Divergent changes in regional pulmonary filling characteristics during endotoxin-induced acute lung injury in pigs

Abstract

Introduction: Divergent regional filling characteristics of the lung may explain ventilator-induced lung injury. In this descriptive study, the potential of electrical impedance tomography (EIT) to determine progressive changes in regional filling characteristics during acute lung injury was explored. Methods: Endotoxin was infused during 150 minutes in 11 mechanically ventilated pigs (VC, TV 10 ml/kg, PEEP 5, RR set to normocapnia at I:E 1:2). EIT (Evaluation Kit 2; Drager Medical) was used to monitor global and regional (four equal ventrodorsal regions ofinterest, ROIs 1 to 4) impedance changes at the mid-thoracic level. The tidal regional versus global impedance changes were normalized and analysed by seconddegree polynomial correlation [1]. A square coefficient (x2) 0 indicates recruitment and a value around 0 indicates homogeneous regional to global filling. Statistical evaluation was by ANOVA and Kruskal-Wallis post-hoc test, significance was set at P 0 indicates recruitment and a value around 0 indicates homogeneous regional to global filling. Statistical evaluation was by ANOVA and Kruskal-Wallis post-hoc test, significance was set at P 2 gradient and shunt, Qs/Qt, from 5.7 + 3.6 to 33 + 24 kPa and from 9.2 + 2 to 27 + 6%. Homogeneous filling in all four ROIs occurred at baseline (Figure 1) but progressively changed to hyperinfl ation in ROI 1 (x2 = -0.36) and recruitment (x2 = 0.66) in ROI 4 at 150 minutes, with ROIs 2 and 3 showing intermediate but similar changes. The x2 gradient from ROIs 1 to 4 (dotted line) increased significantly consistent with increased regional heterogeneity comprising hyperinfl ation as well as recruitment. Conclusions: EIT can identify lung areas showing hyperinfl ation, recruitment or homogeneous filling, allowing ventilator settings to be adjusted to optimize pulmonary filling characteristics. Monitoring by EIT may thus potentially be used to minimize ventilator-induced lung injury.