COVID-19 Acute Respiratory Distress Syndrome Clinical Trial
Official title:
Correlation Between Level of Partial Pressure of Carbon Dioxide and Respiratory Effort in Patients With COVID-19 Undergoing Pressure Support Ventilation With Extracorporeal Membrane Oxygenation
Excessive respiratory effort may cause self-inflicted lung injury (SILI) and inspiratory muscle injuries , stimulate desynchronization between the patient and ventilator , and worsen the perfusion of extrapulmonary organs . Appropriate respiratory drive and effort should be maintained during the treatment of patients with respiratory failure . In contrast, respiratory drive and effort are commonly increased in patients with COVID-19 pneumonia , and this phenomenon may persist in critically ill patients with COVID-19, even after receiving venovenous ECMO (vv-ECMO) support, owing to low pulmonary compliance and a high systemic inflammatory state . To reduce respiratory effort and drive, ICU physicians often administer high doses of sedative drugs, analgesics, and muscle relaxants. The prolonged use of high doses of these drugs can cause loss of the spontaneous cough reflex, which in turn impairs sputum drainage and eventually worsens pulmonary consolidation and lung infections. As the partial pressure of carbon dioxide in arterial blood (PaCO2) could affect the respiratory drive from the respiratory center (1), it has been shown that altering different levels of extracorporeal carbon dioxide removal in patients undergoing ECMO recovering from acute respiratory distress syndrome (ARDS) could alter respiratory drive. We hope to find a more appropriate target for maintaining PaCO2 to control respiratory effort in patients with COVID-19 undergoing ECMO.
A stable environment was maintained during the study to avoid stress and abrupt stimulation. Before the start of the study, sedative drugs were titrated to Richmond agitation sedation scale values of -3 to -2, an assisted breathing mode trial was conducted, and support pressure level were adjusted to achieve tidal volume < 6 mL/kg. The ECMO GF was adjusted to achieve stable baseline conditions, defined as PaCO2 < 40 mmHg, respiratory rate < 25 bpm, and peak airway pressure < 25 cm H2O. PEEP, fraction of inspired oxygen, pressure support ventilation (PSV), ECMO blood flow, and dose of vasoconstrictors, sedatives, and analgesics remained unchanged throughout the study. The study protocol was initiated when the baseline parameters s were stable. The baseline parameters, including ventilation settings, arterial and arterial blood gas analysis, hemodynamics, and indicators of respiratory effort were measured in the baseline group. Then, the ECMO GF was modified to 50% of the baseline, and etCO2 values were monitored. ECMO GF was adjusted at 5-min intervals (increasing or decreasing by 0.5 L/min each time) until etCO2 stabilized at a level 5-10 mmHg higher than the baseline. After 20 min, the parameters were measured for the second time in the high-CO2 group (Figure 1). The study was stopped if the heart rate (HR) was > 140 beats/min and/or respiratory rate was > 40 bpm and/or systolic blood pressure > 180 mmHg and/or patients experienced anxiety or diaphoresis. ;