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Angle-Closure Detection in Anterior Segment OCT based on Multi-Level Deep Network

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arxiv 1902.03585 v1 pith:HRBEAAD3 submitted 2019-02-10 cs.CV

Angle-Closure Detection in Anterior Segment OCT based on Multi-Level Deep Network

classification cs.CV
keywords as-octdeepdetectionangle-closureanteriorlearningsegmentsystem
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Irreversible visual impairment is often caused by primary angle-closure glaucoma, which could be detected via Anterior Segment Optical Coherence Tomography (AS-OCT). In this paper, an automated system based on deep learning is presented for angle-closure detection in AS-OCT images. Our system learns a discriminative representation from training data that captures subtle visual cues not modeled by handcrafted features. A Multi-Level Deep Network (MLDN) is proposed to formulate this learning, which utilizes three particular AS-OCT regions based on clinical priors: the global anterior segment structure, local iris region, and anterior chamber angle (ACA) patch. In our method, a sliding window based detector is designed to localize the ACA region, which addresses ACA detection as a regression task. Then, three parallel sub-networks are applied to extract AS-OCT representations for the global image and at clinically-relevant local regions. Finally, the extracted deep features of these sub-networks are concatenated into one fully connected layer to predict the angle-closure detection result. In the experiments, our system is shown to surpass previous detection methods and other deep learning systems on two clinical AS-OCT datasets.

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