C-Elastography: In Vitro Feasibility Phantom Study

Danial P. Shahraki; Viksit Kumar; Siavash Ghavami; Matthew W. Urban; Azra Alizad; Bojan B. Guzina; Mostafa Fatemi

doi:10.1016/j.ultrasmedbio.2020.02.005

C-Elastography: In Vitro Feasibility Phantom Study

Danial P. Shahraki, Viksit Kumar, Siavash Ghavami, Matthew W. Urban, Azra Alizad, Bojan B. Guzina, Mostafa Fatemi

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

C-Elastography (CE) is a new ultrasound technique that locally maps the non-linear elasticity of soft tissue using low-frequency (150–250 Hz) shear waves generated by the acoustic radiation force (ARF). CE is based on a recent finding that the magnitude of the ARF in an isotropic tissue-like solid is related linearly to a third-order modulus of elasticity, C, which is responsible for the coupling between deviatoric and volumetric constitutive behaviors. The main objective of the work described here was to examine the feasibility of using and performance of C-elastography in differentiating and characterizing soft tissue via a pilot study on ex vivo tissue and tissue-mimicking inclusions cast in a gelatin block. In this vein, the CE technique deploys a combination of ultrasound motion sensing and 3-D visco-elastodynamic simulation to estimate the non-linear modulus C. As ultrasound focusing inherently confines the ARF to a small region, CE provides the means for measuring C within O(mm³) volumes. Equipped with such data analysis, we performed in vitro CE experiments on agar-based, xenograft and normal breast tissue samples embedded in a gelatin matrix. The compound C-elastograms indicate marked (and sharp) C-contrast, with average values of 1.9 and 5.6 at push points inside the featured soft and hard inclusions, respectively.

Original language	English (US)
Pages (from-to)	1738-1754
Number of pages	17
Journal	Ultrasound in Medicine and Biology
Volume	46
Issue number	7
DOIs	https://doi.org/10.1016/j.ultrasmedbio.2020.02.005
State	Published - Jul 2020
Externally published	Yes

Bibliographical note

Funding Information:
This work was supported by National Institutes of Health Grant EB23113. The authors Dr. Matthew Goetz for providing the xenograft breast tumors. The contributions of Dr. Roman Tokmashev during early implementation of C-elastography and the computing resources provided by the University of Minnesota's Supercomputing Institute are kindly acknowledged. Finally, the authors of this article have no conflicts of interest to disclose.

Funding Information:
This work was supported by National Institutes of Health Grant EB23113. The authors Dr. Matthew Goetz for providing the xenograft breast tumors. The contributions of Dr. Roman Tokmashev during early implementation of C-elastography and the computing resources provided by the University of Minnesota's Supercomputing Institute are kindly acknowledged.

Publisher Copyright:
© 2020 World Federation for Ultrasound in Medicine & Biology

Keywords

Acoustic radiation force
C-Elastography
Non-linear elasticity imaging
Shear wave
Tissue differentiation

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title = "C-Elastography: In Vitro Feasibility Phantom Study",

abstract = "C-Elastography (CE) is a new ultrasound technique that locally maps the non-linear elasticity of soft tissue using low-frequency (150–250 Hz) shear waves generated by the acoustic radiation force (ARF). CE is based on a recent finding that the magnitude of the ARF in an isotropic tissue-like solid is related linearly to a third-order modulus of elasticity, C, which is responsible for the coupling between deviatoric and volumetric constitutive behaviors. The main objective of the work described here was to examine the feasibility of using and performance of C-elastography in differentiating and characterizing soft tissue via a pilot study on ex vivo tissue and tissue-mimicking inclusions cast in a gelatin block. In this vein, the CE technique deploys a combination of ultrasound motion sensing and 3-D visco-elastodynamic simulation to estimate the non-linear modulus C. As ultrasound focusing inherently confines the ARF to a small region, CE provides the means for measuring C within O(mm3) volumes. Equipped with such data analysis, we performed in vitro CE experiments on agar-based, xenograft and normal breast tissue samples embedded in a gelatin matrix. The compound C-elastograms indicate marked (and sharp) C-contrast, with average values of 1.9 and 5.6 at push points inside the featured soft and hard inclusions, respectively.",

keywords = "Acoustic radiation force, C-Elastography, Non-linear elasticity imaging, Shear wave, Tissue differentiation",

author = "Shahraki, {Danial P.} and Viksit Kumar and Siavash Ghavami and Urban, {Matthew W.} and Azra Alizad and Guzina, {Bojan B.} and Mostafa Fatemi",

note = "Funding Information: This work was supported by National Institutes of Health Grant EB23113. The authors Dr. Matthew Goetz for providing the xenograft breast tumors. The contributions of Dr. Roman Tokmashev during early implementation of C-elastography and the computing resources provided by the University of Minnesota's Supercomputing Institute are kindly acknowledged. Finally, the authors of this article have no conflicts of interest to disclose. Funding Information: This work was supported by National Institutes of Health Grant EB23113. The authors Dr. Matthew Goetz for providing the xenograft breast tumors. The contributions of Dr. Roman Tokmashev during early implementation of C-elastography and the computing resources provided by the University of Minnesota's Supercomputing Institute are kindly acknowledged. Publisher Copyright: {\textcopyright} 2020 World Federation for Ultrasound in Medicine & Biology",

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AU - Alizad, Azra

AU - Guzina, Bojan B.

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C-Elastography: In Vitro Feasibility Phantom Study

Abstract

Bibliographical note

Keywords

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