Leveraging natural fluctuations for matrix-based aberration correction in photoacoustic imaging

TL;DR

This paper introduces a novel method to adapt reflection-matrix based aberration correction techniques for photoacoustic imaging by analyzing covariance matrices of dynamic targets, improving deep tissue imaging resolution.

Contribution

It presents a framework that enables direct application of reflection-matrix techniques to photoacoustic imaging of dynamic targets, overcoming previous limitations.

Findings

Successfully applied to vessel-mimicking targets with flowing absorbers.

Validated through simulations and experiments.

Enhanced resolution in photoacoustic imaging by correcting aberrations.

Abstract

Photoacoustic imaging is the leading technique for deep tissue optical imaging, allowing single-shot imaging at depths. However, its resolution may be limited by acoustic aberrations, caused by natural unknown heterogeneities in the tissue speed of sound. In recent years, reflection-matrix based scattering-compensation techniques have been successfully employed in ultrasound, optics, and seismology, to computationally correct such distortions. However, they have not been adapted to photoacoustic imaging since they rely on multiple acquisitions under different controlled excitations, such as input plane-wave illuminations, which do not result in signal changes in photoacoustics. Here, we introduce a framework that enables the direct application of the state-of-the-art reflection-matrix based aberration correction techniques to photoacoustic imaging of dynamic targets. Specifically, we show that a covariance matrix analysis of a conventional set of photoacoustic frames of dynamic targets, such as flowing red blood cells in blood vessels, yields a virtual reflection-matrix that is mathematically analogous to a pulse-echo reflection-matrix, and lends itself to direct processing by conventional reflection-matrix based scattering-compensation algorithms. We validate and demonstrate the approach for photoacoustic aberration correction of vessel-mimicking targets containing flowing absorbers in both simulations and experiments.