James Fishbaugh, Ronald Zambrano, Joel S Schuman, Gadi Wollstein, Jared Vicory, Beatriz Paniagua
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引用次数: 0
摘要
青光眼会导致视野逐渐恶化,是全球失明的主要原因。青光眼的损害是不可逆的,对生活质量有很大影响。因此,早期发现青光眼并密切监测其进展情况以保护功能性视力至关重要。在临床上,青光眼的常规监测方法是使用光学相干断层扫描(OCT)进行衍生测量,如重要视觉结构的厚度。对于哪些指标代表青光眼进展最相关的生物标志物,目前还没有达成共识。此外,尽管纵向 OCT 数据越来越多,但与青光眼相关的三维结构随时间变化的定量模型并不存在。在本文中,我们提出了一种算法,将三维 OCT 图像视为结构随时间变化的观测结果,在成像层面执行分层大地构造。分层建模将受试者轨迹作为差分空间中的大地线,而群体水平(青光眼与对照组)轨迹也是大地线,将受试者轨迹解释为平均值的偏差。我们的初步实验表明,与正常衰老相比,青光眼引起的结构变化幅度更大。我们的算法有可能应用于特定患者青光眼进展的监测和分析,以及人口趋势和人口变异的统计模型。
Modeling Longitudinal Optical Coherence Tomography Images for Monitoring and Analysis of Glaucoma Progression.
Glaucoma causes progressive visual field deterioration and is the leading cause of blindness worldwide. Glaucomatous damage is irreversible and greatly impacts quality of life. Therefore, it is critically important to detect glaucoma early and closely monitor progression to preserve functional vision. Glaucoma is routinely monitored in the clinical setting using optical coherence tomography (OCT) for derived measures such as the thickness of important visual structures. There is not a consensus of what measures represent the most relevant biomarkers of glaucoma progression. Further, despite the increasing availability of longitudinal OCT data, a quantitative model of 3D structural change over time associated with glaucoma does not exist. In this paper we present an algorithm that will perform hierarchical geodesic modeling at the imaging level, considering 3D OCT images as observations of structural change over time. Hierarchical modeling includes subject-wise trajectories as geodesics in the space of diffeomorphisms and population level (glaucoma vs control) trajectories are also geodesics which explain subject-wise trajectories as deviations from the mean. Our preliminary experiments demonstrate a greater magnitude of structural change associated with glaucoma compared to normal aging. Our algorithm has the potential application in patient-specific monitoring and analysis of glaucoma progression as well as a statistical model of population trends and population variability.