OCT angiography (OCTA) is an extension of OCT that can readily segment and image the central subfield and parafoveal macular microvasculature.
8 Using motion contrast by comparing multiple B-scans obtained at the same location, vessel density metrics obtained from OCTA images have been used to discriminate different ETDRS severity levels in the diabetic retina.
9–11 However, limitations of OCTA include motion artifacts attributed to poor fixation, projection artifacts, segmentation errors, lack of information regarding vascular leakage or permeability, difficulties in distinguishing pseudoflow from true flow, and a comparatively smaller field of view.
12,13 To address some of these limitations, montaging of multiple images, averaging of multiple en face OCTA images, and patient guidance to avoid decentration and defocus have been used.
14,15 However, when comparing quantitative OCTA metrics from the superficial capillary plexus (SCP), deep capillary plexus (DCP) and choroid, intereye, or intersubject variabilities including age,
16 axial length,
17 refractive error,
18 and astigmatism,
19 may result in difficulties comparing across a cohort of eyes requiring mathematical calculations to account for these variabilities.
19 Additionally, studies have shown significant differences in quantitative metrics across multiple OCTA devices
20 and limited reproducibility of quantitative metrics with different postprocessing algorithms.
21 Given these concerns with intereye quantitative metric comparisons, evaluating intraeye characteristics and the impact of retinal disease on quantitative measurements in different quadrants within a single eye with quadrant asymmetry (QA) analysis may be a potential solution. For instance, quadrant analyses were conducted in optic disc drusen patients.
22 Additionally, QA was also used by our group to show the presence of asymmetric outflow with wide field indocyanine green angiography among the vortex veins in central serous chorioretinopathy and pachychoroid diseased eyes.
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