A novel capnogram analysis to guide ventilation during cardiopulmonary resuscitation: clinical and experimental observations

• Published in: Critical care (London, England) Vol. 26; no. 1; pp. 1 - 13
• Main Authors: Lesimple, Arnaud, Fritz, Caroline, Hutin, Alice, Charbonney, Emmanuel, Savary, Dominique, Delisle, Stéphane, Ouellet, Paul, Bronchti, Gilles, Lidouren, Fanny, Piraino, Thomas, Beloncle, François, Prouvez, Nathan, Broc, Alexandre, Mercat, Alain, Brochard, Laurent, Tissier, Renaud, Richard, Jean-Christophe
• Format: Journal Article
• Language: English
• Published: London BioMed Central 23.09.2022; BioMed Central Ltd; Springer Nature B.V; BMC
• Subjects: Algorithms; Analysis; Animal research; Cadaver; Cadavers; Capnography; Carbon Dioxide; Cardiac arrest; Cardiopulmonary Resuscitation; Classification; CO2 pattern; CPR; CPR (First aid); Critical care; Critical Care Medicine; Emergency Medicine; Ethics; Hemodynamics; Humans; Intensive; Intrathoracic airway closure; Intubation; Laboratory animals; Life Sciences; Lung; Medicine; Medicine & Public Health; Methods; Out-of-Hospital Cardiac Arrest; Simulation; Swine; Thoracic distension; Ventilators; France; pattern; Thoracic distension; CO; Intrathoracic airway closure; Cardiopulmonary resuscitation; Cardiac arrest; CO2 pattern
• ISSN: 1364-8535; 1466-609X; 1364-8535; 1366-609X; 1466-609X
• DOI: 10.1186/s13054-022-04156-0

Background Cardiopulmonary resuscitation (CPR) decreases lung volume below the functional residual capacity and can generate intrathoracic airway closure. Conversely, large insufflations can induce thoracic distension and jeopardize circulation. The capnogram (CO 2 signal) obtained during continuous chest compressions can reflect intrathoracic airway closure, and we hypothesized here that it can also indicate thoracic distension. Objectives To test whether a specific capnogram may identify thoracic distension during CPR and to assess the impact of thoracic distension on gas exchange and hemodynamics. Methods (1) In out-of-hospital cardiac arrest patients, we identified on capnograms three patterns: intrathoracic airway closure, thoracic distension or regular pattern. An algorithm was designed to identify them automatically. (2) To link CO 2 patterns with ventilation, we conducted three experiments: (i) reproducing the CO 2 patterns in human cadavers, (ii) assessing the influence of tidal volume and respiratory mechanics on thoracic distension using a mechanical lung model and (iii) exploring the impact of thoracic distension patterns on different circulation parameters during CPR on a pig model. Measurements and main results (1) Clinical data: 202 capnograms were collected. Intrathoracic airway closure was present in 35%, thoracic distension in 22% and regular pattern in 43%. (2) Experiments: (i) Higher insufflated volumes reproduced thoracic distension CO 2 patterns in 5 cadavers. (ii) In the mechanical lung model, thoracic distension patterns were associated with higher volumes and longer time constants. (iii) In six pigs during CPR with various tidal volumes, a CO 2 pattern of thoracic distension, but not tidal volume per se, was associated with a significant decrease in blood pressure and cerebral perfusion. Conclusions During CPR, capnograms reflecting intrathoracic airway closure, thoracic distension or regular pattern can be identified. In the animal experiment, a thoracic distension pattern on the capnogram is associated with a negative impact of ventilation on blood pressure and cerebral perfusion during CPR, not predicted by tidal volume per se.