mITT). Will be included in this analysis only patients with evidence of an Atypical Acute Respiratory Distress Syndrome (Microvascular COVID-19 Lung Vessels Obstructive Thromboinflammatory Syndrome (MicroCLOTS). Subgroups analysis: Some pre-defined subgroups analysis will be performed: 1. Patients with with P/F <200 mmHg>100 mmHg; 2. Patients with with P/F <100 mmHg; 3. Patient 65+ group; 4. Patients under 65 years old. Interim analyses: Interim analyses will not be performed ;


Study Design


Related Conditions & MeSH terms

  • Acute Lung Injury
  • Acute Respiratory Distress Syndrome
  • Respiratory Distress Syndrome, Adult
  • Respiratory Distress Syndrome, Newborn
  • Syndrome

NCT number NCT04453371
Study type Interventional
Source Negovsky Reanimatology Research Institute
Contact
Status Withdrawn
Phase Phase 3
Start date October 15, 2020
Completion date February 15, 2021

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