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Two-dimensional complex shear modulus imaging of soft tissues by integration of Algebraic Helmoltz Inversion and LMS filter into dealing with noisy data: A simulation study

Pham-Thi, T.-H. and Luong, Q.-H. and Nguyen, V.-D. and Tran, D.-T. and Huynh, H.-T. (2020) Two-dimensional complex shear modulus imaging of soft tissues by integration of Algebraic Helmoltz Inversion and LMS filter into dealing with noisy data: A simulation study. Mathematical Biosciences and Engineering, 17 (1). pp. 404-417. ISSN 15471063

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Abstract

Elasticity and viscosity of soft tissues can be obtained from the complex shear modulus imaging (CSMI). CSMI is often used not only to investigate the structure of tissues but also to detect tumors in tissues. One of the most popular ways to categorize the methods used in CSMI is into quasi-static and dynamic methods. In the dynamic method, a force excitation is used to create the shear wave propagation, and the particle velocities are measured to extract their amplitude and phase at spatial locations. These parameters are then employed to directly or indirectly estimate the Complex Shear Modulus (CSM) represented by elasticity and viscosity. Algebraic Helmholtz Inversion (AHI) algorithm provides the direct estimation of CSM using the Finite Difference Time Domain (FDTD) technique. The limitation of this method, however, is that the noise generated from measuring the particle velocity strongly degrades the accuracy of the estimation. To overcome this problem, we proposed in this paper an adaptive AHI (AAHI) algorithm that offers a good performance in CSMI with a mean error of 2:06%. © 2020 the Author(s).

Item Type: Article
Divisions: Faculties > Faculty of Control Engineering
Identification Number: 10.3934/mbe.2020022
Uncontrolled Keywords: Algebra; Computerized tomography; Elastic moduli; Elasticity; Finite difference time domain method; Histology; Shear flow; Shear strain; Shear waves; Tissue; Velocity control; Viscosity; Wave propagation; Complex shear modulus; Finite difference time domain technique; Force excitation; Helmholtz; Least mean squares; Particle velocities; Simulation studies; Spatial location; Time domain analysis; algorithm; automated pattern recognition; computer simulation; diagnostic imaging; human; imaging phantom; mechanical stress; neoplasm; reproducibility; signal processing; theoretical model; viscosity; Young modulus; Algorithms; Computer Simulation; Elastic Modulus; Humans; Models, Theoretical; Neoplasms; Pattern Recognition, Automated; Phantoms, Imaging; Reproducibility of Results; Signal Processing, Computer-Assisted; Stress, Mechanical; Viscosity
Additional Information: Language of original document: English. All Open Access, Gold.
URI: http://eprints.lqdtu.edu.vn/id/eprint/9186

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