Lorentz force optical coherence elastography

Chen Wu; Manmohan Singh; Zhaolong Han; Raksha Raghunathan; Chih Hao Liu; Jiasong Li; Alexander Schill; Kirill V. Larin

doi:10.1117/1.JBO.21.9.090502

Lorentz force optical coherence elastography

Chen Wu, Manmohan Singh, Zhaolong Han, Raksha Raghunathan, Chih Hao Liu, Jiasong Li, Alexander Schill, Kirill V. Larin

Houston Methodist

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Quantifying tissue biomechanical properties can assist in detection of abnormalities and monitoring disease progression and/or response to a therapy. Optical coherence elastography (OCE) has emerged as a promising technique for noninvasively characterizing tissue biomechanical properties. Several mechanical loading techniques have been proposed to induce static or transient deformations in tissues, but each has its own areas of applications and limitations. This study demonstrates the combination of Lorentz force excitation and phase-sensitive OCE at ∼1.5 million A-lines per second to quantify the elasticity of tissue by directly imaging Lorentz force-induced elastic waves. This method of tissue excitation opens the possibility of a wide range of investigations using tissue biocurrents and conductivity for biomechanical analysis.

Original language	English (US)
Article number	090502
Journal	Journal of Biomedical Optics
Volume	21
Issue number	9
DOIs	https://doi.org/10.1117/1.JBO.21.9.090502
State	Published - Sep 1 2016

Keywords

biocurrent
elasticity
Lorentz force
optical coherence elastography
tissue

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Biomaterials
Atomic and Molecular Physics, and Optics
Biomedical Engineering

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10.1117/1.JBO.21.9.090502

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title = "Lorentz force optical coherence elastography",

abstract = "Quantifying tissue biomechanical properties can assist in detection of abnormalities and monitoring disease progression and/or response to a therapy. Optical coherence elastography (OCE) has emerged as a promising technique for noninvasively characterizing tissue biomechanical properties. Several mechanical loading techniques have been proposed to induce static or transient deformations in tissues, but each has its own areas of applications and limitations. This study demonstrates the combination of Lorentz force excitation and phase-sensitive OCE at ∼1.5 million A-lines per second to quantify the elasticity of tissue by directly imaging Lorentz force-induced elastic waves. This method of tissue excitation opens the possibility of a wide range of investigations using tissue biocurrents and conductivity for biomechanical analysis.",

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AU - Wu, Chen

AU - Singh, Manmohan

AU - Han, Zhaolong

AU - Raghunathan, Raksha

AU - Liu, Chih Hao

AU - Li, Jiasong

AU - Schill, Alexander

AU - Larin, Kirill V.

PY - 2016/9/1

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N2 - Quantifying tissue biomechanical properties can assist in detection of abnormalities and monitoring disease progression and/or response to a therapy. Optical coherence elastography (OCE) has emerged as a promising technique for noninvasively characterizing tissue biomechanical properties. Several mechanical loading techniques have been proposed to induce static or transient deformations in tissues, but each has its own areas of applications and limitations. This study demonstrates the combination of Lorentz force excitation and phase-sensitive OCE at ∼1.5 million A-lines per second to quantify the elasticity of tissue by directly imaging Lorentz force-induced elastic waves. This method of tissue excitation opens the possibility of a wide range of investigations using tissue biocurrents and conductivity for biomechanical analysis.

AB - Quantifying tissue biomechanical properties can assist in detection of abnormalities and monitoring disease progression and/or response to a therapy. Optical coherence elastography (OCE) has emerged as a promising technique for noninvasively characterizing tissue biomechanical properties. Several mechanical loading techniques have been proposed to induce static or transient deformations in tissues, but each has its own areas of applications and limitations. This study demonstrates the combination of Lorentz force excitation and phase-sensitive OCE at ∼1.5 million A-lines per second to quantify the elasticity of tissue by directly imaging Lorentz force-induced elastic waves. This method of tissue excitation opens the possibility of a wide range of investigations using tissue biocurrents and conductivity for biomechanical analysis.

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KW - Lorentz force

KW - optical coherence elastography

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Lorentz force optical coherence elastography

Abstract

Keywords

ASJC Scopus subject areas

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