Radiological Society of North America/Quantitative Imaging Biomarker Alliance Shear Wave Speed Bias Quantification in Elastic and Viscoelastic Phantoms

Palmeri, Mark L.; Milkowski, Andy; Barr, Richard G.; Carson, Paul L.; Couade, Mathieu; Chen, Jun; Chen, Shigao; Dhyani, Manish; Ehman, Richard L.; Garra, Brian S.; Gee, Albert; Guenette, Gilles; Hah, Zaegyoo; Lynch, Ted; Macdonald, Michael C.; Managuli, Ravi; Miette, Véronique; Nightingale, Kathryn R.; Obuchowski, Nancy A.; Rouze, Ned C.; Morris, D. Cody; Fielding, Shana; Deng, Yufeng; Chan, David Y.; Choudhury, Kingshuk Roy; Yang, Sheng; Samir, Anthony E.; Shamdasani, Vijay; Urban, Matthew W.; Wear, Keith A.; Xie, Hua; Ozturk, Arinc; Qiang, Boqin; Song, Pengfei; McAleavey, Stephen A.; Rosenzweig, Stephen; Wang, Michael; Okamura, Yoko; McLaughlin, Glen; Chen, Yuling; Napolitano, David; Carlson, Lindsey; Erpelding, Todd N.; Hall, Timothy J.

doi:10.1002/jum.15609

Cited by 34 publications

(22 citation statements)

References 22 publications

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“…A notable limitation of this work is that it neglects viscosity. Viscosity introduces dispersion and attenuation in shear wave elastography data, which has been shown to bias estimated parameters based upon group speeds [60]. We have observed some dispersion in vastus lateralis data, primarily across the fibers with less dispersion along the fibers [61], which is consistent with reports from the literature [45].…”

Section: Discussionsupporting

confidence: 85%

Full Characterization of in vivo Muscle as an Elastic, Incompressible, Transversely Isotropic Material Using Ultrasonic Rotational 3D Shear Wave Elasticity Imaging

Knight

Trutna

Rouze

et al. 2022

IEEE Trans. Med. Imaging

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Using a 3D rotational shear wave elasticity imaging (SWEI) setup, 3D shear wave data were acquired in the vastus lateralis of a healthy volunteer. The innate tilt between the transducer face and the muscle fibers results in the excitation of multiple shear wave modes, allowing for more complete characterization of muscle as an elastic, incompressible, transversely isotropic (ITI) material. The ability to measure both the shear vertical (SV) and shear horizontal (SH) wave speed allows for measurement of three independent parameters needed for full ITI material characterization: the longitudinal shear modulus µ L , the transverse shear modulus µ T , and the tensile anisotropy χ E . Herein we develop and validate methodology to estimate these parameters and measure them in vivo, with µ L = 5.77 ± 1.00 kPa, µ T = 1.93 ± 0.41 kPa (giving shear anisotropy χµ = 2.11 ± 0.92), and χ E = 4.67 ± 1.40 in a relaxed vastus lateralis muscle. We also demonstrate that 3D SWEI can be used to more accurately characterize muscle mechanical properties as compared to 2D SWEI.

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Section: Discussionsupporting

confidence: 85%

Full Characterization of in vivo Muscle as an Elastic, Incompressible, Transversely Isotropic Material Using Ultrasonic Rotational 3D Shear Wave Elasticity Imaging

Knight

Trutna

Rouze

et al. 2022

IEEE Trans. Med. Imaging

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“…2b). These values cover the range of depths relevant to liver assessment, consistent with similar studies analyzing depth-dependent biases (Chang et al 2013;Hall et al 2013;Wang et al 2014;Dhyani et al 2018;Palmeri et al 2021). For the third group of measurements, the acquisition box was fixed at 20 mm below the US probe, and the ROI was placed in the center of the box.…”

Section: Experimental Procedure: Confounder Analysissupporting

confidence: 72%

“…A decay in SWD can be caused only by frequency-dependent effects, that is, by effects that influence each phase velocity differently. As discussed, in viscoelastic media, attenuation depends on the frequency and lowers the SNR of higher-frequency components (Palmeri et al 2021). This may affect the estimations of high-frequency phase velocities (Deffieux et al 2009) and introduce biases in the computation of the dispersion slope.…”

Section: Discussionmentioning

confidence: 99%

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Sources of Variability in Shear Wave Speed and Dispersion Quantification with Ultrasound Elastography: A Phantom Study

Martiartu

Nambiar

Kirchner

et al. 2021

Ultrasound in Medicine & Biology

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There is a growing interest in quantifying shear-wave dispersion (SWD) with ultrasound shear-wave elastography (SWE). Recent studies suggest that SWD complements shear-wave speed (SWS) in diffuse liver disease diagnosis. To accurately interpret these metrics in clinical practice, we analyzed the impact of operatordependent acquisition parameters on SWD and SWS measurements. Considered parameters were the acquisition depth, lateral position and size of the region of interest (ROI), as well as the size of the SWE acquisition box. Measurements were performed using the Canon Aplio i800 system (Canon Medical Systems, Otawara, Tochigi, Japan) and four homogeneous elasticity phantoms with certified stiffness values ranging from 3.7 to 44 kPa. In general, SWD exhibited two to three times greater variability than SWS. The acquisition depth was the main variance-contributing factor for both SWS and SWD, which decayed significantly with depth. The lateral ROI position contributed as much as the acquisition depth to the total variance in SWD. Locations close to the initial shear-wave excitation pulse were more robust to biases because of inaccurate probeÀphantom coupling. The size of the ROI and acquisition box did not introduce significant variations. These results suggest that future guidelines on multiparametric elastography should account for the depth-and lateral-dependent variability of measurements.

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“…Validation of mechanical properties against specific microstructural findings on histology and prognostic utility beyond common clinical tests (eGFR and proteinuria) are also necessary steps for establishing clinical utility. Reconciling the results from ultrasound-based methods implemented by different vendors is an important step as well as further exploring the role of evaluating the viscoelastic properties of the renal tissue 88 .…”

Section: Future Opportunities For Renal Elastography Investigationmentioning

confidence: 99%

Novel Uses of Ultrasound to Assess Kidney Mechanical Properties

et al. 2021

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Ultrasound is a key imaging tool for the evaluation of the kidney. Over the last two decades, methods to measure the mechanical properties of soft tissues have been developed and used in clinical practice, though the use in the kidney has not been as widespread as for other applications. The mechanical properties of the kidney are determined by the structure and composition of the renal parenchyma as well as the perfusion characteristics. As pathological processes change these factors, the mechanical properties change and can be used for diagnostic purposes as well as monitoring treatment or disease progression. Ultrasound-based elastography methods for evaluating the mechanical properties of the kidney use focused ultrasound beams to perturb the kidney and then high frame rate ultrasound methods are used to measure the resulting motion. The motion is analyzed to estimate the mechanical properties. This review will describe the principles of these methods and discuss several seminal studies related to characterizing the kidney. Additionally, an overview of the clinical use of elastography methods in native and kidney allografts will be provided. Perspectives on future developments and uses of elastography technology along with other complementary ultrasound imaging modalities will be provided.

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Radiological Society of North America/Quantitative Imaging Biomarker Alliance Shear Wave Speed Bias Quantification in Elastic and Viscoelastic Phantoms

Cited by 34 publications

References 22 publications

Full Characterization of in vivo Muscle as an Elastic, Incompressible, Transversely Isotropic Material Using Ultrasonic Rotational 3D Shear Wave Elasticity Imaging

Full Characterization of in vivo Muscle as an Elastic, Incompressible, Transversely Isotropic Material Using Ultrasonic Rotational 3D Shear Wave Elasticity Imaging

Sources of Variability in Shear Wave Speed and Dispersion Quantification with Ultrasound Elastography: A Phantom Study

Novel Uses of Ultrasound to Assess Kidney Mechanical Properties

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