Virtual Source Synthetic Aperture for Accurate Lateral Displacement Estimation in Ultrasound Elastography

TL;DR

This paper introduces the use of Virtual Source Synthetic Aperture (VSSA) imaging to enhance lateral displacement estimation in ultrasound elastography, achieving higher resolution and sampling frequency for more accurate tissue characterization.

Contribution

The paper presents a novel application of VSSA beamforming combined with OVERWIND elastography to improve lateral displacement estimation accuracy in ultrasound imaging.

Findings

Significant improvement in lateral displacement estimation accuracy.

Enhanced lateral resolution and sampling frequency.

Effective application demonstrated through simulations and experiments.

Abstract

Ultrasound elastography is an emerging noninvasive imaging technique wherein pathological alterations can be visualized by revealing the mechanical properties of the tissue. Estimating tissue displacement in all directions is required to accurately estimate the mechanical properties. Despite capabilities of elastography techniques in estimating displacement in both axial and lateral directions, estimation of axial displacement is more accurate than lateral direction due to higher sampling frequency, higher resolution and having a carrier signal propagating in the axial direction. Among different ultrasound imaging techniques, Synthetic Aperture (SA) has better lateral resolution than others, but it is not commonly used for ultrasound elastography due to its limitation in imaging depth of field. Virtual source synthetic aperture (VSSA) imaging is a technique to implement synthetic aperture beamforming on the focused transmitted data to overcome limitation of SA in depth of field while maintaining the same lateral resolution as SA. Besides lateral resolution, VSSA has the capability of increasing sampling frequency in the lateral direction without interpolation. In this paper, we utilize VSSA to perform beamforming to enable higher resolution and sampling frequency in the lateral direction. The beamformed data is then processed using our recently published elastography technique, OVERWIND [1]. Simulation and experimental results show substantial improvement in estimation of lateral displacements.