Novel application of thoracic impedance to characterize ventilations during cardiopulmonary resuscitation in the pragmatic airway resuscitation trial

Background: Significant challenges exist in measuring ventilation quality during out-of-hospital cardiopulmonary arrest (OHCA) outcomes. Since ventilation is associated with outcomes in cardiac arrest, tools that objectively describe ventilation dynamics are needed. We sought to characterize thoracic impedance (TI) oscillations associated with ventilation waveforms in the Pragmatic Airway Resuscitation Trial (PART). Methods: We analyzed CPR process files collected from adult OHCA enrolled in PART. We limited the analysis to cases with simultaneous capnography ventilation recordings at the Dallas-Fort Worth site. We identified ventilation waveforms in the thoracic impedance signal by applying automated signal processing with adaptive filtering techniques to remove overlying artifacts from chest compressions. We correlated detected ventilations with the end-tidal capnography signals. We determined the amplitudes (Ai, Ae) and durations (Di, De) of both insuation and exhalation phases. We compared dierences between laryngeal tube (LT) and endotracheal intubation (ETI) airway management during mechanical or manual chest compressions using Mann-Whitney U-test. Results: We included 303 CPR process cases in the analysis; 209 manual (77 ETI, 132 LT), 94 mechanical (41 ETI, 53 LT). Ventilation Ai and Ae were higher for ETI than LT in both manual (ETI: Ai 0.71 0, Ae 0.70 0 vs LT: Ai 0.46 0, Ae 0.45 0; p < 0.01 respectively) and mechanical chest compressions (ETI: Ai 1.22 0, Ae 1.14 0 VS LT: Ai 0.74 0, Ae 0.68 0; p < 0.01 respectively). Ventilations per minute, duration of TI amplitude insufflation and exhalation did not dier among groups. Conclusion: Compared with LT, ETI thoracic impedance ventilation insuation and exhalation amplitude were higher while duration did not dier. TI may provide a novel approach to characterizing ventilation during OHCA.