Purpose : Progression detection in advanced glaucoma is often challenging. Retinal Nerve Fibre Layer Optical Texture Analysis (ROTA), a novel algorithm, uncovers optical texture and trajectories of axonal fibre bundles with high sensitivity and specificity. In this 5-year longitudinal study, we investigated the performance of ROTA in identifying progression and characteristics of axonal fiber bundle losses in advanced glaucoma.

Methods : 95 eyes of 84 patients with advanced glaucoma (vertical cup-to-disc ratio ≥0.85 and visual field mean deviation ≤-12 dB) were followed for at least 5 years. ROTA and retinal nerve fibre layer (RNFL)/ganglion cell-inner plexiform layer (GCIPL) thickness measurements were obtained from the Triton optical coherence tomography (OCT) (Topcon, Japan) and Cirrus HD-OCT (Carl Zeiss Meditec, USA), respectively. Progressive loss in axonal fibre bundle optical texture in ROTA was detected and confirmed by three observers. Progressive RNFL/GCIPL thinning was determined by Guided Progression Analysis (GPA).

Results : Of 95 eyes, progression was identified in 43 eyes (45.3%) by ROTA and 32 eyes (33.7%) by GPA of RNFL thickness and/or GCIPL thickness. Progressive RNFL loss on ROTA was found most often over the superior papillofoveal bundle (10 eyes) (23.3%) followed by the inferior arcuate bundle (9 eyes) (20.9%), the inferior papillomacular bundle (8 eyes) (18.6%), the inferior papillofoveal bundle (7 eyes) (16.3%), the superior arcuate bundle (6 eyes) (14.0%), and the superior papillomacular bundle (6 eyes) (14.0%). For eyes with concomitant progressive RNFL loss on ROTA and progressive RNFL/GCIPL thinning during the study period (n=26 eyes), 21 had progressive RNFL changes detected first by ROTA and 2 had progression identified on the same date; ROTA was on average 10.3 months (95% confidence interval 3.0-17.6 months) ahead of GPA of RNFL/GCIPL thickness in detecting glaucoma progression.

Conclusions : ROTA could identify progressive axonal fibre bundle loss in advanced glaucoma that was not detectable in conventional progression analysis of RNFL/GCIPL thickness.

This abstract was presented at the 2024 ARVO Annual Meeting, held in Seattle, WA, May 5-9, 2024.

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Figure 1. Venn diagram (no. of eyes).

Figure 1. Venn diagram (no. of eyes).

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Figure 2. Comparison of ROTA (a), RNFL GPA (b) and GCIPL GPA (c) to discern the location of RNFL defects.

Figure 2. Comparison of ROTA (a), RNFL GPA (b) and GCIPL GPA (c) to discern the location of RNFL defects.

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