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Intracycle power and ventilation mode as potential contributors to ventilator-induced lung injury.

Authors :
Marini JJ
Crooke PS
Tawfik P
Chatburn RL
Dries DJ
Gattinoni L
Source :
Intensive care medicine experimental [Intensive Care Med Exp] 2021 Nov 01; Vol. 9 (1), pp. 55. Date of Electronic Publication: 2021 Nov 01.
Publication Year :
2021

Abstract

Background: High rates of inflation energy delivery coupled with transpulmonary tidal pressures of sufficient magnitude may augment the risk of damage to vulnerable, stress-focused units within a mechanically heterogeneous lung. Apart from flow amplitude, the clinician-selected flow waveform, a relatively neglected dimension of inflation power, may distribute inflation energy of each inflation cycle non-uniformly among alveoli with different mechanical properties over the domains of time and space. In this initial step in modeling intracycle power distribution, our primary objective was to develop a mathematical model of global intracycle inflation power that uses clinician-measurable inputs to allow comparisons of instantaneous ICP profiles among the flow modes commonly encountered in clinical practice: constant, linearly decelerating, exponentially decelerating (pressure control), and spontaneous (sinusoidal).<br />Methods: We first tested the predictions of our mathematical model of passive inflation with the actual physical performance of a mechanical ventilator-lung system that simulated ventilation to three types of patients: normal, severe ARDS, and severe airflow obstruction. After verification, model predictions were then generated for 5000 'virtual ARDS patients'. Holding constant the tidal volume and inflation time between modes, the validated model then varied the flow profile and quantitated the resulting intensity and timing of potentially damaging 'elastic' energy and intracycle power (pressure-flow product) developed in response to random combinations of machine settings and severity levels for ARDS.<br />Results: Our modeling indicates that while the varied flow patterns ultimately deliver similar total amounts of alveolar energy during each breath, they differ profoundly regarding the potentially damaging pattern with which that energy distributes over time during inflation. Pressure control imposed relatively high maximal intracycle power.<br />Conclusions: Flow amplitude and waveform may be relatively neglected and modifiable determinants of VILI risk when ventilating ARDS.<br /> (© 2021. The Author(s).)

Details

Language :
English
ISSN :
2197-425X
Volume :
9
Issue :
1
Database :
MEDLINE
Journal :
Intensive care medicine experimental
Publication Type :
Academic Journal
Accession number :
34719749
Full Text :
https://doi.org/10.1186/s40635-021-00420-9