Dilated choroidal veins and their role in recurrences of myopic macular neovascularisations

Myopic choroidal neovascularization with neovascular signal around perforating scleral vessel prone to recur after anti-VEGF therapy

BACKGROUND

To compare the recurrence of myopic choroidal neovascularization (mCNV) based on the neovascular signal of mCNV around the perforating scleral vessel (PSV).

METHODS

A consecutive series of naïve patients with mCNV accepted anti-VEGF therapy with a minimum 12-month follow-up period. The neovascular signal relationship between PSV and mCNV were classified into the presence of neovascular signal of CNV around PSV or not. The recurrence of mCNV, best-corrected visual acuity (BCVA), hyperreflective foci height, CNV area and CNV flow area were analyzed between two groups.

RESULTS

Neovascular signal of CNV around PSV was detected in 20 eyes (39.2%). The one-year recurrence rate in the group with neovascular signal of CNV around PSV was significantly higher than that in the group without neovascular signal of CNV around PSV (P = 0.045). The recurrence time in the group with neovascular signal around PSV was shorter than that in the group without neovascular signal around PSV (P = 0.030). Cox proportional hazard model showed that the presence of neovascular signal of CNV around PSV [hazard ratio (HR): 2.904] and subfoveal choroidal thickness ≤ 50 μm (HR: 0.368) were risk factors for recurrence of mCNV. In the group with neovascular signal around PSV, the BCVA was worse (P = 0.024) and the CNV flow area was more unstable (P = 0.027) after therapy.

CONCLUSIONS

PSV was commonly detected in patients with mCNV. The presence of neovascular signal of CNV around PSV was prone to recur with a shorter time in mCNV patients.

A Novel Exploration of the Choroidal Vortex Vein System: Incidence and Characteristics of Posterior Vortex Veins in Healthy Eyes

Purpose

The purpose of this study was to investigate the incidence and characteristics of posterior vortex veins (PVVs) in healthy eyes and explore their relationship with age and refractive status.

Methods

This retrospective cross-sectional analysis encompassed 510 eyes from 255 consecutive healthy participants. Wide-field optical coherence tomography angiography (WF-OCTA) imaging was used to assess the presence of PVVs. Eyes were classified according to refractive status (emmetropia, low and moderate myopia, and high myopia) and age (minors and adults). The incidence and characteristics of eyes with PVVs were analyzed.

Results

Participants (mean age = 30.60 ± 21.12 years, 47.4% men) showed a mean refractive error of -2.83 ± 3.10 diopters (D; range = -12.00 to +0.75). PVVs were observed in 16.1% (82/510) of eyes. Of these, 39% (32/82) had PVVs in one eye and 61% (50/82) in both eyes. The mean number of PVVs per eye was 1.65 ± 1.05 (range = 1-6). PVVs are mainly around the optic disc (78%, 64/82) of eyes with PVVs and less in the macular area (6.1%, 5/82) or elsewhere (15.9%, 13/82). PVV incidence correlated with refractive status: 10.3% (22/213) in emmetropia, 16.6% (31/187) in low and moderate myopia, and 26.4% (29/110) in high myopia (P = 0.001), but not with age. Refractive status was the key predictor of PVV occurrence (odds ratio [OR] = 1.45, 95% confidence interval [CI] = 1.02-2.06, P = 0.038).

Conclusions

This study confirms PVVs' presence in healthy eyes, highlighting their inherent existence and susceptibility to alterations due to refractive conditions. These findings enhance our understanding of the vortex vein system and its distribution within the eyes.

ASSESSMENT AND ROLE OF ARTERY-VEIN COMPLEX IN MYOPIC CHOROIDAL NEOVASCULARIZATION USING OPTICAL COHERENCE TOMOGRAPHY ANGIOGRAPHY

PURPOSE

To analyze the presence of an artery-vein complex (AVC) underneath myopic choroidal neovascularization (mCNV) and to determine its relationship with neovascular activity.

METHODS

Retrospective analysis of 681 eyes from 362 patients with high myopia defined by an axial length of >26 mm using optical coherence tomography (OCT) and OCT angiography imaging. Patients with clinical diagnosis of mCNV and good quality OCT angiography images were then selected. An AVC was defined by the identification of both perforating scleral vessels and dilated choroidal veins under or in contact with the mCNV in the same case. Swept source OCT (SS-OCT) and SS-OCT angiography images (TRITON; Topcon Corporation, Tokyo, Japan) were reviewed to detect AVC in the mCNV area.

RESULTS

Fifty eyes of 49 highly myopic patients with mCNV were analyzed. Eyes with AVC were statistically older (69.95 ± 13.53 vs. 60.83 ± 10.47 years old; P < 0.01), needed less intravitreal injections/year along the follow-up period (0.80 ± 0.62 vs. 1.92 ± 0.17; P < 0.01), and showed less relapses/year (0.58 ± 0.75 vs. 0.46 ± 0.42; P < 0.05) when compared with eyes without AVC. Moreover, eyes with AVC were less likely to relapse during the first year from mCNV activation (n = 5/14 vs. n = 14/16; P < 0.01; P < 0.01). No significant differences were found regarding either axial length (30.55 ± 2.31 vs. 29.65 ± 2.24, P > 0.05) or best-corrected visual acuity (0.4 ± 0.5 vs. 0.4 ± 0.5 Logarithm of the Minimum Angle of Resolution (logMAR), P > 0.05) between groups.

CONCLUSION

AVC complex has an influence over myopic choroidal neovascularization activity resulting in less aggressive neovascular lesions than those with perforating scleral vessels only.