When could airway plateau pressure above 30 cmH2O be acceptable in ARDS patients?

Increasing heterogeneity is associated with IL-6 expression in the lungs following mechanical ventilation

This study aimed to characterize how peak inspiratory pressure (PIP) and positive end-expiratory pressure (PEEP) influence regional lung volume heterogeneity as a result of mechanical ventilation and the influence of this heterogeneity on markers of inflammation within the lungs. Four groups of BALB/C mice (n = 7 or 8 per group) were mechanically ventilated for 2 h using low or high (12 cmH2O or 20 cmH2O) peak inspiratory pressure (PIP) with or without 2 cmH2O positive end-expiratory pressure (PEEP). Four-dimensional computed tomography (4-DCT) images were acquired using synchrotron-based radiation source at baseline and after 2 h. Regional tidal volumes were obtained by 4-D cross-correlational X-ray velocimetry, whereas end-expiratory volume was quantified by Hounsfield units. Tissue was harvested from 10 lung regions, and expression of IL-6 and monocyte chemo-attractant protein 1 (MCP-1) was quantified using qPCR. We found a significant reduction in specific end-expiratory volume (sEEV) in mice ventilated with low PIP and no PEEP and a reduction in tidal volume in groups without PEEP. End-expiratory volume heterogeneity decreased in the low PIP and no PEEP group, whereas tidal volume heterogeneity decreased in the equivalent high PIP group, potentially due to regional redistribution of lung volumes. We found associations between IL-6 expression and tidal volume heterogeneity. In this study, we have demonstrated that changes in PIP and PEEP impact atelectasis, overdistension, and heterogeneity, and that increases in tidal volume heterogeneity may be driving IL-6-mediated biotrauma. These findings highlight the importance of considering the spatial distribution of tidal volumes as a driver of lung injury during mechanical ventilation.NEW & NOTEWORTHY The combination of low inspiratory and expiratory pressure promotes atelectasis but is not associated with markers of injury in the healthy lung during short-term ventilation. High inspiratory pressures promote tidal volume heterogeneity, which is correlated with the expression of genetic markers of lung injury. These data suggest that heterogeneity in tidal volume may be a key driver of biotrauma in the healthy, mechanically ventilated lung.

Monitoring Lung Injury Severity and Ventilation Intensity during Mechanical Ventilation

Acute respiratory distress syndrome (ARDS) is a severe form of respiratory failure burden by high hospital mortality. No specific pharmacologic treatment is currently available and its ventilatory management is a key strategy to allow reparative and regenerative lung tissue processes. Unfortunately, a poor management of mechanical ventilation can induce ventilation induced lung injury (VILI) caused by physical and biological forces which are at play. Different parameters have been described over the years to assess lung injury severity and facilitate optimization of mechanical ventilation. Indices of lung injury severity include variables related to gas exchange abnormalities, ventilatory setting and respiratory mechanics, ventilation intensity, and the presence of lung hyperinflation versus derecruitment. Recently, specific indexes have been proposed to quantify the stress and the strain released over time using more comprehensive algorithms of calculation such as the mechanical power, and the interaction between driving pressure (DP) and respiratory rate (RR) in the novel DP multiplied by four plus RR [(4 × DP) + RR] index. These new parameters introduce the concept of ventilation intensity as contributing factor of VILI. Ventilation intensity should be taken into account to optimize protective mechanical ventilation strategies, with the aim to reduce intensity to the lowest level required to maintain gas exchange to reduce the potential for VILI. This is further gaining relevance in the current era of phenotyping and enrichment strategies in ARDS.