Strain and Blood Inflammatory Markers as Prognostic Tools for ARDS AMIS (ARDS - Markers of Inflammation...
Acute Respiratory Distress SyndromeThe objective is determine the strain measured at the bedside could be a dynamic prognostic marker of during Acute respiratory Distress Syndrome (ARDS).
The Strategy of "Pulmonary Opening by Titration of Positive End-expiratory Pressure" Means of a...
Respiratory Distress SyndromeAdultPulmonary recruitment maneuvers open these lung areas and appropriate adjustment of positive expiratory pressure (PEP) helps to stabilize recruitment and reduce the stress associated with alveolar opening and closing. Its beneficial effects in the lung affected by Acute Respiratory Distress Syndrome (ARDS) remain unclear. The hypothesis is that there is a heterogeneous effect of the recruitment maneuver according to the phenotype of ARDS. It is important to be able to define responder patients from non-responders to this recruiting maneuver.
Enhanced Lung Protective Ventilation for ARDS Patients With PrismaLung
Acute Respiratory Distress SyndromeAcute Respiratory Distress Syndrome (ARDS) still remains associated with a mortality rate of 30 - 45 % despite improvement in mechanical ventilation. Driving pressure, defined as the difference between the end-inspiratory and the end-expiratory airway pressure, appears as an important factor contributing to mortality in patients with the ARDS. In patients already receiving a conventional tidal volume of 6 ml/kg predicted body weight (PBW), a driving pressure ≥ 14 cmH2O increases the risk of death in the hospital. One mean to lower the driving pressure is to decrease the tidal volume such that from 6 to 4 ml/kg predicted body weight. However, this strategy promotes hypercarbia by reducing the alveolar ventilation, providing the respiratory rate is constant. In this setting, implementing an extracorporeal CO2 removal (ECCO2R) therapy may offset the associated hypercarbia. The investigators have previously demonstrated that combining a membrane oxygenator within an hemofiltration circuit provides efficacious low flow ECCO2R on a renal replacement therapy monitor. In this study, we thought to investigate the efficacy of the PrismaLung stand-alone therapy. Using a PrismaFlex monitor and a HP-X circuit, a neonatal membrane oxygenator (PrismaLung) is used to provide decarboxylation without renal replacement therapy. The study will consist in three periods: The first period will address the efficacy of the PrismaLung device at tidal volume of 6 and 4 ml/kg PBW using an off-on-off design. The second part of the study will investigate the effect of varying the sweep gas flow and the mixture of the sweep gas on the CO2 removal rate (random order). The third part will compare three ventilatory strategies applied in a cross-over design : Minimal distension: Tidal volume 4 ml/kg PBW and positive end-expiratory pressure (PEEP) based on the ARDSNet PEEP/FiO2 table (ARMA). Maximal recruitment: 4 ml/kg PBW and PEEP adjusted to maintain a plateau pressure between 23 - 25 cmH2O. Standard: Tidal volume 6 ml/kg and PEEP based on the ARDSNet PEEP/FiO2 table (ARMA). Each strategies will be apply in a random order for a duration of 22 hours. Pulmonary inflammatory and fibrosis pathway will be assess before and after each period using bronchoalveolar lavage (BAL) samples. Systemic inflammatory cytokines will also be investigate. Main measurements will include respiratory mechanics, transpulmonary pressure, work of breathing, end-expiratory lung volume and tidal ventilation using electrical impedance tomography.
Decrease of Lesions Induced by Mechanical Ventilation During ARDS
ARDSHumanModification of mechanically ventilated lesions by an ultra-protective multimodal strategy compared to a protective strategy in patients with veno-venous ECMO for severe ARDS.
Diaphragm Dysfunction in ARDS Patients With V-V ECMO
Respiratory Distress SyndromeUse of veno-venous extracorporeal oxygenation membrane is a therapeutic option for the management of the most severe patients with acute respiratory distress syndrome (ARDS). Given the prolonged duration of this strategy, the question of its impact on the occurrence on diaphragm dysfunction has been raised. The present study endeavors to evaluate and follow up the prevalence, risk factors and prognosis of diaphragm dysfunction in patients with VV-ECMO.
Tocilizumab for Patients With Cancer and COVID-19 Disease
Hematopoietic and Lymphoid Cell NeoplasmMalignant Solid Neoplasm4 moreThis phase II expanded access trial will study how well tocilizumab works in reducing the serious symptoms including pneumonitis (severe acute respiratory distress) in patients with cancer and COVID-19. COVID-19 is caused by the SARS-CoV-2 virus. COVID-19 can be associated with an inflammatory response by the immune system which may also cause symptoms of COVID-19 to worsen. This inflammation may be called "cytokine storm," which can cause widespread problems in the body. Tocilizumab is a medicine designed to block the action of a protein called interleukin-6 (IL-6) that is involved with the immune system and is known to be a key factor for problems with excessive inflammation. Tocilizumab is effective in treating "cytokine storm" from a type of cancer immunotherapy and may be effective in reducing the inflammatory response and "cytokine storm" seen in severe COVID-19 disease. Treating the inflammation may help to reduce symptoms, improve the ability to breathe without a breathing machine (ventilator), and prevent patients from having more complications.
Plerixafor in Acute Respiratory Distress Syndrome Related to COVID-19 (Phase IIb)
COVID-19 Acute Respiratory Distress SyndromeCOVID-19This phase IIb study, LEONARDO is a multicenter, randomized, double-blind, placebo- controlled, parallel group study, to assess the therapeutic efficacy and safety of Plerixafor in patients over 18 years of age, with acute respiratory failure related to COVID-19 and Recently admitted in ICU or equivalent structure (within 48 hours) for COVID-19 related respiratory failure without invasive mechanical ventilation and requiring oxygen support ≥ 5L/min to obtain a transcutaneous O2 saturation > 94% A total of 150 participants, will be randomized in a 2:1 ratio to receive either Plerixafor (n=100) or placebo (n=50) as a continuous IV infusion for 7 days (from D1 to D8) in addition to standard of care (e.g. glucocorticoids...). Safety data will be reviewed by an independent Data and Safety Monitoring Board (DSMB) during the study.
Inhaled GM-CSF for Respiratory Virus-Associated Severe Pneumonia
Acute Respiratory Distress SyndromePneumonia1 moreThis study will investigate the safety and efficacy of the administration of inhaled GM-CSF to patients with respiratory virus-associated pneumonia.
Intratracheal Budesonide/Surfactant Prevents BPD
Respiratory Distress SyndromeBronchopulmonary DysplasiaA double-blind study includes: 1) birth Wt 500-1499 gm, 2) respiratory distress shortly after birth and requires resuscitation 3) failure to NCPAP within 4 hrs after birth, defined as: a) FIO2 ≥ 0.30, pressure > 5cmH2O b) severe retraction c) apnea d) PCO2 ≥ 60 mmHg. Exclusion criteria: 1) lethal cardiopulmonary status 2) severe congenital anomalies. Given the COVID19 pandemics, the recruitment became difficult. Under the consideration of scientific and practical consideration, we therefore determine to have a sample of 300, (150 in each group), fulfill the criteria of type I error 0.05, type II error 0.10, power 90% and with an expectation of 30 % improvement of primary outcome (from 60 % in control group to 40 % in the intervention group as original presumed).Appropriate amount of placebo will be used as it does not affect the biophysical property of curosurf (PAS abstract 2017 San Francisco). Primary outcome of study is death or BPD defined by NICHD criteria. Follow up study of neuromotor and cognitive function and pulmonary states will be done at 1-2 years of corrected age.
Pilot RCT of Therapeutic Hypothermia Plus Neuromuscular Blockade in COVID-19 Patients With ARDS...
Respiratory Distress SyndromeAdult1 moreAcute Respiratory Distress Syndrome (ARDS) is a serious condition that occurs as a complication of medical and surgical diseases, has a mortality of ~40%, and has no known treatment other than optimization of support. Data from basic research, animal models, and retrospective studies, case series, and small prospective studies suggest that therapeutic hypothermia (TH) similar to that used for cardiac arrest may be lung protective in patients with ARDS; however, shivering is a major complication of TH, often requiring paralysis with neuromuscular blocking agents (NMBA) to control. Since the recently completed NHLBI PETAL ROSE trial showed that NMBA had no effect (good or bad) in patients with moderate to severe ARDS, the investigators sought to evaluate whether TH combined with NMBA is beneficial in patients with ARDS. The investigators are scheduled to begin enrolling in a Department of Defense-funded Phase IIb multicenter RCT of TH (core temperature 34-35°C) + NMBA for 48h vs. usual temperature management in patients with ARDS with time on ventilator as the primary outcome. Since COVID-19 is now the most common cause of ARDS, we are conducting a pilot study to examine the safety and feasibility of including patients with COVID-19-associated ARDS in our upcoming trial. In this pilot, we will randomize 20 patients with COVID-19 and ARDS to either TH+NMBA for 48h or usual temperature management. The primary outcome is achieving and maintaining the target temperature. Secondary outcomes include safety, physiologic measures, mortality, hospital and ICU length of stay, and serum biomarkers collected on days 0, 1, 2, 3, 4, and 7.