Experimental validation of simultaneous excitation of orthogonal coded push pulses for fast shear wave elastography

Abstract

Shear wave elastography is useful for quantitatively evaluating tissue elasticity by measuring the speed of a shear wave induced within the body by acoustic radiation. The purpose of this paper is to demonstrate a pushing-and-imaging sequence, coded push pulse excitation to increase the signal-to-noise ratio (SNR) of the observed shear wave propagation without increasing measurement time and push pulse amplitude. In this paper, we irradiate multiple coded-pulse sequences from different locations at the same time and separate overlapped shear waves by decoding to quickly image a wider area with high SNR. We divided the aperture into two sub-apertures and irradiated coded pulse sequences from each sub-aperture at the same time using Orthogonal Golay Code (OGC). The received shear waves induced by two push pulse sequences are overlapped but are separated orthogonaly after postprocessing. As a result, measurement time decreases and SNR increases due to push pulse compression. The proposed method was validated with an elasticity quality assurance phantom using a linear probe (VeraSonics, L7-4).