<p>Capnometry is a cost-efficient method of monitoring carbon dioxide (CO<sub>2</sub>) in healthcare settings, especially during mechanical ventilation and cardiopulmonary bypass. However, the utility of capnometers for studying CO<sub>2</sub> elimination in a longer-duration, clinical extracorporeal membrane oxygenation (ECMO) has been poorly characterized. This report presents data from 10 venovenous ECMO patients at Vanderbilt University Medical Center between April and June 2021. Exhaust CO<sub>2</sub> was intermittently measured from a membrane oxygenator’s gas outlet, and arterial blood samples were simultaneously drawn from the patient. Clinical variables including ECMO and ventilator management, patient demographics, and outcomes were recorded. Exhaust CO<sub>2</sub> and other study variables were recorded at 233 discrete time points from the 10 patients. The median duration of ECMO support was 9&#xa0;days. Sweep gas flow rate demonstrated a strong, negative correlation with exhaust CO<sub>2</sub> concentration, from both univariate and multivariate regression analyses (adjusted β = − 5.556 for sweep &lt; 4&#xa0;L/min, <i>p</i> &lt; 0.001). Blood flow, oxygenator duration of use, and arterial CO<sub>2</sub> demonstrated weaker relationships with exhaust CO<sub>2</sub> (adjusted β = 2.341, − 0.258, 0.175, respectively), which agrees with the clinical understanding about CO<sub>2</sub> management during ECMO. This descriptive study provides foundation for future research to precisely define the clinical role of ECMO exhaust capnometry in the management of the sweep gas flow and the overall therapy.</p>

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Clinical characterization of membrane oxygenator exhaust capnometry during venovenous extracorporeal membrane oxygenation

  • John W. Stokes,
  • Whitney D. Gannon,
  • Elizabeth Simonds,
  • Ioannis A. Ziogas,
  • W. Kelly Wu,
  • Yatrik J. Patel,
  • Sean A. Francois,
  • Caitlin T. Demarest,
  • Matthew Bacchetta,
  • Rei Ukita

摘要

Capnometry is a cost-efficient method of monitoring carbon dioxide (CO2) in healthcare settings, especially during mechanical ventilation and cardiopulmonary bypass. However, the utility of capnometers for studying CO2 elimination in a longer-duration, clinical extracorporeal membrane oxygenation (ECMO) has been poorly characterized. This report presents data from 10 venovenous ECMO patients at Vanderbilt University Medical Center between April and June 2021. Exhaust CO2 was intermittently measured from a membrane oxygenator’s gas outlet, and arterial blood samples were simultaneously drawn from the patient. Clinical variables including ECMO and ventilator management, patient demographics, and outcomes were recorded. Exhaust CO2 and other study variables were recorded at 233 discrete time points from the 10 patients. The median duration of ECMO support was 9 days. Sweep gas flow rate demonstrated a strong, negative correlation with exhaust CO2 concentration, from both univariate and multivariate regression analyses (adjusted β = − 5.556 for sweep < 4 L/min, p < 0.001). Blood flow, oxygenator duration of use, and arterial CO2 demonstrated weaker relationships with exhaust CO2 (adjusted β = 2.341, − 0.258, 0.175, respectively), which agrees with the clinical understanding about CO2 management during ECMO. This descriptive study provides foundation for future research to precisely define the clinical role of ECMO exhaust capnometry in the management of the sweep gas flow and the overall therapy.