Dynamic Relative Regional Lung Strain Estimated by Electrical Impedance Tomography in an Experimental Model of ARDS

To analyze the role of PEEP on dynamic relative regional strain (DRRS) in a model of ARDS, respective maps were generated by electrical impedance tomography (EIT). Eight ARDS pigs submitted to PEEP steps of 0, 5, 10, and 15 cm H O at fixed ventilation were evaluated by EIT images. DRRS was calculated as (V /EELI)/(V /EELI ), where the tidal volume (V ) and end-expiratory lung impedance (EELI) are the tidal and end-expiratory change in lung impedance, respectively. The measurement at 15 PEEP was taken as reference (end-expiratory transpulmonary pressure > 0 cm H O). The relationship between EIT variables (center of ventilation, EELI, and DRRS) and airway pressures was assessed with mixed-effects models using EIT measurements as dependent variables and PEEP as fixed-effect variable. At constant ventilation, respiratory compliance increased progressively with PEEP (lowest value at zero PEEP 10 ± 3 mL/cm H O and highest value at 15 PEEP 16 ± 6 mL/cm H O; < .001), whereas driving pressure decreased with PEEP (highest value at zero PEEP 34 ± 6 cm H O and lowest value at 15 PEEP 21 ± 4 cm H O; < .001). The mixed-effect regression models showed that the center of ventilation moved to dorsal lung areas with a slope of 1.81 (1.44-2.18) % points by each cm H O of PEEP; < .001. EELI increased with a slope of 0.05 (0.02-0.07) (arbitrary units) for each cm H O of PEEP; < .001. DRRS maps showed that local strain in ventral lung areas decreased with a slope of -0.02 (-0.24 to 0.15) with each cm H O increase of PEEP; < .001. EIT-derived DRRS maps showed high strain in ventral lung zones at low levels of PEEP. The findings suggest overdistention of the baby lung.