Parametric Analysis of SV Mode Shear Waves in Transversely Isotropic Materials Using Ultrasonic Rotational 3-D SWEI

Parametric Analysis of SV Mode Shear Waves in Transversely Isotropic Materials Using Ultrasonic Rotational 3-D SWEI

Ultrasonic rotational 3-D shear wave elasticity imaging (SWEI) has been used to induce and evaluate multiple shear wave modes, including both the shear horizontal (SH) and shear vertical (SV) modes in in vivo muscle. Observations of both the SH and SV modes allow the muscle to be characterized as an...

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Bibliographic Details
Published in:IEEE transactions on ultrasonics, ferroelectrics, and frequency control Vol. 69; no. 11; pp. 3145 - 3154
Main Authors: Knight, Anna E, Jin, Felix Q, Paley, Courtney Trutna, Rouze, Ned C, Moavenzadeh, Spencer R, Pietrosimone, Laura S, Palmeri, Mark L, Nightingale, Kathryn R
Format: Journal Article
Language:English
Published: United States The Institute of Electrical and Electronics Engineers, Inc. (IEEE) 01-11-2022
Subjects:
Amplitudes
Anisotropy
Elasticity
Elasticity Imaging Techniques - methods
Evaluation
Geometry
Green's functions
Interrogation
Isotropic material
Muscles
Parameters
Parametric analysis
Parametric statistics
SH waves
Shear modulus
Transverse shear
Ultrasonics
Ultrasonography
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Summary:Ultrasonic rotational 3-D shear wave elasticity imaging (SWEI) has been used to induce and evaluate multiple shear wave modes, including both the shear horizontal (SH) and shear vertical (SV) modes in in vivo muscle. Observations of both the SH and SV modes allow the muscle to be characterized as an elastic, incompressible, transversely isotropic (ITI) material with three parameters: the longitudinal shear modulus μ , the transverse shear modulus μ , and the tensile anisotropy χ . Measurement of the SV wave is necessary to characterize χ , but the factors that influence SV mode generation and characterization with ultrasonic SWEI are complicated. This work uses Green's function (GF) simulations to perform a parametric analysis to determine the optimal interrogation parameters to facilitate visualization and quantification of SV mode shear waves in muscle. We evaluate the impact of five factors: μ , μ , χ , fiber tilt angle [Formula: see text], and F-number of the push geometry on SV mode speed, amplitude, and rotational distribution. These analyses demonstrate that the following hold: 1) as μ increases, SV waves decrease in amplitude so are more difficult to measure in SWEI imaging; 2) as μ increases, the SV wave speeds increase; 3) as χ increases, the SV waves increase in speed and separate from the SH waves; 4) as fiber tilt angle [Formula: see text] increases, the measurable SV waves remain approximately the same speed, but change in strength and in rotational distribution; and 5) as the push beam geometry changes with F-number, the measurable SV waves remain approximately the same speed, but change in strength and rotational distribution. While specific SV mode speeds depend on the combinations of all parameters considered, measurable SV waves can be generated and characterized across the range of parameters considered. To maximize measurable SV waves separate from the SH waves, it is recommended to use an F/1 push geometry and [Formula: see text].
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ISSN:0885-3010
1525-8955
DOI:10.1109/TUFFC.2022.3203935