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A Miniature Dual-Fiber Probe for Quantitative Optical Coherence Elastography
Publikationstyp
Journal Article
Publikationsdatum
2023-11
Sprache
English
Author
Enthalten in
Volume
70
Issue
11
Start Page
3064
End Page
3072
Citation
IEEE Transactions on Biomedical Engineering 70 (11): 3064-3072 (2023-11)
Publisher DOI
Scopus ID
Optical coherence elastography (OCE) allows for high resolution analysis of elastic tissue properties. However, due to the limited penetration of light into tissue, miniature probes are required to reach structures inside the body, e.g., vessel walls. Shear wave elastography relates shear wave velocities to quantitative estimates of elasticity. Generally, this is achieved by measuring the runtime of waves between two or multiple points. For miniature probes, optical fibers have been integrated and the runtime between the point of excitation and a single measurement point has been considered. This approach requires precise temporal synchronization and spatial calibration between excitation and imaging. We present a miniaturized dual-fiber OCE probe of diameter allowing for robust shear wave elastography. Shear wave velocity is estimated between two optics and hence independent of wave propagation between excitation and imaging. We quantify the wave propagation by evaluating either a single or two measurement points. Particularly, we compare both approaches to ultrasound elastography. Our experimental results demonstrate that quantification of local tissue elasticities is feasible. For homogeneous soft tissue phantoms, we obtain mean deviations of and for single-fiber and dual-fiber OCE, respectively. In inhomogeneous phantoms, we measure mean deviations of up to and for single-fiber and dual-fiber OCE, respectively. We present a dual-fiber OCE approach that is much more robust in inhomogeneous tissues. Moreover, we demonstrate the feasibility of elasticity quantification in ex-vivo coronary arteries. This study introduces an approach for robust elasticity quantification from within the tissue.
Schlagworte
Elasticity
Elastography
Imaging
Miniaturized Imaging Probes
Optical Coherence Elastography
Optical fibers
Optics
Probes
Propagation
Shear Wave Elastography
Vascular Elasticity
DDC Class
610: Medicine, Health