Keratoconus detection using deep learning of colour-coded maps with anterior segment optical coherence tomography: a diagnostic accuracy study

Kazutaka Kamiya; Yuji Ayatsuka; Yudai Kato; Fusako Fujimura; Masahide Takahashi; Nobuyuki Shoji; Yosai Mori; Kazunori Miyata

doi:10.1136/bmjopen-2019-031313

Keratoconus detection using deep learning of colour-coded maps with anterior segment optical coherence tomography: a diagnostic accuracy study

BMJ Open. 2019 Sep 27;9(9):e031313. doi: 10.1136/bmjopen-2019-031313.

Authors

Kazutaka Kamiya¹, Yuji Ayatsuka², Yudai Kato², Fusako Fujimura³, Masahide Takahashi⁴, Nobuyuki Shoji⁴, Yosai Mori⁵, Kazunori Miyata⁵

Affiliations

¹ Visual Phisiology, School of Allied Health Sciences, Kitasato University, Sagamihara, Japan kamiyak-tky@umin.ac.jp.
² Cresco Ltd, Technology Laboratory, Tokyo, Japan.
³ Visual Phisiology, School of Allied Health Sciences, Kitasato University, Sagamihara, Japan.
⁴ Department of Ophthalmology, School of Medicine, Kitasato University, Sagamihara, Japan.
⁵ Miyata Eye Hospital, Department of Ophthalmology, Miyakonojo, Japan.

Abstract

Objective: To evaluate the diagnostic accuracy of keratoconus using deep learning of the colour-coded maps measured with the swept-source anterior segment optical coherence tomography (AS-OCT).

Design: A diagnostic accuracy study.

Setting: A single-centre study.

Participants: A total of 304 keratoconic eyes (grade 1 (108 eyes), 2 (75 eyes), 3 (42 eyes) and 4 (79 eyes)) according to the Amsler-Krumeich classification, and 239 age-matched healthy eyes.

Main outcome measures: The diagnostic accuracy of keratoconus using deep learning of six colour-coded maps (anterior elevation, anterior curvature, posterior elevation, posterior curvature, total refractive power and pachymetry map).

Results: Deep learning of the arithmetical mean output data of these six maps showed an accuracy of 0.991 in discriminating between normal and keratoconic eyes. For single map analysis, posterior elevation map (0.993) showed the highest accuracy, followed by posterior curvature map (0.991), anterior elevation map (0.983), corneal pachymetry map (0.982), total refractive power map (0.978) and anterior curvature map (0.976), in discriminating between normal and keratoconic eyes. This deep learning also showed an accuracy of 0.874 in classifying the stage of the disease. Posterior curvature map (0.869) showed the highest accuracy, followed by corneal pachymetry map (0.845), anterior curvature map (0.836), total refractive power map (0.836), posterior elevation map (0.829) and anterior elevation map (0.820), in classifying the stage.

Conclusions: Deep learning using the colour-coded maps obtained by the AS-OCT effectively discriminates keratoconus from normal corneas, and furthermore classifies the grade of the disease. It is suggested that this will become an aid for improving the diagnostic accuracy of keratoconus in daily practice.

Clinical trial registration number: 000034587.

Keywords: accuracy; deep learning; diagnosis; keratoconus; optical coherence tomography.

MeSH terms

Case-Control Studies
Deep Learning*
Disease Progression
Humans
Keratoconus / classification*
Retrospective Studies
Sensitivity and Specificity
Tomography, Optical Coherence / methods*