Tissue elasticity reconstruction based on 3-dimensional finite-element model

Makoto Yamakawa; Tsuyoshi Shiina

doi:10.1143/jjap.38.3393

Tissue elasticity reconstruction based on 3-dimensional finite-element model

Makoto Yamakawa, Tsuyoshi Shiina

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

2 Citations (Scopus)

Abstract

We describe a method of estimating the elasticity distribution in tissue based on the 3-D finite-element model. Generally, the elastic modulus is calculated from the strain and the stress. The strain field can be estimated from the RF signals measured for pre- and postcompressed tissue, while it is impossible to directly measure the stress field within the tissue. Therefore, we reconstruct the tissue elasticity distribution by solving the inverse problem, that is, by estimating the elasticity modulus from the axial strain field and the external pressure distribution at the surface of the tissue. We have performed a simulation and a phantom experiment to demonstrate the ability of the proposed method. The results verified that the method is able to detect tumors more quantitatively than the conventional method based on the 2-D model, even for lesions invisible in a B-mode image.

Original language	English
Pages (from-to)	3393-3398
Number of pages	6
Journal	Japanese Journal of Applied Physics, Part 1: Regular Papers and Short Notes and Review Papers
Volume	38
Issue number	5 B
DOIs	https://doi.org/10.1143/jjap.38.3393
Publication status	Published - 1999
Externally published	Yes

Keywords

Elasticity
Finite-element method
Inverse problem
Strain
Stress
Tissue

ASJC Scopus subject areas

Engineering(all)
Physics and Astronomy(all)

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10.1143/jjap.38.3393

Cite this

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abstract = "We describe a method of estimating the elasticity distribution in tissue based on the 3-D finite-element model. Generally, the elastic modulus is calculated from the strain and the stress. The strain field can be estimated from the RF signals measured for pre- and postcompressed tissue, while it is impossible to directly measure the stress field within the tissue. Therefore, we reconstruct the tissue elasticity distribution by solving the inverse problem, that is, by estimating the elasticity modulus from the axial strain field and the external pressure distribution at the surface of the tissue. We have performed a simulation and a phantom experiment to demonstrate the ability of the proposed method. The results verified that the method is able to detect tumors more quantitatively than the conventional method based on the 2-D model, even for lesions invisible in a B-mode image.",

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AU - Yamakawa, Makoto

AU - Shiina, Tsuyoshi

PY - 1999

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N2 - We describe a method of estimating the elasticity distribution in tissue based on the 3-D finite-element model. Generally, the elastic modulus is calculated from the strain and the stress. The strain field can be estimated from the RF signals measured for pre- and postcompressed tissue, while it is impossible to directly measure the stress field within the tissue. Therefore, we reconstruct the tissue elasticity distribution by solving the inverse problem, that is, by estimating the elasticity modulus from the axial strain field and the external pressure distribution at the surface of the tissue. We have performed a simulation and a phantom experiment to demonstrate the ability of the proposed method. The results verified that the method is able to detect tumors more quantitatively than the conventional method based on the 2-D model, even for lesions invisible in a B-mode image.

AB - We describe a method of estimating the elasticity distribution in tissue based on the 3-D finite-element model. Generally, the elastic modulus is calculated from the strain and the stress. The strain field can be estimated from the RF signals measured for pre- and postcompressed tissue, while it is impossible to directly measure the stress field within the tissue. Therefore, we reconstruct the tissue elasticity distribution by solving the inverse problem, that is, by estimating the elasticity modulus from the axial strain field and the external pressure distribution at the surface of the tissue. We have performed a simulation and a phantom experiment to demonstrate the ability of the proposed method. The results verified that the method is able to detect tumors more quantitatively than the conventional method based on the 2-D model, even for lesions invisible in a B-mode image.

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KW - Finite-element method

KW - Inverse problem

KW - Strain

KW - Stress

KW - Tissue

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Tissue elasticity reconstruction based on 3-dimensional finite-element model

Abstract

Keywords

ASJC Scopus subject areas

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