Ultrasonic Estimation of Soft Tissue Visco Elastic Properties

TL;DR

This paper introduces a finite element analysis method to estimate shear wave speed in soft tissues, enhancing the accuracy of mechanical property measurement for diagnostic purposes using ultrasound imaging.

Contribution

It presents a novel finite element simulation approach for estimating shear wave speed in soft tissues, improving upon traditional ultrasound-based methods.

Findings

Finite element model successfully estimates shear wave speed.

Agar-gelatine model mimics soft tissue properties.

Time-To-Peak displacement method effectively tracks wave propagation.

Abstract

Conventional imaging of diagnostic ultrasound is widely used. Although it makes the differences in the soft tissues echogenicities' apparent and clear, it fails in describing and estimating the soft tissue mechanical properties. It cannot portray their mechanical properties, such as the elasticity and stiffness. Estimating the mechanical properties increases chances of the identification of lesions or any pathological changes. Physicians are now characterizing the tissue's mechanical properties as diagnostic metrics. Estimating the tissue's mechanical properties is achieved by applying an Acoustic Radiation Force Impulse (ARFI) on the tissue and calculating the resulted shear wave speed. Due to the difficulty of calculating the shear wave speed precisely inside the tissue, it is estimated by analyzing ultrasound images of the tissue at a very high frame rate. In this study, the shear wave speed is estimated using finite element analysis. A two-dimensional model is constructed to simulate the tissue's mechanical properties. For a generalized soft tissue model, Agar-gelatine model is used because it has similar properties to the soft tissue. A point force is applied at the center of the proposed model. As a result of this force, a deformation is caused. Peak displacements are tracked along the lateral dimension of the model to estimate the shear wave speed of the propagating wave using the Time-To-Peak displacement (TTP) method.