Literature DB >> 25554970

Shear wave elastography using amplitude-modulated acoustic radiation force and phase-sensitive optical coherence tomography.

Thu-Mai Nguyen1, Bastien Arnal1, Shaozhen Song2, Zhihong Huang3, Ruikang K Wang4, Matthew O'Donnell1.   

Abstract

Investigating the elasticity of ocular tissue (cornea and intraocular lens) could help the understanding and management of pathologies related to biomechanical deficiency. In previous studies, we introduced a setup based on optical coherence tomography for shear wave elastography (SWE) with high resolution and high sensitivity. SWE determines tissue stiffness from the propagation speed of shear waves launched within tissue. We proposed acoustic radiation force to remotely induce shear waves by focusing an ultrasound (US) beam in tissue, similar to several elastography techniques. Minimizing the maximum US pressure is essential in ophthalmology for safety reasons. For this purpose, we propose a pulse compression approach. It utilizes coded US emissions to generate shear waves where the energy is spread over a long emission, and then numerically compressed into a short, localized, and high-energy pulse. We used a 7.5-MHz single-element focused transducer driven by coded excitations where the amplitude is modulated by a linear frequency-swept square wave (1 to 7 kHz). An inverse filter approach was used for compression. We demonstrate the feasibility of performing shear wave elastography measurements in tissue-mimicking phantoms at low US pressures (mechanical index < 0.6)

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Year:  2015        PMID: 25554970      PMCID: PMC4282275          DOI: 10.1117/1.JBO.20.1.016001

Source DB:  PubMed          Journal:  J Biomed Opt        ISSN: 1083-3668            Impact factor:   3.170


  23 in total

1.  Shear wave elasticity imaging: a new ultrasonic technology of medical diagnostics.

Authors:  A P Sarvazyan; O V Rudenko; S D Swanson; J B Fowlkes; S Y Emelianov
Journal:  Ultrasound Med Biol       Date:  1998-11       Impact factor: 2.998

2.  Assessment of viscous and elastic properties of sub-wavelength layered soft tissues using shear wave spectroscopy: theoretical framework and in vitro experimental validation.

Authors:  Thu-Mai Nguyen; Mathieu Couade; Jeremy Bercoff; Mickael Tanter
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2011-11       Impact factor: 2.725

3.  Quantitative assessment of arterial wall biomechanical properties using shear wave imaging.

Authors:  Mathieu Couade; Mathieu Pernot; Claire Prada; Emmanuel Messas; Joseph Emmerich; Patrick Bruneval; Aline Criton; Mathias Fink; Mickael Tanter
Journal:  Ultrasound Med Biol       Date:  2010-10       Impact factor: 2.998

4.  Coded excitation system for improving the penetration of real-time phased-array imaging systems.

Authors:  M O'Donnell
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  1992       Impact factor: 2.725

5.  The variance of quantitative estimates in shear wave imaging: theory and experiments.

Authors:  Thomas Deffieux; Jean-Luc Gennisson; Benoit Larrat; Mathias Fink; Mickael Tanter
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2012-11       Impact factor: 2.725

6.  Visualizing ultrasonically induced shear wave propagation using phase-sensitive optical coherence tomography for dynamic elastography.

Authors:  Thu-Mai Nguyen; Shaozhen Song; Bastien Arnal; Zhihong Huang; Matthew O'Donnell; Ruikang K Wang
Journal:  Opt Lett       Date:  2014-02-15       Impact factor: 3.776

7.  Shear wave imaging optical coherence tomography (SWI-OCT) for ocular tissue biomechanics.

Authors:  Shang Wang; Kirill V Larin
Journal:  Opt Lett       Date:  2014-01-01       Impact factor: 3.776

8.  Quantitative assessment of breast lesion viscoelasticity: initial clinical results using supersonic shear imaging.

Authors:  Mickael Tanter; Jeremy Bercoff; Alexandra Athanasiou; Thomas Deffieux; Jean-Luc Gennisson; Gabriel Montaldo; Marie Muller; Anne Tardivon; Mathias Fink
Journal:  Ultrasound Med Biol       Date:  2008-04-08       Impact factor: 2.998

9.  In vivo three-dimensional optical coherence elastography.

Authors:  Brendan F Kennedy; Xing Liang; Steven G Adie; Derek K Gerstmann; Bryden C Quirk; Stephen A Boppart; David D Sampson
Journal:  Opt Express       Date:  2011-03-28       Impact factor: 3.894

10.  Dynamic spectral-domain optical coherence elastography for tissue characterization.

Authors:  Xing Liang; Steven G Adie; Renu John; Stephen A Boppart
Journal:  Opt Express       Date:  2010-06-21       Impact factor: 3.894
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  25 in total

1.  Dual shear wave induced laser speckle contrast signal and the improvement in shear wave speed measurement.

Authors:  Sinan Li; Yi Cheng; Robert J Eckersley; Daniel S Elson; Meng-Xing Tang
Journal:  Biomed Opt Express       Date:  2015-05-05       Impact factor: 3.732

Review 2.  Optical coherence elastography - OCT at work in tissue biomechanics [Invited].

Authors:  Kirill V Larin; David D Sampson
Journal:  Biomed Opt Express       Date:  2017-01-27       Impact factor: 3.732

3.  Integrated optical coherence tomography and multielement ultrasound transducer probe for shear wave elasticity imaging of moving tissues.

Authors:  Andrei B Karpiouk; Donald J VanderLaan; Kirill V Larin; Stanislav Y Emelianov
Journal:  J Biomed Opt       Date:  2018-10       Impact factor: 3.170

4.  Quantifying tissue viscoelasticity using optical coherence elastography and the Rayleigh wave model.

Authors:  Zhaolong Han; Manmohan Singh; Salavat R Aglyamov; Chih-Hao Liu; Achuth Nair; Raksha Raghunathan; Chen Wu; Jiasong Li; Kirill V Larin
Journal:  J Biomed Opt       Date:  2016-09-01       Impact factor: 3.170

5.  In Vivo Elasticity Mapping of Posterior Ocular Layers Using Acoustic Radiation Force Optical Coherence Elastography.

Authors:  Yueqiao Qu; Youmin He; Arya Saidi; Yihang Xin; Yongxiao Zhou; Jiang Zhu; Teng Ma; Ronald H Silverman; Don S Minckler; Qifa Zhou; Zhongping Chen
Journal:  Invest Ophthalmol Vis Sci       Date:  2018-01-01       Impact factor: 4.799

6.  Four-dimensional (4D) phase velocity optical coherence elastography in heterogeneous materials and biological tissue.

Authors:  Hsiao-Chuan Liu; Piotr Kijanka; Matthew W Urban
Journal:  Biomed Opt Express       Date:  2020-06-18       Impact factor: 3.732

7.  Acoustic radiation force optical coherence elastography for elasticity assessment of soft tissues.

Authors:  Jiang Zhu; Xingdao He; Zhongping Chen
Journal:  Appl Spectrosc Rev       Date:  2018-06-25       Impact factor: 5.917

8.  Spatial localization of mechanical excitation affects spatial resolution, contrast, and contrast-to-noise ratio in acoustic radiation force optical coherence elastography.

Authors:  Nichaluk Leartprapun; Rishyashring R Iyer; Colin D Mackey; Steven G Adie
Journal:  Biomed Opt Express       Date:  2019-10-24       Impact factor: 3.732

9.  In vivo evaluation of posterior eye elasticity using shaker-based optical coherence elastography.

Authors:  Xuejun Qian; Runze Li; Yan Li; Gengxi Lu; Youmin He; Mark S Humayun; Zhongping Chen; Qifa Zhou
Journal:  Exp Biol Med (Maywood)       Date:  2020-01-07

10.  Polarization-sensitive optical coherence elastography.

Authors:  Arata Miyazawa; Shuichi Makita; En Li; Kohei Yamazaki; Masaki Kobayashi; Shingo Sakai; Yoshiaki Yasuno
Journal:  Biomed Opt Express       Date:  2019-09-16       Impact factor: 3.732
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