Abstract
Extravascular lung water (EVLW) is a basic symptom of congestive heart failure and other conditions. Computed tomography (CT) is standard to assess EVLW, but it requires ionizing radiation and radiology facilities. Lung ultrasound reverberation artifacts called B-lines have been used to assess EVLW. However, B-line artifact analysis relies on visual interpretation and subjects to inter-observer variability. We developed lung ultrasound surface wave elastography (LUSWE) to measure lung surface wave speed. This research aims to develop LUSWE to measure the change of lung surface wave speed due to lung water in an ex vivo swine lung model. The surface wave speeds of a fresh ex vivo swine lung were measured at four frequencies of 100 Hz, 200 Hz, 300 Hz, and 400 Hz. An amount of water was then filled into the lung through its trachea. Ultrasound imaging was used to guide the water filling until significant changes were visible on the imaging. The lung surface wave speeds were measured. An additional 120 ml of water was then filled into the lung. The lung surface wave speeds were then measured again. The results demonstrated that the lung surface wave speed decreased with respect to water content.
Highlights
Extravascular lung water (EVLW) is common for patients with congestive heart failure and other inflammatory conditions, such as acute respiratory distress syndrome [1]
This pilot study aimed at measuring the effect of lung water on the surface wave speed in an ex vivo swine lung model
The surface wave speed increased with frequency, there was a little drop from 200 Hz to 300 Hz for the water volume of 120 mL
Summary
Extravascular lung water (EVLW) is common for patients with congestive heart failure and other inflammatory conditions, such as acute respiratory distress syndrome [1]. Lung ultrasound reverberation artifacts called B-lines have been used to assess EVLW. Lung ultrasound surface wave elastography (LUSWE) was developed [3,4,5,6] to measure the surface wave speed of a lung and was applied for assessing patients with interstitial lung disease (ILD) [7,8]. We studied a lung phantom sponge model using LUSWE to measure the water effects on the surface wave speed of sponges [9,10,11]. We could not identify the trend of surface wave speed with water in the sponge phantom model. This pilot study aimed at measuring the effect of lung water on the surface wave speed in an ex vivo swine lung model
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