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174 results on '"Moult, Eric M."'

1. Retinal blood flow speed quantification at the capillary level using temporal autocorrelation fitting OCTA

Author

Hwang, Yunchan, Won, Jungeun, Yaghy, Antonio, Takahashi, Hiroyuki, Girgis, Jessica M., Lam, Kenneth, Chen, Siyu, Moult, Eric M., Ploner, Stefan B., Maier, Andreas, Waheed, Nadia K., and Fujimoto, James G.

Subjects
Electrical Engineering and Systems Science - Image and Video Processing
Abstract

Optical coherence tomography angiography (OCTA) can visualize vasculature structures, but provides limited information about the blood flow speeds. Here, we present a second generation variable interscan time analysis (VISTA) OCTA, which evaluates a quantitative surrogate marker for blood flow speed in vasculature. At the capillary level, spatially compiled OCTA and a simple temporal autocorrelation model, {\rho}({\tau}) = exp(-{\alpha}{\tau}), were used to evaluate a temporal autocorrelation decay constant, {\alpha}, as the blood flow speed marker. A 600 kHz A-scan rate swept-source provides short interscan time OCTA and fine A-scan spacing acquisition, while maintaining multi mm2 field of views for human retinal imaging. We demonstrate the cardiac pulsatility and repeatability of {\alpha} measured with VISTA. We show different {\alpha} for different retinal capillary plexuses in healthy eyes and present representative VISTA OCTA of eyes with diabetic retinopathy.

Published
2023

3. Efficient and high accuracy 3-D OCT angiography motion correction in pathology

Author

Ploner, Stefan B., Kraus, Martin F., Moult, Eric M., Husvogt, Lennart, Schottenhamml, Julia, Alibhai, A. Yasin, Waheed, Nadia K., Duker, Jay S., Fujimoto, James G., and Maier, Andreas K.

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, I.4.3
Abstract

We propose a novel method for non-rigid 3-D motion correction of orthogonally raster-scanned optical coherence tomography angiography volumes. This is the first approach that aligns predominantly axial structural features like retinal layers and transverse angiographic vascular features in a joint optimization. Combined with the use of orthogonal scans and favorization of kinematically more plausible displacements, the approach allows subpixel alignment and micrometer-scale distortion correction in all 3 dimensions. As no specific structures or layers are segmented, the approach is by design robust to pathologic changes. It is furthermore designed for highly parallel implementation and brief runtime, allowing its integration in clinical routine even for high density or wide-field scans. We evaluated the algorithm with metrics related to clinically relevant features in a large-scale quantitative evaluation based on 204 volumetric scans of 17 subjects including both a wide range of pathologies and healthy controls. Using this method, we achieve state-of-the-art axial performance and show significant advances in both transverse co-alignment and distortion correction, especially in the pathologic subgroup., Comment: 22 pages, 11 figures, 4 tables

Published
2020
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5. Geometric Perfusion Deficits: A Novel OCT Angiography Biomarker for Diabetic Retinopathy Based on Oxygen Diffusion.

Author

Chen, Siyu, Moult, Eric M, Zangwill, Linda M, Weinreb, Robert N, and Fujimoto, James G

Subjects
Capillaries, Retinal Vessels, Fundus Oculi, Humans, Diabetic Retinopathy, Oxygen, Tomography, Optical Coherence, Fluorescein Angiography, Retrospective Studies, Cross-Sectional Studies, Pilot Projects, Reproducibility of Results, Regional Blood Flow, Adult, Aged, Middle Aged, Female, Male, Tomography, Optical Coherence, Ophthalmology & Optometry, Clinical Sciences, Opthalmology and Optometry, Public Health and Health Services
Abstract

PurposeTo develop geometric perfusion deficits (GPD), an optical coherence tomography angiography (OCTA) biomarker based on oxygen diffusion, and to evaluate its utility in a pilot study of healthy subjects and patients with diabetic retinopathy (DR).DesignRetrospective cross-sectional study.MethodsCommercial spectral-domain optical coherence tomography angiography (OCTA) instruments were used to acquire repeated 3 × 3-mm2 and 6 × 6-mm2 motion-corrected macular OCTA volumes. En face OCTA images corresponding to the superficial capillary plexus (SCP), deep capillary plexus (DCP), and full retinal projections were obtained using automatic segmentation. For each projection, the GPD percentage and the vessel density percentage, the control metric, were computed, and their values were compared between the normal and DR eyes. The repeated OCTA acquisitions were used to assess the test-retest repeatability of the GPD and vessel density percentages.ResultsRepeated OCTA scans of 15 normal eyes and 12 DR eyes were obtained. For all en face projections, GPD percentages were significantly higher in DR eyes than in normal eyes; vessel density percentages were significantly lower in all but 1 projection (DCP). Large GPD areas were used to identify focal perfusion deficits. Test-retest analysis showed that the GPD percentage had superior repeatability than the vessel density percentage in most cases. A strong negative correlation between the GPD percentage and the vessel density percentage was also found.ConclusionsGeometric perfusion deficits, an OCTA biomarker based on oxygen diffusion, provides a quantitative metric of macular microvascular remodeling with a strong physiological underpinning. The GPD percentage may serve as a useful biomarker for detecting and monitoring DR.

Published
2021

17. Analyzing Relative Blood Flow Speeds in Choroidal Neovascularization Using Variable Interscan Time Analysis OCT Angiography

Author

Rebhun, Carl B., Moult, Eric M., Ploner, Stefan B., Neto, Carlos Moreira, Alibhai, A. Yasin, Schottenhamml, Julia, Lee, Byungkun, Choi, WooJhon, Rifai, Fareed A., Tam, Mary W., Husvogt, Lennart, Baumal, Caroline R., Witkin, Andre J., Maier, Andreas, Rosenfeld, Philip J., Duker, Jay S., Fujimoto, James G., and Waheed, Nadia K.

Published
2018
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22. Onset and Progression of Persistent Choroidal Hypertransmission Defects in Intermediate AMD: A Novel Clinical Trial Endpoint

Author

Liu, Jeremy, primary, Shen, Mengxi, additional, Laiginhas, Rita, additional, Herrera, Gissel, additional, Li, Jianqing, additional, Shi, Yingying, additional, Hiya, Farhan, additional, Trivizki, Omer, additional, Waheed, Nadia K., additional, Chung, Carol Y., additional, Moult, Eric M., additional, Fujimoto, James G., additional, Gregori, Giovanni, additional, and Rosenfeld, Philip J., additional

Published
2023
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23. Multiscale correlation of microvascular changes on optical coherence tomography angiography with retinal sensitivity in diabetic retinopathy

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Levine, Emily S, Moult, Eric M, Greig, Eugenia Custo, Zhao, Yi, Pramil, Varsha, Gendelman, Isaac, Alibhai, Agha Y, Baumal, Caroline R, Witkin, Andre J, Duker, Jay S, Fujimoto, James G, Waheed, Nadia K, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Levine, Emily S, Moult, Eric M, Greig, Eugenia Custo, Zhao, Yi, Pramil, Varsha, Gendelman, Isaac, Alibhai, Agha Y, Baumal, Caroline R, Witkin, Andre J, Duker, Jay S, Fujimoto, James G, and Waheed, Nadia K

Abstract

PURPOSE: To assess global, zonal, and local correlations between vessel density changes measured by optical coherence tomography angiography and retinal sensitivity measured by microperimetry across diabetic retinopathy severity. METHODS: Diabetic patients and nondiabetic controls underwent optical coherence tomography angiography imaging and microperimetry testing. Pearson's correlation was used to assess associations between average sensitivity and skeletonized vessel density (SVD) or foveal avascular zone area centrally. Linear mixed effects modeling was used to assess relationships between local SVD measurements and their spatially corresponding retinal sensitivity measurements. RESULTS: Thirty-nine eyes from 39 participants were imaged. In all slabs, there was a statistically significant positive correlation between retinal sensitivities and SVDs on both global and zonal scales. No statistically significant correlation was found between central retinal sensitivities and the foveal avascular zone areas. Assessment of 1,136 spatially paired retinal sensitivity and SVD measurements revealed a statistically significant local relationship; this seemed to be driven by eyes with proliferative diabetic retinopathy that had reduced retinal sensitivities. CONCLUSION: This study supports positive correlations between SVD and retinal sensitivity at global and zonal spatial scales in diabetic eyes. However, our analysis did not find evidence of statistically significant correlations between retinal sensitivity and SVD on a local scale until advanced diabetic retinopathy.

Published
2023

25. Abstract: OCT-OCTA Segmentation

Author

Schottenhamml, Julia, primary, Moult, Eric M., additional, Novais, Eduardo A., additional, Kraus, Martin F., additional, Lee, ByungKun, additional, Choi, WooJhon, additional, Ploner, Stefan B., additional, Husvogt, Lennart, additional, Lu, Chen D., additional, Yiu, Patrick, additional, Rosenfeld, Philip J., additional, Duker, Jay S., additional, Maier, Andreas K., additional, Waheed, Nadia, additional, and Fujimoto, James G., additional

Published
2018
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27. Optical Coherence Tomography Angiography Analysis Toolbox: A Repeatable and Reproducible Software Tool for Quantitative Optical Coherence Tomography Angiography Analysis

Author

Girgis, Jessica M., primary, Saukkonen, Daniel, additional, Hüther, Alexander, additional, Alibhai, A. Yasin, additional, Moult, Eric M., additional, Abu-Qamar, Omar, additional, Fujimoto, James G., additional, Baumal, Caroline R., additional, Witkin, Andre J., additional, Duker, Jay S., additional, and Waheed, Nadia K., additional

Published
2023
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28. Abstract: OCT-OCTA Segmentation : A Novel Framework and an Application to Segment Bruch’s Membrane in the Presence of Drusen

Author

Schottenhamml, Julia, Moult, Eric M., Novais, Eduardo A., Kraus, Martin F., Lee, ByungKun, Choi, WooJhon, Ploner, Stefan B., Husvogt, Lennart, Lu, Chen D., Yiu, Patrick, Rosenfeld, Philip J., Duker, Jay S., Maier, Andreas K., Waheed, Nadia, Fujimoto, James G., Maier, Andreas, editor, Deserno, Thomas M., editor, Handels, Heinz, editor, Maier-Hein, Klaus Hermann, editor, Palm, Christoph, editor, and Tolxdorff, Thomas, editor

Published
2018
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29. High speed, long range, deep penetration swept source OCT for structural and angiographic imaging of the anterior eye

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Harvard University--MIT Division of Health Sciences and Technology, Chen, Siyu, Potsaid, Benjamin, Li, Yan, Lin, Junhong, Hwang, Yunchan, Moult, Eric M, Zhang, Jason, Huang, David, Fujimoto, James G, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Harvard University--MIT Division of Health Sciences and Technology, Chen, Siyu, Potsaid, Benjamin, Li, Yan, Lin, Junhong, Hwang, Yunchan, Moult, Eric M, Zhang, Jason, Huang, David, and Fujimoto, James G

Abstract

AbstractThis study reports the development of prototype swept-source optical coherence tomography (SS-OCT) technology for imaging the anterior eye. Advances in vertical-cavity surface-emitting laser (VCSEL) light sources, signal processing, optics and mechanical designs, enable a unique combination of high speed, long range, and deep penetration that addresses the challenges of anterior eye imaging. We demonstrate SS-OCT with a 325 kHz A-scan rate, 12.2 µm axial resolution (in air), and 15.5 mm depth range (in air) at 1310 nm wavelength. The ultrahigh 325 kHz A-scan rate not only facilitates biometry measurements by minimizing acquisition time and thus reducing motion, but also enables volumetric OCT for comprehensive structural analysis and OCT angiography (OCTA) for visualizing vasculature. The 15.5 mm (~ 11.6 mm in tissue) depth range spans all optical surfaces from the anterior cornea to the posterior lens capsule. The 1310 nm wavelength range enables structural OCT and OCTA deep in the sclera and through the iris. Achieving high speed and long range requires linearizing the VCSEL wavenumber sweep to efficiently utilize analog-to-digital conversion bandwidth. Dual channel recording of the OCT and calibration interferometer fringe signals, as well as sweep to sweep wavenumber compensation, is used to achieve invariant 12.2 µm (~ 9.1 µm in tissue) axial resolution and optimum point spread function throughout the depth range. Dynamic focusing using a tunable liquid lens extends the effective depth of field while preserving the lateral resolution. Improved optical and mechanical design, including parallax “split view” iris cameras and stable, ergonomic patient interface, facilitates accurate instrument positioning, reduces patient motion, and leads to improved imaging data yield and measurement accuracy. We present structural and angiographic OCT images of the anterior eye, demonstrating the unique imaging capabilities using represen

Published
2022

30. OCT-OCTA segmentation: combining structural and blood flow information to segment Bruch’s membrane

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Schottenhamml, Julia, Moult, Eric M, Ploner, Stefan B, Chen, Siyu, Novais, Eduardo, Husvogt, Lennart, Duker, Jay S, Waheed, Nadia K, Fujimoto, James G, Maier, Andreas K, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Schottenhamml, Julia, Moult, Eric M, Ploner, Stefan B, Chen, Siyu, Novais, Eduardo, Husvogt, Lennart, Duker, Jay S, Waheed, Nadia K, Fujimoto, James G, and Maier, Andreas K

Abstract

© 2020 Optical Society of America under the terms of the OSA Open Access Publishing Agreement In this paper we present a fully automated graph-based segmentation algorithm that jointly uses optical coherence tomography (OCT) and OCT angiography (OCTA) data to segment Bruch's membrane (BM). This is especially valuable in cases where the spatial correlation between BM, which is usually not visible on OCT scans, and the retinal pigment epithelium (RPE), which is often used as a surrogate for segmenting BM, is distorted by pathology. We validated the performance of our proposed algorithm against manual segmentation in a total of 18 eyes from healthy controls and patients with diabetic retinopathy (DR), non-exudative age-related macular degeneration (AMD) (early/intermediate AMD, nascent geographic atrophy (nGA) and drusen-associated geographic atrophy (DAGA) and geographic atrophy (GA)), and choroidal neovascularization (CNV) with a mean absolute error of ∼0.91 pixel (∼4.1 µm). This paper suggests that OCT-OCTA segmentation may be a useful framework to complement the growing usage of OCTA in ophthalmic research and clinical communities.

Published
2022

31. Efficient and high accuracy 3-D OCT angiography motion correction in pathology

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Ploner, Stefan B, Kraus, Martin F, Moult, Eric M, Husvogt, Lennart, Schottenhamml, Julia, Yasin Alibhai, A, Waheed, Nadia K, Duker, Jay S, Fujimoto, James G, Maier, Andreas K, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Ploner, Stefan B, Kraus, Martin F, Moult, Eric M, Husvogt, Lennart, Schottenhamml, Julia, Yasin Alibhai, A, Waheed, Nadia K, Duker, Jay S, Fujimoto, James G, and Maier, Andreas K

Abstract

© 2020 Optical Society of America under the terms of the OSA Open Access Publishing Agreement We describe a novel method for non-rigid 3-D motion correction of orthogonally raster-scanned optical coherence tomography angiography volumes. This is the first approach that aligns predominantly axial structural features such as retinal layers as well as transverse angiographic vascular features in a joint optimization. Combined with orthogonal scanning and favorization of kinematically more plausible displacements, subpixel alignment and micrometer-scale distortion correction is achieved in all 3 dimensions. As no specific structures are segmented, the method is by design robust to pathologic changes. Furthermore, the method is designed for highly parallel implementation and short runtime, allowing its integration into clinical workflow even for high density or wide-field scans. We evaluated the algorithm with metrics related to clinically relevant features in an extensive quantitative evaluation based on 204 volumetric scans of 17 subjects, including patients with diverse pathologies and healthy controls. Using this method, we achieve state-of-the-art axial motion correction and show significant advances in both transverse co-alignment and distortion correction, especially in the subgroup with pathology.

Published
2022

32. Growth Modeling for Quantitative, Spatially Resolved Geographic Atrophy Lesion Kinetics

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Harvard University--MIT Division of Health Sciences and Technology, Moult, Eric M, Hwang, Yunchan, Shi, Yingying, Wang, Liang, Chen, Siyu, Waheed, Nadia K, Gregori, Giovanni, Rosenfeld, Philip J, Fujimoto, James G, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Harvard University--MIT Division of Health Sciences and Technology, Moult, Eric M, Hwang, Yunchan, Shi, Yingying, Wang, Liang, Chen, Siyu, Waheed, Nadia K, Gregori, Giovanni, Rosenfeld, Philip J, and Fujimoto, James G

Abstract

Purpose: To demonstrate the applicability of a growth modeling framework for quantifying spatial variations in geographic atrophy (GA) lesion kinetics. Methods: Thirty-eight eyes from 27 patients with GA secondary to age-related macular degeneration were imaged with a commercial swept source optical coherence tomography instrument at two visits separated by 1 year. Local GA growth rates were computed at 6-µm intervals along each lesion margin using a previously described growth model. Corresponding margin eccentricities, margin angles, and growth angles were also computed. The average GA growth rates conditioned on margin eccentricity, margin angle, growth angle, and fundus position were estimated via kernel regression. Results: A total of 88,356 GA margin points were analyzed. The average GA growth rates exhibited a hill-shaped dependency on eccentricity, being highest in the 0.5 mm to 1.6 mm range and lower on either side of that range. Average growth rates were also found to be higher for growth trajectories oriented away from (smaller growth angle), rather than toward (larger growth angle), the foveal center. The dependency of average growth rate on margin angle was less pronounced, although lesion segments in the superior and nasal aspects tended to grow faster. Conclusions: Our proposed growth modeling framework seems to be well-suited for generating accurate, spatially resolved GA growth rate atlases and should be confirmed on larger datasets. Translational Relevance: Our proposed growth modeling framework may enable more accurate measurements of spatial variations in GA growth rates.

Published
2022

38. Multiscale correlation of microvascular changes on optical coherence tomography angiography with retinal sensitivity in diabetic retinopathy

Author

Levine, Emily S., primary, Moult, Eric M., additional, Greig, Eugenia Custo, additional, Zhao, Yi, additional, Pramil, Varsha, additional, Gendelman, Isaac, additional, Alibhai, A. Yasin, additional, Baumal, Caroline R., additional, Witkin, Andre J., additional, Duker, Jay S., additional, Fujimoto, James G., additional, and Waheed, Nadia K., additional

Published
2021
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39. Mean macular intercapillary area in eyes with diabetic macular oedema after anti‐vascular endothelial growth factor therapy and its association with treatment response

Author

Sorour, Osama A., primary, Elsheikh, Mohamed, additional, Chen, Siyu, additional, Elnahry, Ayman G., additional, Baumal, Caroline R., additional, Pramil, Varsha, additional, Abdelhalim, Tamer I., additional, Nassar, Elsayed, additional, Moult, Eric M., additional, Witkin, Andre J., additional, Duker, Jay S., additional, and Waheed, Nadia K., additional

Published
2021
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40. Analysis of correlations between local geographic atrophy growth rates and local OCT angiography-measured choriocapillaris flow deficits

Author

Moult, Eric M., primary, Shi, Yingying, additional, Zhang, Qinqin, additional, Wang, Liang, additional, Mazumder, Rahul, additional, Chen, Siyu, additional, Chu, Zhongdi, additional, Feuer, William, additional, Waheed, Nadia K., additional, Gregori, Giovanni, additional, Wang, Ruikang K., additional, Rosenfeld, Philip J., additional, and Fujimoto, James G., additional

Published
2021
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42. SPATIAL DISTRIBUTION OF CHORIOCAPILLARIS IMPAIRMENT IN EYES WITH CHOROIDAL NEOVASCULARIZATION SECONDARY TO AGE-RELATED MACULAR DEGENERATION: A Quantitative OCT Angiography Study

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Moult, Eric M, Alibhai, Agha Yasin, Rebhun, Carl, Lee, ByungKun, Ploner, Stefan, Schottenhamml, Julia, Husvogt, Lennart, Baumal, Caroline R, Witkin, Andre J, Maier, Andreas, Duker, Jay S, Rosenfeld, Phillip J, Waheed, Nadia K, Fujimoto, James G, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Moult, Eric M, Alibhai, Agha Yasin, Rebhun, Carl, Lee, ByungKun, Ploner, Stefan, Schottenhamml, Julia, Husvogt, Lennart, Baumal, Caroline R, Witkin, Andre J, Maier, Andreas, Duker, Jay S, Rosenfeld, Phillip J, Waheed, Nadia K, and Fujimoto, James G

Abstract

PURPOSE: To develop an optical coherence tomography angiography (OCTA)-based framework for quantitatively analyzing the spatial distribution of choriocapillaris (CC) impairment around choroidal neovascularization (CNV) secondary to age-related macular degeneration. METHODS: In a retrospective, cross-sectional study, 400-kHz swept-source OCTA images from 7 eyes of 6 patients with CNV secondary to age-related macular degeneration were quantitatively analyzed using custom software. A lesion-centered zonal OCTA analysis technique-which portioned the field-of-view into zones relative to CNV boundaries-was developed to quantify the spatial dependence of CC flow deficits. RESULTS: Quantitative, lesion-centered zonal analysis of CC OCTA images revealed highest flow-deficit percentages near CNV boundaries, decreasing in zones farther from the boundaries. Optical coherence tomography angiography using shorter (1.5 ms) interscan times revealed more severe flow deficits than OCTA using longer (3.0 ms) interscan times; however, spatial trends were similar for both interscan times. A detailed description of the OCTA processing steps and parameters was provided so as to elucidate their influence on quantitative measurements. CONCLUSION: Impairment of the CC, assessed by flow-deficit percentages, was most prominent closest to CNV boundaries. The lesion-centered zonal analysis technique enabled quantitative CC measurements relative to focal lesions. Understanding how processing steps, imaging/processing parameters, and artifacts can affect quantitative CC measurements is important for longitudinal, OCTA-based studies of disease progression, and treatment response.

Published
2021

43. Retinal Nonperfusion Relationship to Arteries or Veins Observed on Widefield Optical Coherence Tomography Angiography in Diabetic Retinopathy

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Ishibazawa, Akihiro, De Pretto, Lucas R., Alibhai, A. Yasin, Moult, Eric M., Arya, Malvika, Sorour, Osama, Mehta, Nihaal, Baumal, Caroline R., Witkin, Andre J., Yoshida, Akitoshi, Duker, Jay S., Fujimoto, James G., Waheed, Nadia K., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Ishibazawa, Akihiro, De Pretto, Lucas R., Alibhai, A. Yasin, Moult, Eric M., Arya, Malvika, Sorour, Osama, Mehta, Nihaal, Baumal, Caroline R., Witkin, Andre J., Yoshida, Akitoshi, Duker, Jay S., Fujimoto, James G., and Waheed, Nadia K.

Abstract

Copyright 2019 The Authors PURPOSE. To evaluate whether retinal capillary nonperfusion is found predominantly adjacent to arteries or veins in eyes with diabetic retinopathy (DR). METHODS. Sixty-three eyes from 44 patients with proliferative DR (PDR) or non-PDR (NPDR) were included. Images (12 3 12-mm) foveal-centered optical coherence tomography (OCT) angiography (OCTA) images were taken using the Zeiss Plex Elite 9000. In 37 eyes, widefield montages with five fixation points were also obtained. A semiautomatic algorithm that detects nonperfusion in full-retina OCT slabs was developed, and the percentages of capillary nonperfusion within the total image area were calculated. Retinal arteries and veins were manually traced. Based on the shortest distance, nonperfusion pixels were labeled as either arterial-side or venous-side. Arterial-adjacent and venous-adjacent nonperfusion and the A/V ratio (arterial-adjacent nonperfusion divided by venous-adjacent nonperfusion) were quantified. RESULTS. Twenty-two eyes with moderate NPDR, 16 eyes with severe NPDR, and 25 eyes with PDR were scanned. Total nonperfusion area in PDR (median: 8.93%) was greater than in moderate NPDR (3.49%, P < 0.01). Arterial-adjacent nonperfusion was greater than venous-adjacent nonperfusion for all stages of DR (P < 0.001). The median A/V ratios were 1.93 in moderate NPDR, 1.84 in severe NPDR, and 1.78 in PDR. The A/V ratio was negatively correlated with the total nonperfusion area (r ¼ -0.600, P < 0.0001). The results from the widefield montages showed similar patterns. CONCLUSIONS. OCTA images with arteries and veins traced allowed us to estimate the nonperfusion distribution. In DR, smaller nonperfusion tends to be arterial-adjacent, while larger nonperfusion tends toward veins.

Published
2021

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