Tracking the optic nerve head in OCT video using dual eigenspaces and an adaptive vascular distribution model

Optical coherence tomography (OCT) is a novel ophthalmic imaging modality generating cross sectional views of the retina. OCT systems form images in 1.5 seconds by directing a superluminescent diode (SLD) beam over the retinal surface. Involuntary ocular motion may occur, however, causing incorrect locations to be imaged. This motion may leave no obvious artifacts and thus go undetected. For glaucoma monitoring especially, knowing the measurement location is crucial. The commercially available OCT system displays a near-IR video of the SLD beam traversing the retinal around the optic nerve head. We developed a prototype system to detect the nerve head and SLD beam position in this video, and report the actual scan path relative to the nerve head. This system must cope with low image contrast and few reliable retinal features. In its adaptive model generation phase, the system directly detects vasculature and the nerve head and builds an individual model of the vascular pattern. The nerve head identification is multi-tiered, using a novel, dual-eigenspace technique and a geometric comparison of detected vessel positions and nerve head hypotheses. In its operational phase, a correspondence is achieved between detected vasculature and the model. The system was evaluated on video of three subjects not used to form the eigenspaces. The system located the optic nerve head to within 5 pixels in 99% of 2800 video fields manually inspected, and was thus able to determine the true scan path relative to the nerve head.

[1]  Paul Watta,et al.  An eigenface approach for estimating driver pose , 2000, ITSC2000. 2000 IEEE Intelligent Transportation Systems. Proceedings (Cat. No.00TH8493).

[2]  W. J. Daunicht,et al.  Eye movement measurement with the scanning laser ophthalmoscope , 1992 .

[3]  Jun Zhang,et al.  Pace recognition: eigenface, elastic matching, and neural nets , 1997, Proc. IEEE.

[4]  Lawrence Sirovich,et al.  Application of the Karhunen-Loeve Procedure for the Characterization of Human Faces , 1990, IEEE Trans. Pattern Anal. Mach. Intell..

[5]  Hong Shen,et al.  Rapid automated tracing and feature extraction from retinal fundus images using direct exploratory algorithms , 1999, IEEE Transactions on Information Technology in Biomedicine.

[6]  M. Goldbaum,et al.  Detection of blood vessels in retinal images using two-dimensional matched filters. , 1989, IEEE transactions on medical imaging.

[7]  M. Turk,et al.  Eigenfaces for Recognition , 1991, Journal of Cognitive Neuroscience.

[8]  B. Roysam,et al.  Image processing algorithms for retinal montage synthesis, mapping, and real-time location determination , 1998, IEEE Transactions on Biomedical Engineering.

[9]  T.Q. Nguyen,et al.  Frontal face localization using linear discriminant , 1999, Conference Record of the Thirty-Third Asilomar Conference on Signals, Systems, and Computers (Cat. No.CH37020).

[10]  David J. Kriegman,et al.  Eigenfaces vs. Fisherfaces: Recognition Using Class Specific Linear Projection , 1996, ECCV.

[11]  Charles V. Stewart,et al.  Robust hierarchical algorithm for constructing a mosaic from images of the curved human retina , 1999, Proceedings. 1999 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (Cat. No PR00149).

[12]  Elizabeth C. Botha,et al.  Automatic face recognition in a heterogeneous population , 1998, Pattern Recognit. Lett..

[13]  Stan Z. Li,et al.  Face recognition using the nearest feature line method , 1999, IEEE Trans. Neural Networks.