Abstract

Reflection artifacts caused by acoustic inhomogeneities constitute a major problem in epi-mode biomedical photoacoustic imaging. Photoacoustic transients from the skin and superficial optical absorbers traverse into the tissue and reflect off echogenic structures to generate reflection artifacts. These artifacts cause difficulties in the interpretation of images and reduce contrast and imaging depth. We recently developed a method called PAFUSion (photoacoustic-guided focused ultrasound) to circumvent the problem of reflection artifacts in photoacoustic imaging. We already demonstrated that the photoacoustic signals can be backpropagated using synthetic aperture pulse-echo data for identifying and reducing reflection artifacts in vivo. In this work, we propose an alternative variant of PAFUSion in which synthetic backpropagation of photoacoustic signals is based on multi-angled plane-wave ultrasound measurements. We implemented plane-wave and synthetic aperture PAFUSion in a handheld ultrasound/photoacoustic imaging system and demonstrate reduction of reflection artifacts in phantoms and in vivo measurements on a human finger using both approaches. Our results suggest that, while both approaches are equivalent in terms of artifact reduction efficiency, plane-wave PAFUSion requires less pulse echo acquisitions when the skin absorption is the main cause of reflection artifacts.

Highlights

  • Photoacoustic (PA) imaging allows the detection of optical absorption contrast inside optically scattering tissue via ultrasound (US) detection of thermoelastically induced US, when irradiating the tissue with pulsed laser light [1, 2]

  • We propose an alternative variant of PAFUSion in which synthetic backpropagation of photoacoustic signals is based on multi-angled planewave ultrasound measurements

  • We implemented plane-wave and synthetic aperture PAFUSion in a handheld ultrasound/photoacoustic imaging system and demonstrate reduction of reflection artifacts in phantoms and in vivo measurements on a human finger using both approaches. While both approaches are equivalent in terms of artifact reduction efficiency, plane-wave PAFUSion requires less pulse echo acquisitions when the skin absorption is the main cause of reflection artifacts

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Summary

Introduction

Photoacoustic (PA) imaging (optoacoustic imaging) allows the detection of optical absorption contrast inside optically scattering tissue via ultrasound (US) detection of thermoelastically induced US, when irradiating the tissue with pulsed laser light [1, 2]. High light fluence beneath the US probe results in strong PA signals from the skin and superficial blood vessels. These PA transients will traverse into the tissue and reflect off the echogenic structures to generate reflection artifacts (echo clutter) [10,11,12,13,14,15,16], that can significantly reduce contrast and imaging depth [10, 13]. It is important to identify and reduce in-plane reflection artifacts for clinically successful high-contrast deep tissue epi-PA imaging

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