A Joint Multitask Learning Model for Cross-sectional and Longitudinal Predictions of Visual Field Using OCT.
Asaoka Ryo, Xu Linchuan, Murata Hiroshi, Kiwaki Taichi, Matsuura Masato, Fujino Yuri, Tanito Masaki, Mori Kazuhiko, Ikeda Yoko, Kanamoto Takashi
AI Summary
This study developed an AI model using OCT to predict both current visual field (10°) and future progression (24-2) in glaucoma, showing superior accuracy for earlier detection and monitoring.
Abstract
Purpose
We constructed a multitask learning model (latent space linear regression and deep learning [LSLR-DL]) in which the 2 tasks of cross-sectional predictions (using OCT) of visual field (VF; central 10°) and longitudinal progression predictions of VF (30°) were performed jointly via sharing the deep learning (DL) component such that information from both tasks was used in an auxiliary manner (The Association for Computing Machinery's Special Interest Group on Knowledge Discovery and Data Mining [SIGKDD] 2021). The purpose of the current study was to investigate the prediction accuracy preparing an independent validation dataset.
Design
Cohort study.
Participants
Cross-sectional training and testing data sets included the VF (Humphrey Field Analyzer [HFA] 10-2 test) and an OCT measurement (obtained within 6 months) from 591 eyes of 351 healthy people or patients with open-angle glaucoma (OAG) and from 155 eyes of 131 patients with OAG, respectively. Longitudinal training and testing data sets included 7984 VF results (HFA 24-2 test) from 998 eyes of 592 patients with OAG and 1184 VF results (HFA 24-2 test) from 148 eyes of 84 patients with OAG, respectively. Each eye had 8 VF test results (HFA 24-2 test). The OCT sequences within the observation period were used.
Methods
Root mean square error (RMSE) was used to evaluate the accuracy of LSLR-DL for the cross-sectional prediction of VF (HFA 10-2 test). For the longitudinal prediction, the final (eighth) VF test (HFA 24-2 test) was predicted using a shorter VF series and relevant OCT images, and the RMSE was calculated. For comparison, RMSE values were calculated by applying the DL component (cross-sectional prediction) and the ordinary pointwise linear regression (longitudinal prediction).
Main outcome measures
Root mean square error in the cross-sectional and longitudinal predictions.
Results
Using LSLR-DL, the mean RMSE in the cross-sectional prediction was 6.4 dB and was between 4.4 dB (VF tests 1 and 2) and 3.7 dB (VF tests 1-7) in the longitudinal prediction, indicating that LSLR-DL significantly outperformed other methods.
Conclusions
The results of this study indicate that LSLR-DL is useful for both the cross-sectional prediction of VF (HFA 10-2 test) and the longitudinal progression prediction of VF (HFA 24-2 test).
Shields Classification
Key Concepts6
Using the multitask learning model (LSLR-DL), the mean root mean square error (RMSE) in the cross-sectional prediction of visual field (HFA 10-2 test) was 6.4 dB.
Using the multitask learning model (LSLR-DL), the mean root mean square error (RMSE) in the longitudinal prediction of visual field (HFA 24-2 test) was between 4.4 dB (VF tests 1 and 2) and 3.7 dB (VF tests 1-7).
The multitask learning model (LSLR-DL) significantly outperformed other methods for both the cross-sectional prediction of visual field (HFA 10-2 test) and the longitudinal progression prediction of visual field (HFA 24-2 test).
A multitask learning model (latent space linear regression and deep learning [LSLR-DL]) was constructed for cross-sectional predictions of visual field (VF; central 10°) and longitudinal progression predictions of VF (30°).
The cross-sectional training and testing datasets for the multitask learning model included visual field (Humphrey Field Analyzer [HFA] 10-2 test) and OCT measurements (obtained within 6 months) from 591 eyes of 351 healthy people or patients with open-angle glaucoma (OAG) and from 155 eyes of 131 patients with OAG, respectively.
The longitudinal training and testing datasets for the multitask learning model included 7984 visual field (VF) results (HFA 24-2 test) from 998 eyes of 592 patients with open-angle glaucoma (OAG) and 1184 VF results (HFA 24-2 test) from 148 eyes of 84 patients with OAG, respectively, with each eye having 8 VF test results.
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