Ahmed A. Sleman, A. Soliman, M. Ghazal, H. Sandhu, S. Schaal, Adel Said Elmaghraby, A. El-Baz
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引用次数: 2
摘要
在三维光学相干断层扫描(OCT)数据中准确分割人眼视网膜层提供相关的临床信息。本文介绍了一种3D分割方法,该方法使用自适应患者特异性视网膜图谱以及3D OCT数据的外观模型。为了重建三维视网膜扫描图谱,我们首先分割黄斑的中心区域,在那里我们可以清楚地识别中央凹。利用马尔可夫吉布斯随机场(Markov Gibbs Random Field, MGRF),包括12层视网膜的强度、形状和空间信息,对视网膜中央凹选定区域进行分割。从200个不同的个体收集的一组共同注册的OCT扫描被用来预先构建一个二维形状。在接下来的步骤中,将这种形状先验适应于一阶外观和二阶空间相互作用的MGRF模型。对黄斑中心“中央凹区”进行分割后,利用已分割的层的标记和外观对相邻的切片进行分割。然后递归重复最后一步,直到患者的3D OCT扫描被分割。这种方法在35个人身上进行了测试,其中一些是正常的,另一些是病理的,然后与人工分割的地面真相进行比较,最后这些结果由医学视网膜专家验证。使用骰子相似系数(DSC)、一致系数(AC)和平均偏差(AD)等指标来衡量所提出方法的性能。所提出的方法的完成精度显示出有希望的结果,与最先进的3D OCT方法相比具有明显的优势。
The accurate segmentation of retinal layers of the eye in a 3-D Optical Coherence Tomography (OCT) data provides relevant clinical information. This paper introduces a 3D segmentation approach that uses an adaptive patient-specific retinal atlas as well as an appearance model for 3D OCT data. To reconstruct that atlas of 3D retinal scan, we first segment the central area of the macula at which we can clearly identify the fovea. Markov Gibbs Random Field (MGRF) including intensity, shape, and spatial information of 12 layers of retina were all used to segment the selected area of retinal fovea. A set of co-registered OCT scans that were gathered from 200 different individuals were used to build A 2D shape prior. This shape prior was adapted in a following step to the first order appearance and second order spatial interaction MGRF model. After segmenting the center of the macula “foveal area”, the labels and appearances of the layers that have been segmented were used to have the adjacent slices segmented as well. The last step was then repeated recursively until the a 3D OCT scan of the patient is segmented. This approach was tested on 35 individuals while some of them were normal and others were pathological, and then compared to a manually segmented ground truth and finally these results were verified by medical retina experts. Metrics such as Dice Similarity Coefficient (DSC), agreement coefficient (AC), and average deviation (AD) metrics were used to measure the performance of the proposed approach. Accomplished accuracy by the proposed approach shows promising results with noticeable advantages over the state-of-the-art 3D OCT approach.
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