SWENet: A Physics-Informed Deep Neural Network (PINN) for Shear Wave Elastography

Shear wave elastography (SWE) enables the measurement of elastic properties of soft materials in a non-invasive manner and finds broad applications in various disciplines. The state-of-the-art SWE methods rely on the measurement of local shear wave speeds to infer material parameters and suffer from...

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Bibliographic Details
Published in:IEEE transactions on medical imaging 2024-04, Vol.43 (4), p.1434-1448
Main Authors: Yin, Ziying, Li, Guo-Yang, Zhang, Zhaoyi, Zheng, Yang, Cao, Yanping
Format: Article
Language:English
Subjects:
Artificial neural networks
Biological neural networks
Biological tissues
Brain
deep learning
Elastic properties
Elasticity Imaging Techniques - methods
Elastography
Heterogeneity
Inclusions
inverse problem
Magnetic resonance
Mathematical models
Mechanical properties
Neural networks
Neural Networks, Computer
phantom and ex vivo experiments
Phantoms
Physics
physics-informed neural network
Shear modulus
Shear wave elastography
Solid tumors
Spatial variations
Training
tumor biomechanics
Ultrasonography
Wave diffraction
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Summary:Shear wave elastography (SWE) enables the measurement of elastic properties of soft materials in a non-invasive manner and finds broad applications in various disciplines. The state-of-the-art SWE methods rely on the measurement of local shear wave speeds to infer material parameters and suffer from wave diffraction when applied to soft materials with strong heterogeneity. In the present study, we overcome this challenge by proposing a physics-informed neural network (PINN)-based SWE (SWENet) method. The spatial variation of elastic properties of inhomogeneous materials has been introduced in the governing equations, which are encoded in SWENet as loss functions. Snapshots of wave motions have been used to train neural networks, and during this course, the elastic properties within a region of interest illuminated by shear waves are inferred simultaneously. We performed finite element simulations, tissue-mimicking phantom experiments, and ex vivo experiments to validate the method. Our results show that the shear moduli of soft composites consisting of matrix and inclusions of several millimeters in cross-section dimensions with either regular or irregular geometries can be identified with excellent accuracy. The advantages of the SWENet over conventional SWE methods consist of using more features of the wave motions and enabling seamless integration of multi-source data in the inverse analysis. Given the advantages of SWENet, it may find broad applications where full wave fields get involved to infer heterogeneous mechanical properties, such as identifying small solid tumors with ultrasound SWE, and differentiating gray and white matters of the brain with magnetic resonance elastography.
ISSN:0278-0062
1558-254X
1558-254X
DOI:10.1109/TMI.2023.3338178