Fourier optics analysis of phase-mask-based path-length-multiplexed optical coherence tomography

Yin, Biwei; Dwelle, Jordan; Wang, Bingqing; Wang, Tianyi; Feldman, Marc D.; Rylander, H. G.; Milner, Thomas E.

doi:10.1364/josaa.32.002169

Cited by 7 publications

(5 citation statements)

References 25 publications

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“…An integral component of the SAR-OCT system is a path length multiplexing element (PME), described in detail by Yin et al, 25 Wang et al, 11 and Gardner et al 13 The PME provides additional contrast to standard OCT images by separating sample path light into 3 different path lengths, each corresponding to a different angular range. Path length 1 ( L ; “Low”) is light that has scattered at generally low angles, whereas path lengths 2 ( H 2 ; “High 2”) and 3 ( H 3 ; “High 3”) contain light that has scattered at generally higher angles (Figure 2A).…”

Section: Methodsmentioning

confidence: 99%

Scattering-Angle-Resolved Optical Coherence Tomography of a Hypoxic Mouse Retina Model

et al. 2019

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Several studies have noted a correlation between retinal degeneration and traumatic encephalopathy (TE) making the retina a leading candidate for detection and assessment. Scattering-angle-resolved optical coherence tomography (SAR-OCT) is a candidate imaging modality to detect sub-resolution changes in retinal microstructure. SAR-OCT images of murine retinas that experience a hypoxic insult—euthanasia by isoflurane overdose—are presented. A total of 4 SAR-OCT measurement parameters are reported in 6 longitudinal experiments: blood flow volume fraction, total retinal thickness, reflectance index, and scattering angle. As each mouse expires, blood flow volume fraction decreases, total retinal thickness increases, reflectance index decreases, and scattering angle diversity increases. Contribution of the retinal vasculature to scattering angle diversity is discussed. Results of this study suggest the utility of SAR-OCT to measure TE using scattering angle diversity contrast in the retina.

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Section: Methodsmentioning

confidence: 99%

Scattering-Angle-Resolved Optical Coherence Tomography of a Hypoxic Mouse Retina Model

et al. 2019

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“…At each mode's focal plane, other modes present as a potential side-lobe or out-of-focus artifacts that could blur the in-focus mode. But since the SMF core spatially filters the backscattered light, off-axis scattering centers are strongly attenuated [20] and no significant side-lobe artifacts are observed as shown in Fig. 4 and Fig.…”

Section: Lateral Psf Artifactsmentioning

confidence: 97%

μOCT imaging using depth of focus extension by self-imaging wavefront division in a common-path fiber optic probe

et al. 2016

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Optical coherence tomography (OCT) is an attractive medical modality due to its ability to acquire high-resolution, cross-sectional images inside the body using flexible, small-diameter, scanning fiber optic probes. Conventional, cross-sectional OCT imaging technologies have approximately 10-μm axial resolution and 30-μm lateral resolution, specifications that enable the visualization of microscopic architectural morphology. While this resolution is useful for many clinical applications, it is insufficient for resolving individual cells that characterize many diseases. To address this gap, a supercontinuum-laser-based, μm-resolution OCT (μOCT) system and a 500 μm-diameter, extended depth of focus single fiber optic probe for endoscopic and intravascular imaging were designed and fabricated. At the distal tip of the fiber optic probe, a cylindrical waveguide was used to divide the wavefront to provide multiple circular propagation modes. Once transmitted through a relatively high NA lens (NA >0.1), these modes were projected as multiple coaxial foci (~3 μm full width at half maximum (FWHM)) over a greatly extended focal depth range. The distal tip of the probe also contained a common-path reference reflectance to minimize polarization and dispersion imbalances between sample and reference arm light. Measurements showed that the probe provides a 20-fold depth of focus extension, maintaining a 3-5 µm lateral resolution (FWHM of PSF) and a 2 μm axial resolution over a depth range of approximately 1 mm. These results suggest that this new optical configuration will be useful for achieving high-resolution, cross-sectional OCT imaging in catheter/endoscope-based medical imaging devices.

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“…Thus, each sub image in the OCT interferogram is separated vertically by 2.5 mm. A more rigorous Fourier optical analysis of the PME operation for imaging was previously published [33]. A Monte Carlo model was developed to determine the effect of PME center aperture size on the intensity of light in each pathlength.…”

Section: Pathlength Multiplexing Elementmentioning

confidence: 99%

Design Considerations for Murine Retinal Imaging Using Scattering Angle Resolved Optical Coherence Tomography

et al. 2018

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Optical coherence tomography (OCT), an optical imaging approach enabling cross-sectional analysis of turbid samples, is routinely used for retinal imaging in human and animal models of diseases affecting the retina. Scattering angle resolved (SAR-)OCT has previously been demonstrated as offering additional contrast in human studies, but no SAR-OCT system has been reported in detail for imaging the retinas of mice. An optical model of a mouse eye was designed and extended for validity at wavelengths of light around 1310 nm; this model was then utilized to develop a SAR-OCT design for murine retinal imaging. A Monte Carlo technique simulates light scattering from the retina, and the simulation results are confirmed with SAR-OCT images. Various images from the SAR-OCT system are presented and utility of the system is described. SAR-OCT is demonstrated as a viable and robust imaging platform to extend utility of retinal OCT imaging by incorporating scattering data into investigative ophthalmologic analysis.

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Fourier optics analysis of phase-mask-based path-length-multiplexed optical coherence tomography

Cited by 7 publications

References 25 publications

Scattering-Angle-Resolved Optical Coherence Tomography of a Hypoxic Mouse Retina Model

Scattering-Angle-Resolved Optical Coherence Tomography of a Hypoxic Mouse Retina Model

μOCT imaging using depth of focus extension by self-imaging wavefront division in a common-path fiber optic probe

Design Considerations for Murine Retinal Imaging Using Scattering Angle Resolved Optical Coherence Tomography

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