AI to Identify Strain-Sensitive Regions of the Optic Nerve Head Linked to Functional Loss in Glaucoma.
Chuangsuwanich Thanadet, Nongpiur Monisha E, Braeu Fabian A, Prasad Shimna Clara, Tun Tin A, Thiéry Alexandre, Perera Shamira, Ho Ching Lin, Buist Martin, Barbastathis George
AI Summary
ONH tissue strain significantly improved glaucoma VF defect classification (e.g., superior arcuate, AUC 0.83 to 0.87). Neuroretinal rim strain, particularly inferotemporal, was key, suggesting it's a critical biomechanical biomarker for axonal injury and disease monitoring.
Abstract
Purpose
The purposes of this study were to assess whether optic nerve head (ONH) biomechanics, quantified by tissue strain, improves classification of progressive visual field (VF) loss patterns in glaucoma beyond morphology, and to use saliency maps to identify ONH regions associated with the predictions.
Methods
We recruited 249 patients with glaucoma (mean age 69 ± 5 years, 54% female patients). One eye per subject was imaged under (1) primary gaze and (2) primary gaze with IOP elevated to approximately 35 millimeters of mercury (mm Hg) via ophthalmo-dynamometry. Twelve subjects were excluded due to poor scan quality/limited lamina cribrosa (LC) visibility. Experts classified subjects into four categories based on the presence of specific visual field defects (VFDs): (1) superior nasal step (N = 26), (2) superior partial arcuate (N = 62), (3) full superior hemifield defect (N = 25), and (4) other/non-specific defects (N = 124). Automatic segmentation and digital volume correlation computed neural tissue and LC strains. Biomechanical and structural features were input to a PointNet model. Three classification tasks were performed to detect: (1) superior nasal step, (2) superior partial arcuate, and (3) full superior hemifield defect. Data were split 80/20 (train/test). Area under the curve (AUC) assessed performance. Saliency maps (an explainable artificial intelligence [XAI] technique) highlighted ONH regions most critical to classification.
Results
Models achieved AUCs of 0.77 to 0.88 across VFD classifications. The structure-only model reached an AUC of 0.83 ± 0.02 for superior arcuate defects, which significantly improved to 0.87 ± 0.02 (P < 0.05) with the addition of strain information, demonstrating that ONH biomechanics enhance prediction beyond morphology. Strain-sensitive regions were localized to the inferior and inferotemporal rim, expanding with increasing severity of VF loss.
Conclusions
ONH strain enhances classification of glaucomatous VF loss patterns. The neuroretinal rim, rather than the LC, was most critical, suggesting rim strain may play a dominant role in axonal injury and functional loss.
MeSH Terms
Key Concepts5
Models using optic nerve head (ONH) biomechanics and structural features achieved Area Under the Curve (AUCs) of 0.77 to 0.88 across visual field defect (VFD) classifications (superior nasal step, superior partial arcuate, and full superior hemifield defect) in 249 patients with glaucoma.
The structure-only model for superior arcuate defects achieved an AUC of 0.83 ± 0.02, which significantly improved to 0.87 ± 0.02 (P < 0.05) with the addition of strain information, demonstrating that optic nerve head (ONH) biomechanics enhance prediction beyond morphology in 249 patients with glaucoma.
Strain-sensitive regions of the optic nerve head (ONH) were localized to the inferior and inferotemporal rim, expanding with increasing severity of visual field (VF) loss, suggesting the neuroretinal rim, rather than the lamina cribrosa, is most critical in axonal injury and functional loss in glaucoma.
249 patients with glaucoma (mean age 69 ± 5 years, 54% female) were recruited for a study assessing optic nerve head (ONH) biomechanics and visual field (VF) loss patterns.
Optic nerve head (ONH) images were acquired from 249 patients with glaucoma under primary gaze and primary gaze with intraocular pressure (IOP) elevated to approximately 35 mm Hg via ophthalmo-dynamometry.
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