Transthoracic Impedance Measured with Defibrillator Pads—New Interpretations of Signal Change Induced by Ventilations

Compressions during the insufflation phase of ventilations may cause severe pulmonary injury during cardiopulmonary resuscitation (CPR). Transthoracic impedance (TTI) could be used to evaluate how chest compressions are aligned with ventilations if the insufflation phase could be identified in the TTI waveform without chest compression artifacts. Therefore, the aim of this study was to determine whether and how the insufflation phase could be precisely identified during TTI. We synchronously measured TTI and airway pressure (Paw) in 21 consenting anaesthetised patients, TTI through the defibrillator pads and Paw by connecting the monitor-defibrillator’s pressure-line to the endotracheal tube filter. Volume control mode with seventeen different settings were used (5–10 ventilations/setting): Six volumes (150–800 mL) with 12 min(−1) frequency, four frequencies (10, 12, 22 and 30 min(−1)) with 400 mL volume, and seven inspiratory times (0.5–3.5 [Formula: see text]) with 400 mL/10 min(−1) volume/frequency. Median time differences (quartile range) between timing of expiration onset in the Paw-line (Paw(EO)) and the TTI peak and TTI maximum downslope were measured. TTI peak and Paw(EO) time difference was 579 (432–723) [Formula: see text] for 12 min(−1), independent of volume, with a negative relation to frequency, and it increased linearly with inspiratory time (slope 0.47, [Formula: see text] = 0.72). Paw(EO) and TTI maximum downslope time difference was between −69 and 84 [Formula: see text] for any ventilation setting (time aligned). It was independent ([Formula: see text] < 0.01) of volume, frequency and inspiratory time, with global median values of −47 (−153–65) [Formula: see text] , −40 (−168–68) [Formula: see text] and 20 (−93–128) [Formula: see text] , for varying volume, frequency and inspiratory time, respectively. The TTI peak is not aligned with the start of exhalation, but the TTI maximum downslope is. This knowledge could help with identifying the ideal ventilation pattern during CPR.