Abstract
Due to wavelength-dependent optical attenuation in the skin, the local fluence at a subcutaneous vessel varies with the optical wavelength in a spectral measurement. Hence compensation for such a spectral attenuation is necessary in quantitative measurements of the oxygen saturation of hemoglobin (sO<sub>2</sub>) in blood vessels in vivo using photoacoustic (PA)imaging. Here, by employing a simplified double-layer skin model, we find that although the absolute value of sO<sub>2</sub> in a vessel is seriously affected by the volume fraction of blood and the spatially averaged sO2 in the dermis, the difference of sO<sub>2</sub> between neighboring vessels is minimally affected. Based on in vivo experiments, we demonstrate that the difference in sO<sub>2</sub> between a typical artery and a typical vein is conserved before and after an experimentally acquired spectral compensation. This conservation holds regardless of the animal's systemic physiological state.
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