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Systematic quantification of differences in shear wave elastography estimates between linear-elastic and viscoelastic material assumptions

Sapna R. Bisht, Abhijit Paul, Panchami Patel, Prachi Thareja, Karla P. Mercado‐Shekhar

2024The Journal of the Acoustical Society of America10 citationsDOI

Abstract

Quantitative, accurate, and standardized metrics are important for reliable shear wave elastography (SWE)-based biomarkers. For over two decades, the linear-elastic material assumption has been employed in SWE modes. In recent years, viscoelasticity estimation methods have been adopted in a few clinical systems. The current study aims to systematically quantify differences in SWE estimates obtained using linear-elastic and viscoelastic material assumptions. An acousto-mechanical simulation framework of acoustic radiation force impulse-based SWE was created to elucidate the effect of material viscosity and shear modulus on SWE estimates. Shear modulus estimates exhibited errors up to 72% when a numerical viscoelastic phantom was assessed as linearly elastic. Shear modulus estimates of polyvinyl alcohol phantoms between rheometry and SWE following the Kelvin-Voigt viscoelastic model assumptions were not significantly different. However, the percentage difference in shear modulus estimates between rheometry and SWE using the linear-elastic assumption was 50.1%-62.1%. In ex vivo liver, the percentage difference in shear modulus estimates between linear-elastic and viscoelastic methods was 76.1%. These findings provide a direct and systematic quantification of the potential error introduced when viscoelastic tissues are imaged with SWE following the linear-elastic assumption. This work emphasizes the need to utilize viscoelasticity estimation methods for developing robust quantitative imaging biomarkers.

Topics & Concepts

ViscoelasticityRheometryShear modulusElastic modulusElastographyMaterials scienceLinear elasticityImaging phantomShear (geology)Acoustic radiation forceMechanicsMathematicsComposite materialAcousticsPhysicsUltrasoundFinite element methodOpticsThermodynamicsUltrasound Imaging and ElastographyPhotoacoustic and Ultrasonic ImagingUltrasound and Hyperthermia Applications