High-Quality Passive Acoustic Mapping with the Cross-Correlated Angular Spectrum Method

TL;DR

This paper introduces the AS-TAX method, a novel real-time passive acoustic mapping technique that combines cross-correlation and angular spectrum methods to achieve high-quality imaging with significantly reduced computational complexity, enabling effective monitoring of cavitation activity in focused ultrasound therapy.

Contribution

The paper presents the AS-TAX method, which enhances passive acoustic mapping by suppressing artifacts efficiently and reducing computational load, outperforming traditional methods in image quality and speed.

Findings

AS-TAX achieves comparable image quality to adaptive beamformers.

It reduces computational complexity by two orders of magnitude.

It effectively maps microbubble cavitation activity.

Abstract

While passive acoustic mapping (PAM) has been advanced for monitoring acoustic cavitation activity in focused ultrasound (FUS) therapy, achieving both real-time and high-quality imaging capabilities is still challenging. The angular spectrum (AS) method presents the most efficient algorithm for PAM, but it suffers from artifacts and low resolution due to the diffraction pattern of the imaging array. Data-adaptive beamformers suppress artifacts well, but their overwhelming computational complexity, more than two orders of magnitude higher than the classical time exposure acoustic (TEA) method, hinders their application in real-time. In this work, we introduce the cross-correlated AS method to address the challenge. This method is based on cross-correlating the AS back-propagated wave fields, in the frequency domain, measured by different apodized sub-apertures of the transducer array to provide the normalized correlation coefficient (NCC) matrix for artifacts suppression. We observed that the spatial pattern of NCC matrix is variable which can be utilized by the triple apodization with cross-correlation (TAX) with AS scheme, namely the AS-TAX method, for optimal artifacts suppression outcomes. Both the phantom and mouse tumor experiments showed that: 1) the AS-TAX method has comparable image quality as the data-adaptive beamformers, reducing the energy spread area by 34.8-66.6% and improving image signal-to-noise ratio by 10.7-14.5 dB compared to TEA; 2) it reduces the computational complexity by two orders of magnitude compared to TEA allowing millisecond-level image reconstruction speed with a parallel implementation; 3) it can well map microbubble cavitation activity of different status (stable or inertial). The AS-TAX method represents a real-time approach to monitor cavitation-based FUS therapy with high image quality.