High-Spatiotemporal-Resolution Visualization of Myocardial Strains Through Vector Doppler Estimation: A Small-Animal Study

High-Spatiotemporal-Resolution Visualization of Myocardial Strains Through Vector Doppler Estimation: A Small-Animal Study

High-frequency ultrasound (HFUS) imaging is extensively used for cardiac diseases in small animals due to its high spatial resolution. However, there is a lack of a system that can provide a 2-D high-spatiotemporal dynamic visualization of mouse myocardial strains. In this article, a dynamic HFUS (4...

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Bibliographic Details
Published in:IEEE transactions on ultrasonics, ferroelectrics, and frequency control Vol. 69; no. 6; pp. 1859 - 1870
Main Authors: Huang, Hsin, Chang, Wei-Ting, Huang, Chih-Chung
Format: Journal Article
Language:English
Published: United States IEEE 01-06-2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Animals
Circumferences
Doppler effect
Estimation
Heart - diagnostic imaging
Heart Diseases
High resolution
High-frequency ultrasound (HFUS)
Image resolution
Imaging
In vitro methods and tests
In vivo methods and tests
Mice
myocardial strain imaging
Myocardium
Regional analysis
small-animal imaging
Spatial resolution
Strain
ultrafast ultrasound
Ultrasonography
Ultrasonography, Doppler
vector Doppler imaging (VDI)
Ventricular Function, Left
Visualization
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Summary:High-frequency ultrasound (HFUS) imaging is extensively used for cardiac diseases in small animals due to its high spatial resolution. However, there is a lack of a system that can provide a 2-D high-spatiotemporal dynamic visualization of mouse myocardial strains. In this article, a dynamic HFUS (40 MHz) high-resolution strain imaging was developed through the vector Doppler imaging. Following in vitro tests using a rubber balloon phantom, in vivo experiments were performed on wild-type (WT) and myocardial infarction (MI) mice. High-resolution dynamic images of myocardial strains were obtained in the longitudinal, radial, and circumferential directions at a frame rate of 1 kHz. Global peak strain values for WT mice were −19.3% ± 1.3% (longitudinal), 31.4% ± 1.7% (radial in the long axis), −19.9% ±.8% (circumferential), and 34.4% ± 1.9% (radial in the short axis); those for the MI mice were −16.1% ±.9% (longitudinal), 26.8% ± 2.9% (radial in the long axis), −15.2% ± 2.7% (circumferential), and 21.6% ± 4.8% (radial in the short axis). These results indicate that the strains for MI mice are significantly lower than those for WT mice. Regional longitudinal strain curves in the epicardial, midcardial, and endocardial layers were measured and the peak strain values for WT mice were −22.% and −16.8% in the endocardial and epicardial layers, respectively. However, no significant difference in the layer-based values was noted for the MI mice. Regional analysis results revealed obvious myocardial strain variation in the apical anterior region in the MI mice. The experimental results demonstrate that the proposed dynamic cardiac strain imaging can be useful in high-performance imaging of small-animal cardiac diseases.
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ISSN:0885-3010
1525-8955
DOI:10.1109/TUFFC.2022.3148873