Physiological noise versus white noise to drive a variable ventilator in a porcine model of lung injury

Purpose: Variable ventilation is superior to control mode ventilation in a number of circumstances. The nature of the breathing file used to deliver the variable rate and tidal volume has not been formally examined. Methods: We compared two different noise files in a randomized prospective trial of variable ventilation. Pigs were anesthetized, intubated, and mechanically ventilated. Oleic acid was infused to introduce lung injury. The animals were ventilated at a tidal volume of 7 mL·kg −1 , in variable mode, with either physiologically-derived noise (variability file − 1,587 breath intervals-obtained from a spontaneously breathing volunteer; n =10) or a variability file of identical length derived from computergenerated white noise ( n =10). Results: The physiologically-derived noise had a power law α-exponent of −0.27 and a Hölder exponent of −0.38, indicative of auto-correlated noise. The computer-generated noise had an α-exponent of −0.52 and a Hölder exponent of −0.49, indicative of white noise. Both files showed multifractal characteristics. There were no differences between groups, at any time period, for PaO 2 , PaCO 2 , and static or dynamic respiratory system compliance. No differences were observed between groups for wet:dry lung weight ratios or for interleukin-8 in bronchoalveolar lavage fluid. Conclusion: This study demonstrates that the nature of the variability files, chosen to drive the variable ventilator, had no effect on indices of gas exchange or respiratory mechanics in this model. A considerable overlap of the multifractal files existed. The potential to drive a variable ventilator using algorithmderived files with multifractal characteristics, thereby eliminating the requirement to use physiologically-derived signals, is discussed.