Effects of different flow patterns and end-inspiratory pause on oxygenation and ventilation in newborn piglets: an experimental study

Animals were premedicated with an intramuscular bolus of ketamine (1 mg Kg⁻¹), medetomidine (0.06 mg Kg⁻¹), and azaperone (0.06 mg Kg⁻¹). Midazolam (1 mg Kg⁻¹) and fentanyl (0.03 mg kg⁻¹) were then administered in order to induce anesthesia. Endotracheal intubation was performed with a 3-mm internal diameter cuffed tube to prevent changes in VT due to air-leakage as clinically recommended [11]. During the study period, anesthesia was maintained with propofol (8 mg kg⁻¹ min⁻¹), remifentanil (0.15 μg kg⁻¹ min⁻¹), and cisatracurium (0.1 mg kg⁻¹ h⁻¹). Body temperature was maintained at 35- 36°C with a heat blanket.

A 3-Fr thermodilution catheter (PV2013L07-A, Pulsion Medical Systems AG, München, Germany) was inserted by a cut down to the right femoral artery for cardiac output monitoring. A 4-Fr double-lumen catheter (AK-14412, Arrow International, Inc, USA) was inserted by a cut down into the right or left internal jugular vein for drugs and fluid administration, and for transpulmonary thermodilution.

For mechanical ventilation, a Galileo gold (Hamilton, Bonaduz, Switzerland) was used in the pediatric mode. The ventilator allows square and decelerating flow, and end-inspiratory pause can be adjusted for a constant I/E relationship in VCV. The following ventilatory modes were compared in the study (Figure 1):

Also, by adjusting a short end-inspiratory pause, another two modes were possible. The 10% end-inspiratory pause is based on our routine clinical practice, and due to a lack of evidence for the best short end-inspiratory pause duration in healthy lungs:

After induction of anesthesia, mechanical ventilation was initiated in volume-controlled ventilation (VCV) mode with a constant inspiratory flow (square wave) and the protective [12, 13] tidal volume (VT) set at 10 mL kg⁻¹, inspiratory to expiratory ratio (I/E) at 1/2, respiratory rate (RR) of 30 breaths/min, and FiO₂ of 0.5.

In order to assure a fully open lung during the study while preventing any alveolar collapse, a single recruitment maneuver (RM) was performed before starting the experimental ventilatory protocol. This consisted of the application of 40 cmH₂O of continuous positive airway pressure (CPAP) for 10 seconds as described elsewhere [14], and adjusting for a PEEP of 6 cmH₂O thereafter. Response to RM and adequacy of the PEEP was confirmed by checking for a normal alveolar-arterial oxygen gradient (279 ± 20 mmHg) in the baseline control of the first ventilatory mode [15, 16]. No further RMs were performed, and the PEEP-level was kept constant during the whole experiment. In order to prevent de-recruitment, the sequence of changes in ventilatory modes was performed without disconnecting the breathing circuit.

To prevent bias while applying the four ventilatory modes (DF, SF, DF-EIP, SF-EIP) to the same animal, a sequence of all modes, starting and ending with the same mode, was designed (e.g., DF, SF, DF-EIP, SF-EIP, DF). The 12 possible combinations were determined, and the combinations were randomly applied to 12 animals.

After an initial hemodynamic stabilization, all animals were ventilated for 30 minutes with each mode. The VT, FiO₂, PEEP, RR, and I/E relationships were kept constant during the study. To minimize error and variability, the mean value of the last 10 minutes of each mode was calculated for each variable of the ventilatory parameters. These values were considered representative of the effect of the mode (end-values) and were also taken as the baseline values for the following mode [19]. Mean values of the hemodynamic and arterial blood gas analysis (BGA) parameters were calculated from 4 measurements made during the last 10 min.

Based on data from a previous study in healthy infants after cardiac surgery [7], it was estimated that a total of 12 animals would be needed to detect at least a 25-mmHg difference in oxygenation between flows, with a 5% significance level, and 80% power. All data were entered into the statistical package, SPSS version 15.0 (SPSS, Chicago, IL, USA). The Friedman test was performed for homogeneity. To compare primary outcomes, differences between the end-values and baseline measurements in each ventilatory mode, or the differences in the end-values between the four ventilatory modes, a statistical analysis using the Wilcoxon signed-rank test was performed [20]. To identify differences in the end-values between specific ventilatory modes (secondary outcome), the Bonferroni correction criteria was used to fit a type 1 risk to the chosen significance level (α = 0,05). All values are reported as the mean ± standard deviation (SD).

Until now, the effects of end-inspiratory pause (EIP) on the V/Q relationship during mechanical ventilation of small infant were unknown. In order to ascertain if the effect of flow waveform on oxygenation and ventilation was influenced by EIP but predominantly prevented the effects of EIP at the same time, a short (10% of the Ti) was added in both flows without modifications in the VT and the I/E relationship. We show that a 10% EIP did not produce differences in oxygenation (PaO₂) and ventilation (PaCO₂, VDalv/VTalv) in this experimental model of newborn piglets. The results in oxygenation are in concordance with previous studies [36, 37] and are justified because EIP does not decrease shunt as it does not recruit alveoli. Different from previous studies (in healthy and injured lungs) [33, 34, 36‐38], our results did not show differences in ventilation. The EIP could improve ventilation because [1] it favors gas redistribution in the lungs with different alveolar time constants, improving the V/Q relationship and therefore improving VD/VT [39]. This effect may not appear in homogeneous lungs without different alveolar time constants as in our model of normal lungs; and (2) the EIP increases the MDT. We did not observe an improvement in ventilation (PaCO₂) with constant inspiratory time. When I/E relationship is constant, previous studies in healthy lungs [32, 40] showed that higher EIP (20%) is required to improve ventilation, especially with high RR.

As we observed in our results, hemodynamics remained constant throughout the experimentation with no clinical differences between flows. These results are consistent with previous studies [4, 7, 9, 24]. Therefore, the effects of different flow patterns in oxygenation and ventilation are not explained by changes in pulmonary perfusion.

Historically, the elective intraoperative ventilatory mode in very small infants has been pressure control ventilation for two basic reasons. First, the very real limitation of older anesthesia machines to guarantee a constant VT during volume control ventilation, and second, because of the traditional thinking that DF (inherent to pressure control) improves oxygenation compared with SF (common in volume control). The results obtained in our study together with the new anesthesia machines that accurately ensure very low VT [1] could make volume control the elective intraoperative mode.

Several limitations of this study need to be mentioned. Firstly, this is an experimental study which may limit the application of the findings to the clinical setting. Secondly, this study examined a small number of animals and therefore was not powered to expose small differences in some of the variables measured. Thirdly, currently there is no general indication for routinely applying ARM and supraclinical levels of PEEP during intraoperative ventilatory management in infants. By not applying these techniques, lung homogeneity is not guaranteed, and decelerating flow may favor redistribution of gas and a better V/Q relationship. Fourth, The crossover methodology used could mask differences in the end values of the modes if the effects of the previous ventilatory mode spilled over into the next ventilatory mode. Fifth, a possible limitation were the effects of an unblinded study, however biases was minimized with a standarized protocol in management, monitoring, measurements and data colection. Finally, the clinical monitors used in the study are not completely validated for use in newborn piglets; however, they were applied throughout the study, and their inherent percent error was considered to be similar for the four conditions assessed.