Abstract
Photoacoustic (PA) imaging is an emerging technology that combines structural and functional imaging of tissues using laser and ultrasound energy. We evaluated the ability of PA imaging system to measure real-time systemic and microvascular mean oxygen saturation (mSAO2) in a rat model of hypoxic shock. Male Sprague Dawley rats (n = 6) underwent femoral artery catherization and were subjected to acute hypoxia by lowering the fraction of inspired oxygen (FiO2) from 1.0 to 0.21, and then to 0.08. PA measurements of mSaO2 were taken in the femoral artery near the catheter tip using the Vevo 2100 LAZR at each FiO2 and compared to co-oximetry on blood removed from the femoral catheter. Both co-oximetry and PA imaging measured a similar stepwise decline in femoral artery mSaO2 as FiO2 was lowered. We also measured mSaO2 in the feed arteriole of the rat spinotrapezius muscle and adjacent microvessels (n = 6) using PA imaging. A significant decrease in mSaO2 in both the feed arteriole and adjacent microvessels was recorded as FiO2 was decreased from 1.0 to 0.08. Moreover, we detected a rapid return toward baseline mSaO2 in the feed arteriole and microvessels when FiO2 was increased from 0.08 to 1.0. Thus, PA imaging is noninvasive imaging modality that can accurately measure real-time oxygen saturation in the macro and microcirculation during acute hypoxia. This proof-of-concept study is a first step in establishing PA imaging as an investigational tool in critical illness.