Early detection of acute lung injury uncoupled to hypoxemia in pigs using ultrasound lung comets

Objective. Oleic acid-induced lung injury is an established experimental model of acute lung injury in pigs and is considered to reproduce the early exudative phase of acute respiratory distress syndrome. Ultrasound lung comets are an echographic sign of extravascular lung water, originating from thickened interlobular septa. The objective of this study was to evaluate the timing and relationship between the number of ultrasound lung comets, the Pa0(2)/F10(2) ratio, and the static respiratory compliance in an experimental model of oleic acid-induced lung injury in pigs. Design: Laboratory experiment. Setting: Research institute. Subjects: Ten anesthetized pigs. Interventions: Acute lung injury was induced by injection of oleic acid (0.1 mL/kg, intravenously). Ultrasound lung comets, Pa0(2)/F10(2), and static respiratory compliance were measured at baseline and at 15, 30, 60, and 90 mins after the injection of oleic acid. We evaluated ultrasound lung comets by transthoracic echography (7.5-MHz vascular probe), scanning on right and left hemithoraxes at 12 predefined scanning sites. Measurements and Main Results: Acute lung injury/acute respiratory distress syndrome was present in all pigs at 90 mins. The number of ultrasound lung comets increased over time and was consistently earlier than the decrease in Pa0(2)/F10(2). At 15 mins, ultrasound lung comets were markedly increased, but no significant changes in Pa0(2)/F10(2) were observed. Accordingly, static respiratory compliance was dramatically reduced at 15 mins compared with baseline (17.04 +/- 1.82 vs. 34.84 +/- 2.62 mL/cm H2O, P < .05). Conclusions: Ultrasound lung comets, assessed by transthoracic echography, detected extravascular lung water accumulation very early in the course of the oleic acid lung injury in pigs, in the presence of a normal Pa0(2)/F10(2). These results suggest that ultrasound lung comets could be a very early, noninvasive, and simple method to detect and quantify pulmonary edema in acute lung injury.