Heidelberg Retina Tomograph Measurements of the Optic Disc and Parapapillary Retina for Detecting Glaucoma Analyzed by Machine Learning Classifiers

doi:10.1167/iovs.04-0202

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Heidelberg Retina Tomograph Measurements of the Optic Disc and Parapapillary Retina for Detecting Glaucoma Analyzed by Machine Learning Classifiers

Linda M. Zangwill,¹ Kwokleung Chan,²^,3 Christopher Bowd,¹ Jicuang Hao,²^,3 Te-Won Lee,²^,3 Robert N. Weinreb,¹ Terrence J. Sejnowski,²^,3 and Michael H. Goldbaum¹

^¹From the Hamilton Glaucoma Center and the ^²Institute for Neural Computation, University of California at San Diego, La Jolla, California; and the ^³Computational Neurobiology Laboratories, The Salk Institute, La Jolla, California.

PURPOSE. To determine whether topographical measurements ofthe parapapillary region analyzed by machine learning classifierscan detect early to moderate glaucoma better than similarlyprocessed measurements obtained within the disc margin and toimprove methods for optimization of machine learning classifierfeature selection.

METHODS. One eye of each of 95 patients with early to moderateglaucomatous visual field damage and of each of 135 normal subjectsolder than 40 years participating in the longitudinal DiagnosticInnovations in Glaucoma Study (DIGS) were included. HeidelbergRetina Tomograph (HRT; Heidelberg Engineering, Dossenheim, Germany)mean height contour was measured in 36 equal sectors, both alongthe disc margin and in the parapapillary region (at a mean contourline radius of 1.7 mm). Each sector was evaluated individuallyand in combination with other sectors. Gaussian support vectormachine (SVM) learning classifiers were used to interpret HRTsector measurements along the disc margin and in the parapapillaryregion, to differentiate between eyes with normal and glaucomatousvisual fields and to compare the results with global and regionalHRT parameter measurements. The area under the receiver operatingcharacteristic (ROC) curve was used to measure diagnostic performanceof the HRT parameters and to evaluate the cross-validation strategiesand forward selection and backward elimination optimizationtechniques that were used to generate the reduced feature sets.

RESULTS. The area under the ROC curve for mean height contourof the 36 sectors along the disc margin was larger than thatfor the mean height contour in the parapapillary region (0.97and 0.85, respectively). Of the 36 individual sectors alongthe disc margin, those in the inferior region between 240°and 300°, had the largest area under the ROC curve (0.85–0.91).With SVM Gaussian techniques, the regional parameters showedthe best ability to discriminate between normal eyes and eyeswith glaucomatous visual field damage, followed by the globalparameters, mean height contour measures along the disc margin,and mean height contour measures in the parapapillary region.The area under the ROC curve was 0.98, 0.94, 0.93, and 0.85,respectively. Cross-validation and optimization techniques demonstratedthat good discrimination (99% of peak area under the ROC curve)can be obtained with a reduced number of HRT parameters.

CONCLUSIONS. Mean height contour measurements along the discmargin discriminated between normal and glaucomatous eyes betterthan measurements obtained in the parapapillary region.

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