Quantitative spatial resolution enhancement of reflection matrix optical coherence tomography for deep-tissue imaging

Multiple scattering poses a fundamental limitation in deep imaging, especially for high-resolution optical imaging methods. The amalgamation of reflection matrix measurements and optical coherence tomography (OCT) has afforded significant advantages for deep imaging through highly scattering media....

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Published inJournal of applied physics Vol. 134; no. 7
Main Authors Cao, Jing, Fu, Ling, Wang, Pinghe, Liu, Qian
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 21.08.2023
Subjects
Applied physics
Coherent scattering
Image resolution
Medical imaging
Multiple scatter
Optical Coherence Tomography
Quantitative analysis
Resolution
Spatial resolution
Tomography
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Abstract Multiple scattering poses a fundamental limitation in deep imaging, especially for high-resolution optical imaging methods. The amalgamation of reflection matrix measurements and optical coherence tomography (OCT) has afforded significant advantages for deep imaging through highly scattering media. To empirically exhibit the superior performance of reflection matrix OCT (RMOCT), this study proposes a unique method to ascertain the actual resolutions at each imaging point. In contrast to conventional theoretical lateral resolutions, these resolutions are derived by applying time-reversal decomposition to the time-gated reflection matrix. Moreover, the concept of contribution rate, which quantifies the imaging contributions for each point, is introduced by considering the local imaging point itself and its neighboring points. The contribution rate provides a quantitative evaluation of the imaging quality afforded by a system. To the best of our knowledge, this study represents the comprehensive assessment of the practical performance of RMOCT in terms of actual resolving power and imaging quality.
AbstractList Multiple scattering poses a fundamental limitation in deep imaging, especially for high-resolution optical imaging methods. The amalgamation of reflection matrix measurements and optical coherence tomography (OCT) has afforded significant advantages for deep imaging through highly scattering media. To empirically exhibit the superior performance of reflection matrix OCT (RMOCT), this study proposes a unique method to ascertain the actual resolutions at each imaging point. In contrast to conventional theoretical lateral resolutions, these resolutions are derived by applying time-reversal decomposition to the time-gated reflection matrix. Moreover, the concept of contribution rate, which quantifies the imaging contributions for each point, is introduced by considering the local imaging point itself and its neighboring points. The contribution rate provides a quantitative evaluation of the imaging quality afforded by a system. To the best of our knowledge, this study represents the comprehensive assessment of the practical performance of RMOCT in terms of actual resolving power and imaging quality.
Author Liu, Qian
Fu, Ling
Wang, Pinghe
Cao, Jing
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Snippet Multiple scattering poses a fundamental limitation in deep imaging, especially for high-resolution optical imaging methods. The amalgamation of reflection...
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SubjectTerms Applied physics
Coherent scattering
Image resolution
Medical imaging
Multiple scatter
Optical Coherence Tomography
Quantitative analysis
Resolution
Spatial resolution
Tomography
Title Quantitative spatial resolution enhancement of reflection matrix optical coherence tomography for deep-tissue imaging
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