Comparison of Methods to Detect and Measure Glaucomatous Visual Field Progression

Overview

Journal Transl Vis Sci Technol

Specialties Biomedical Engineering
Ophthalmology

Date 2019 Sep 27

PMID 31555493

Citations 28

Authors

Alessandro Rabiolo

Esteban Morales

Lilian Mohamed

Vicente Capistrano

Ji Hyun Kim

Abdelmonem Afifi

Fei Yu

Anne L Coleman

Kouros Nouri-Mahdavi

Joseph Caprioli

Affiliations

Soon will be listed here.

Abstract

Purpose: To compare methods to assess visual field (VF) progression in glaucoma.

Methods: 4,950 VFs of 253 primary open angle-glaucoma patients were evaluated for progression with the following methods: clinical evaluation, guided progression analysis (GPA), mean deviation (MD), and visual field index (VFI) rates, Advanced Glaucoma Intervention Study (AGIS) and Collaborative Initial Glaucoma Treatment Study (CIGTS) scores, pointwise linear regression (PLR), permutation of PLR (PoPLR), and glaucoma rate index (GRI). A separate simulated series of longitudinal VFs was assessed with all methods except for GPA and clinical evaluation.

Results: The average (±SD) age of the patients at baseline was 65.4 (±11.5) years. The average (±SD) follow-up was 11.8 (±4.6) years, and the mean (±SD) number of VFs was 16.8 (±7.0). Proportion of series detected as progressing was 65% for PoPLR, 58% for GRI, 41% for GPA, 40% for PLR, 36% for CIGTS, 35% for clinicians, 31% for MD rate, 29% for AGIS, and 22% for VFI rate. Median times to detection of progression were 7.3 years for PoPLR, 7.5 years for GRI, 11 years for clinicians, 14 years for GPA, 16 years for PLR, 17 years for CIGTS, 19 years for AGIS, and more than 20 years for MD and VFI rates. In simulated VF series, GRI had the highest partial area under the receiver operator characteristic curve (0.040) to distinguish between glaucoma progression and aging/cataract decay, followed by VFI rate (0.028), MD rate (0.024), and PoPLR (0.006).

Conclusions: GRI and PoPLR showed the highest proportion of series detected as progressing and shortest times to progression detection. GRI exhibited the best ability to detect progression in the simulated VF series.

Translational Relevance: Knowledge of the properties of every method would allow tailoring application in both clinical and research settings.

Citing Articles

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[Visual field prediction based on temporal-spatial feature learning].

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Fuzzy clustering of 24-2 visual field patterns can detect glaucoma progression.

Kim H, Moon S, Lee J, Kim E, Jin S, Kim J PLoS One. 2024; 19(9):e0309011.

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Patil T, Natarajan V, George R Indian J Ophthalmol. 2024; 72(12):1734-1740.

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