Pointwise Visual Field Estimation From Optical Coherence Tomography in Glaucoma Using Deep Learning.
Hemelings Ruben, Elen Bart, Barbosa-Breda João, Bellon Erwin, Blaschko Matthew B, De Boever Patrick, Stalmans Ingeborg
AI Summary
Deep learning accurately estimated glaucoma visual field sensitivities (global and pointwise) from OCT scans, offering a consistent alternative for patients unable to perform reliable visual field tests.
Abstract
Purpose
Standard automated perimetry is the gold standard to monitor visual field (VF) loss in glaucoma management, but it is prone to intrasubject variability. We trained and validated a customized deep learning (DL) regression model with Xception backbone that estimates pointwise and overall VF sensitivity from unsegmented optical coherence tomography (OCT) scans.
Methods
DL regression models have been trained with four imaging modalities (circumpapillary OCT at 3.5 mm, 4.1 mm, and 4.7 mm diameter) and scanning laser ophthalmoscopy en face images to estimate mean deviation (MD) and 52 threshold values. This retrospective study used data from patients who underwent a complete glaucoma examination, including a reliable Humphrey Field Analyzer (HFA) 24-2 SITA Standard (SS) VF exam and a SPECTRALIS OCT.
Results
For MD estimation, weighted prediction averaging of all four individuals yielded a mean absolute error (MAE) of 2.89 dB (2.50-3.30) on 186 test images, reducing the baseline by 54% (MAEdecr%). For 52 VF threshold values' estimation, the weighted ensemble model resulted in an MAE of 4.82 dB (4.45-5.22), representing an MAEdecr% of 38% from baseline when predicting the pointwise mean value. DL managed to explain 75% and 58% of the variance (R2) in MD and pointwise sensitivity estimation, respectively.
Conclusions
Deep learning can estimate global and pointwise VF sensitivities that fall almost entirely within the 90% test-retest confidence intervals of the 24-2 SS test.
Translational relevance: Fast and consistent VF prediction from unsegmented OCT scans could become a solution for visual function estimation in patients unable to perform reliable VF exams.
MeSH Terms
Shields Classification
Key Concepts5
For mean deviation (MD) estimation, a weighted prediction averaging of four individual deep learning models yielded a mean absolute error (MAE) of 2.89 dB (2.50-3.30) on 186 test images, reducing the baseline by 54% (MAEdecr%) in glaucoma patients.
For 52 visual field threshold values' estimation, a weighted ensemble deep learning model resulted in a mean absolute error (MAE) of 4.82 dB (4.45-5.22), representing an MAEdecr% of 38% from baseline when predicting the pointwise mean value in glaucoma patients.
Deep learning models managed to explain 75% of the variance (R2) in mean deviation (MD) and 58% of the variance (R2) in pointwise sensitivity estimation in glaucoma patients.
Deep learning can estimate global and pointwise visual field (VF) sensitivities that fall almost entirely within the 90% test-retest confidence intervals of the 24-2 SITA Standard (SS) test in glaucoma patients.
A customized deep learning (DL) regression model with Xception backbone, trained with four imaging modalities (circumpapillary OCT at 3.5 mm, 4.1 mm, and 4.7 mm diameter) and scanning laser ophthalmoscopy en face images, can estimate pointwise and overall visual field (VF) sensitivity from unsegmented optical coherence tomography (OCT) scans in glaucoma patients.
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