EN FACE IMAGE-BASED ANALYSIS OF RETINAL TRACTION CAUSED BY EPIRETINAL MEMBRANE AND ITS RELATIONSHIP WITH VISUAL FUNCTIONS

Overview

Journal Retina

Date 2019 May 29

PMID 31136461

Citations 16

Authors

Masayuki Hirano

Yuki Morizane

Yuki Kanzaki

Shuhei Kimura

Mio Hosokawa

Yusuke Shiode

Shinichiro Doi

Shinji Toshima

Kosuke Takahashi

Mika Hosogi

Atsushi Fujiwara

Ippei Takasu

Fumio Shiraga

Affiliations

Soon will be listed here.

Abstract

Purpose: To evaluate the relationship between retinal traction caused by epiretinal membrane and visual functions.

Methods: In this institutional study, en face swept-source optical coherence tomography images of 141 eyes of 130 patients with epiretinal membrane were analyzed to investigate maximum depth of retinal folds, which represents retinal traction strength and the distribution pattern of retinal folds. We investigated the relationships between the maximum depth and distribution pattern of retinal folds and visual functions as well as the effects of membrane peeling.

Results: Maximum retinal fold depth was significantly correlated with the metamorphopsia score (P < 0.001). Fifteen eyes showed retinal folds radially extending from the macular epiretinal membrane (radiating folds group), whereas 126 eyes showed a multidirectional pattern of retinal folds (multidirectional folds group). The radiating folds group showed a significantly lower metamorphopsia score (P = 0.014). Multiple regression analysis revealed that the metamorphopsia score was significantly related to maximum retinal fold depth (P = 0.003), distribution pattern (P = 0.015), and central retinal thickness (P < 0.001). One month after membrane peeling, parafoveal retinal folds resolved completely in all cases, and both visual acuity (P < 0.001) and average metamorphopsia score (P = 0.036) were significantly improved.

Conclusion: Both the strength and the distribution pattern of retinal traction are significantly related to metamorphopsia in epiretinal membrane patients.

Citing Articles

Postoperative change in the retinal artery angle after vitrectomy surgery in eyes with idiopathic epiretinal membrane.

Nakamura K, Hirono K, Iwashita Y, Nagura K, Okawa K, Inoue T Sci Rep. 2024; 14(1):30208.

PMID: 39632883 PMC: 11618448. DOI: 10.1038/s41598-024-76511-w.

Epiretinal membrane: an overview and update.

Matoba R, Morizane Y Jpn J Ophthalmol. 2024; 68(6):603-613.

PMID: 39466371 PMC: 11607056. DOI: 10.1007/s10384-024-01127-6.

Impact of retinal traction induced by epiretinal membrane on aniseikonia.

Hirano M, Minakawa S, Imamura Y, Yamamoto N Sci Rep. 2024; 14(1):25110.

PMID: 39443506 PMC: 11499936. DOI: 10.1038/s41598-024-72048-0.

Location and Extent of Paravascular Nerve Fiber Layer Clefts in Eyes with Epiretinal Membranes.

Petersen S, Christensen U, Larsen M J Clin Med. 2024; 13(19).

PMID: 39407790 PMC: 11476506. DOI: 10.3390/jcm13195731.

Fingerprint sign of the Henle fibre layer in epiretinal membrane: a cross-sectional and longitudinal study.

Kim Y, Togloom A, Oh J Graefes Arch Clin Exp Ophthalmol. 2024; 262(11):3597-3607.

PMID: 38856954 DOI: 10.1007/s00417-024-06543-5.