J GlaucomaAugust 20166 citations

Regression Analysis of Optical Coherence Tomography Disc Variables for Glaucoma Diagnosis.

Richter Grace M, Zhang Xinbo, Tan Ou, Francis Brian A, Chopra Vikas, Greenfield David S, Varma Rohit, Schuman Joel S, Huang David

View on PubMed DOI: 10.1097/IJG.0000000000000378

AI Summary

OCT disc variables were studied for glaucoma diagnosis. Adjusting for disc size/axial length did not improve accuracy; however, rim area and vertical CDR showed high diagnostic value.

Abstract

Purpose

To report diagnostic accuracy of optical coherence tomography (OCT) disc variables using both time-domain (TD) and Fourier-domain (FD) OCT, and to improve the use of OCT disc variable measurements for glaucoma diagnosis through regression analyses that adjust for optic disc size and axial length-based magnification error.

Design

Observational, cross-sectional.

Participants

In total, 180 normal eyes of 112 participants and 180 eyes of 138 participants with perimetric glaucoma from the Advanced Imaging for Glaucoma Study.

Methods

Diagnostic variables evaluated from TD-OCT and FD-OCT were: disc area, rim area, rim volume, optic nerve head volume, vertical cup-to-disc ratio (CDR), and horizontal CDR. These were compared with overall retinal nerve fiber layer thickness and ganglion cell complex. Regression analyses were performed that corrected for optic disc size and axial length. Area-under-receiver-operating curves (AUROC) were used to assess diagnostic accuracy before and after the adjustments. An index based on multiple logistic regression that combined optic disc variables with axial length was also explored with the aim of improving diagnostic accuracy of disc variables.

Main outcome measure: Comparison of diagnostic accuracy of disc variables, as measured by AUROC.

Results

The unadjusted disc variables with the highest diagnostic accuracies were: rim volume for TD-OCT (AUROC=0.864) and vertical CDR (AUROC=0.874) for FD-OCT. Magnification correction significantly worsened diagnostic accuracy for rim variables, and while optic disc size adjustments partially restored diagnostic accuracy, the adjusted AUROCs were still lower. Axial length adjustments to disc variables in the form of multiple logistic regression indices led to a slight but insignificant improvement in diagnostic accuracy.

Conclusions

Our various regression approaches were not able to significantly improve disc-based OCT glaucoma diagnosis. However, disc rim area and vertical CDR had very high diagnostic accuracy, and these disc variables can serve to complement additional OCT measurements for diagnosis of glaucoma.

MeSH Terms

AdultAgedArea Under CurveAxial Length, EyeCase-Control StudiesCross-Sectional StudiesFemaleGlaucomaHumansIntraocular PressureMaleMiddle AgedOptic DiskROC CurveRegression AnalysisRetinaRetinal Ganglion CellsSensitivity and SpecificityTomography, Optical CoherenceVisual Field TestsVisual Fields

Shields Classification

Ch. 4Optic Nerve, Retina, and Choroid

Ch. 5Assessment of Visual Fields

Key Concepts6

The unadjusted disc variables with the highest diagnostic accuracies for glaucoma diagnosis were rim volume for time-domain optical coherence tomography (TD-OCT) with an AUROC of 0.864, and vertical cup-to-disc ratio (CDR) for Fourier-domain optical coherence tomography (FD-OCT) with an AUROC of 0.874.