Development of a generative deep learning model to improve epiretinal membrane detection in fundus photography

Joon Yul Choi; Ik Hee Ryu; Jin Kuk Kim; In Sik Lee; Tae Keun Yoo

doi:10.1186/s12911-024-02431-4

Development of a generative deep learning model to improve epiretinal membrane detection in fundus photography

BMC Med Inform Decis Mak. 2024 Jan 26;24(1):25. doi: 10.1186/s12911-024-02431-4.

Authors

Joon Yul Choi¹, Ik Hee Ryu^{2

3}, Jin Kuk Kim^{2

3}, In Sik Lee², Tae Keun Yoo^{4

5}

Affiliations

¹ Department of Biomedical Engineering, Yonsei University, Wonju, South Korea.
² Department of Refractive Surgery, B&VIIT Eye Center, B2 GT Tower, 1317-23 Seocho-Dong, Seocho-Gu, Seoul, South Korea.
³ Research and development department, VISUWORKS, Seoul, South Korea.
⁴ Department of Refractive Surgery, B&VIIT Eye Center, B2 GT Tower, 1317-23 Seocho-Dong, Seocho-Gu, Seoul, South Korea. eyetaekeunyoo@gmail.com.
⁵ Research and development department, VISUWORKS, Seoul, South Korea. eyetaekeunyoo@gmail.com.

Abstract

Background: The epiretinal membrane (ERM) is a common retinal disorder characterized by abnormal fibrocellular tissue at the vitreomacular interface. Most patients with ERM are asymptomatic at early stages. Therefore, screening for ERM will become increasingly important. Despite the high prevalence of ERM, few deep learning studies have investigated ERM detection in the color fundus photography (CFP) domain. In this study, we built a generative model to enhance ERM detection performance in the CFP.

Methods: This deep learning study retrospectively collected 302 ERM and 1,250 healthy CFP data points from a healthcare center. The generative model using StyleGAN2 was trained using single-center data. EfficientNetB0 with StyleGAN2-based augmentation was validated using independent internal single-center data and external datasets. We randomly assigned healthcare center data to the development (80%) and internal validation (20%) datasets. Data from two publicly accessible sources were used as external validation datasets.

Results: StyleGAN2 facilitated realistic CFP synthesis with the characteristic cellophane reflex features of the ERM. The proposed method with StyleGAN2-based augmentation outperformed the typical transfer learning without a generative adversarial network. The proposed model achieved an area under the receiver operating characteristic (AUC) curve of 0.926 for internal validation. AUCs of 0.951 and 0.914 were obtained for the two external validation datasets. Compared with the deep learning model without augmentation, StyleGAN2-based augmentation improved the detection performance and contributed to the focus on the location of the ERM.

Conclusions: We proposed an ERM detection model by synthesizing realistic CFP images with the pathological features of ERM through generative deep learning. We believe that our deep learning framework will help achieve a more accurate detection of ERM in a limited data setting.

Keywords: Deep learning; Epiretinal membrane; Fundus photography; Generative adversarial net.

MeSH terms

Deep Learning*
Diagnostic Techniques, Ophthalmological
Epiretinal Membrane* / diagnostic imaging
Humans
Photography / methods
Retrospective Studies