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Proceedings Paper

Quantitative shear wave imaging optical coherence tomography for noncontact mechanical characterization of myocardium
Author(s): Shang Wang; Andrew L. Lopez; Yuka Morikawa; Ge Tao; Jiasong Li; Irina V. Larina; James F. Martin; Kirill V. Larin
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Paper Abstract

Optical coherence elastography (OCE) is an emerging low-coherence imaging technique that provides noninvasive assessment of tissue biomechanics with high spatial resolution. Among various OCE methods, the capability of quantitative measurement of tissue elasticity is of great importance for tissue characterization and pathology detection across different samples. Here we report a quantitative OCE technique, termed quantitative shear wave imaging optical coherence tomography (Q-SWI-OCT), which enables noncontact measurement of tissue Young’s modulus based on the ultra-fast imaging of the shear wave propagation inside the sample. A focused air-puff device is used to interrogate the tissue with a low-pressure short-duration air stream that stimulates a localized displacement with the scale at micron level. The propagation of this tissue deformation in the form of shear wave is captured by a phase-sensitive OCT system running with the scan of the M-mode imaging over the path of the wave propagation. The temporal characteristics of the shear wave is quantified based on the cross-correlation of the tissue deformation profiles at all the measurement locations, and linear regression is utilized to fit the data plotted in the domain of time delay versus wave propagation distance. The wave group velocity is thus calculated, which results in the quantitative measurement of the Young’s modulus. As the feasibility demonstration, experiments are performed on tissuemimicking phantoms with different agar concentrations and the quantified elasticity values with Q-SWI-OCT agree well with the uniaxial compression tests. For functional characterization of myocardium with this OCE technique, we perform our pilot experiments on ex vivo mouse cardiac muscle tissues with two studies, including 1) elasticity difference of cardiac muscle under relaxation and contract conditions and 2) mechanical heterogeneity of the heart introduced by the muscle fiber orientation. Our results suggest the potential of using Q-SWI-OCT as an essential tool for nondestructive biomechanical evaluation of myocardium.

Paper Details

Date Published: 6 March 2015
PDF: 7 pages
Proc. SPIE 9327, Optical Elastography and Tissue Biomechanics II, 93270F (6 March 2015); doi: 10.1117/12.2078376
Show Author Affiliations
Shang Wang, Baylor College of Medicine (United States)
Univ. of Houston (United States)
Andrew L. Lopez, Baylor College of Medicine (United States)
Yuka Morikawa, Baylor College of Medicine (United States)
Ge Tao, Baylor College of Medicine (United States)
Jiasong Li, Univ. of Houston (United States)
Irina V. Larina, Baylor College of Medicine (United States)
James F. Martin, Baylor College of Medicine (United States)
Texas Heart Institute (United States)
Kirill V. Larin, Baylor College of Medicine (United States)
Univ. of Houston (United States)


Published in SPIE Proceedings Vol. 9327:
Optical Elastography and Tissue Biomechanics II
Kirill V. Larin; David D. Sampson, Editor(s)

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