Optical Coherence Microscopy: A New Technique for High-Resolution, Non-Invasive Imaging in Bulk Biological Tissues

Optical coherence microscopy (OCM) is a novel technique complementary to optical coherence tomography (OCT) which combines low-coherence interferometry with confocal microscopy to achieve micron-scale resolution imaging in highly scattering media. OCM may be implemented using a single-mode fiber-optic low-coherence interferometer (See Fig. 1). A high numerical aperture objective is used to focus sample-arm light into the specimen, and the reference arm length of the interferometer is adjusted to match the sample arm focal plane optical depth. The sample arm of the interferometer comprises a scanning confocal microscope, in which either the sample or the probe beam is laterally scanned in a raster pattern, and the optical fiber acts as a single-mode confocal aperture for combined light illumination and collection. The reference arm length of the interferometer establishes the depth position of an interferometric “coherence gate” in the sample, from which backscattered light is preferentially collected. Initial studies of OCM in scattering phantoms have demonstrated that this technique provides increased optical sectioning depth compared to confocal microscopy alone.

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Measurement of the axial point spread function in scattering media using single-mode fiber-based optical coherence tomography

IEEE Journal of Selected Topics in Quantum Electronics ◽

10.1109/jstqe.2003.813299 ◽

2003 ◽

Vol 9 (2) ◽

pp. 227-233 ◽

Cited By ~ 89

Author(s):

T.G. van Leeuwen ◽

D.J. Faber ◽

M.C. Aalders

Keyword(s):

Optical Coherence Tomography ◽

Point Spread Function ◽

Single Mode ◽

Single Mode Fiber ◽

Optical Coherence ◽

Scattering Media ◽

Point Spread ◽

Spread Function

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1700 nm optical coherence microscopy enables minimally invasive, label-free, in vivo optical biopsy deep in the mouse brain

Light Science & Applications ◽

10.1038/s41377-021-00586-7 ◽

2021 ◽

Vol 10 (1) ◽

Author(s):

Jun Zhu ◽

Hercules Rezende Freitas ◽

Izumi Maezawa ◽

Lee-way Jin ◽

Vivek J. Srinivasan

Keyword(s):

Minimally Invasive ◽

Mouse Brain ◽

Numerical Aperture ◽

Optical Biopsy ◽

Optical Coherence ◽

Label Free ◽

Optical Coherence Microscopy ◽

Minimal Invasiveness ◽

Cortical Regions

AbstractIn vivo, minimally invasive microscopy in deep cortical and sub-cortical regions of the mouse brain has been challenging. To address this challenge, we present an in vivo high numerical aperture optical coherence microscopy (OCM) approach that fully utilizes the water absorption window around 1700 nm, where ballistic attenuation in the brain is minimized. Key issues, including detector noise, excess light source noise, chromatic dispersion, and the resolution-speckle tradeoff, are analyzed and optimized. Imaging through a thinned-skull preparation that preserves intracranial space, we present volumetric imaging of cytoarchitecture and myeloarchitecture across the entire depth of the mouse neocortex, and some sub-cortical regions. In an Alzheimer’s disease model, we report that findings in superficial and deep cortical layers diverge, highlighting the importance of deep optical biopsy. Compared to other microscopic techniques, our 1700 nm OCM approach achieves a unique combination of intrinsic contrast, minimal invasiveness, and high resolution for deep brain imaging.

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Численное моделирование миграции фотонов в однородных и неоднородных цилиндрических фантомах

Журнал технической физики ◽

10.21883/os.2020.06.49417.33-20 ◽

2020 ◽

Vol 128 (6) ◽

pp. 832

Author(s):

А.Ю. Потлов ◽

С.В. Фролов ◽

С.Г. Проскурин

Keyword(s):

Radiation Transfer ◽

Biological Tissues ◽

Photon Density ◽

Radiation Transfer Equation ◽

Scattering Media ◽

Soft Biological Tissues ◽

Photon Diffusion ◽

Low Coherence ◽

The Brain ◽

Pulsed Irradiation

The specific features of photon diffusion of low-coherence pulsed irradiation in phantoms of soft biological tissues (blood-saturated tissues of the brain, breast, etc.) are described. The results of photon migration simulation using the Diffusion Approximation to the Radiation Transfer Equation (RTE) are compared with ones of the Monte Carlo simulations. It has been confirmed that the Photon Density Normalized Maximum (PDNM) moves towards the center of the investigated object in case of relatively uniform and strongly scattering media. In the presence of inhomogeneities, type of the PDNM motion changes drastically. Presence of an absorbing inhomogeneity in the medium directs trajectory of the PDNM motion of towards the point symmetric to the inhomogeneity relative to the geometric center of the investigated object. In case of scattering the PDNM moves toward the direction of the center of the scattering inhomogeneity.

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Application of Fiber Point Diffraction in Measurement of Optical Surface

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.55-57.1200 ◽

2011 ◽

Vol 55-57 ◽

pp. 1200-1205

Author(s):

Liang Nie ◽

Jun Han ◽

Xu Jiang

Keyword(s):

High Performance ◽

Spherical Surface ◽

Spherical Wave ◽

Numerical Aperture ◽

Single Mode ◽

Single Mode Fiber ◽

Optical Surface ◽

Fiber System ◽

Core Diameter ◽

Fringe Contrast

The fiber point diffraction technology is applied in interferometer to measure optical surface with high precision. The wavefront diffracted from the single mode fiber with microns core diameter can be considered as ideal spherical wave and used as the referenced wave in interferometry. To estimate the quality of diffracted wavefront, the theoretical model of optical point diffraction is introduced at first. Based on the model, the influence of fiber core diameter, deformation and end-face shape on wavefront error is studied with numerical analysis. The analysis result shows that the single mode fiber used in experiment is available for instrument design and its influence over systematic error should be negligible within certain numerical aperture. Then a point diffraction interferometer with a single fiber is designed. Compared with the double fiber system, it has merit of noise immunity, high fringe contrast and high performance. Finally, the fiber point diffraction interferometer system is put up to measure spherical surface in experiment. The interference fringes are collected and analyzed with five-step shifting, least squares unwrapping and Zernike fitting method. The results show that the interferometer with optical fiber has achieved a worthy measurement precision and has great development potential.

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