Abstract
Age-related macular degeneration (AMD) affects millions of people and is a leading cause of blindness throughout the world. Ideally, affected individuals would be identified at an early stage before late sequelae such as outer retinal atrophy or exudative neovascular membranes develop, which could produce irreversible visual loss. Early identification could allow patients to be staged and appropriate monitoring intervals to be established. Accurate staging of earlier AMD stages could also facilitate the development of new preventative therapeutics. However, accurate and precise staging of AMD, particularly using newer optical coherence tomography (OCT)-based biomarkers may be time-intensive and requires expert training which may not feasible in many circumstances, particularly in screening settings. In this work we develop deep learning method for automated detection and classification of early AMD OCT biomarker. Deep convolution neural networks (CNN) were explicitly trained for performing automated detection and classification of hyperreflective foci, hyporeflective foci within the drusen, and subretinal drusenoid deposits from OCT B-scans. Numerous experiments were conducted to evaluate the performance of several state-of-the-art CNNs and different transfer learning protocols on an image dataset containing approximately 20000 OCT B-scans from 153 patients. An overall accuracy of 87% for identifying the presence of early AMD biomarkers was achieved.
Highlights
Age-related macular degeneration (AMD) is the leading cause of blindness among elderly individuals in the developed world
We report on the performance of an automated method for detection and classification of multiple early AMD biomarkers: namely, reticular pseudodrusen, intraretinal hyperreflective and hypoflective foci (Fig. 1)
From the receiver operating characteristic (ROC) curves as shown in Fig. 5, InceptionResNet is better suited for detecting the presence of subretinal drusenoid deposits (SDD) and intraretinal hyperreflective foci (IHRF); and Inception is better suited for identifying the presence of hyporeflective foci (hRF)
Summary
Age-related macular degeneration (AMD) is the leading cause of blindness among elderly individuals in the developed world. Relying on color fundus photographs, various studies[3,5,6] have identified risk factors for progression that include the manifestation of large drusen, an increased total drusen area, hyperpigmentation, and depigmentation. Based on these risk factors, the Age-Related Eye Disease Study (AREDS) defined a nine-step detailed scale[7], as well as a simplified scale[8] for assessing the risk of progression of AMD. This paper mainly focuses on developing artificial intelligent methods for the assessment of SSD, HRF and hRF
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