降低形状图复杂性并应用于视网膜血管和神经元分类

arXiv - STAT - Computation Pub Date : 2024-09-13 DOI:arxiv-2409.09168

Benjamin Beaudett, Anuj Srivastava

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引用次数: 0

摘要

形状图是生物和解剖系统中常见的复杂几何结构。形状图是节点的集合，其中一些节点由任意形状的曲线边连接。它们的高复杂性源于大量的节点和边以及边的复杂形状。为了进行统计分析，我们需要尽可能多地保留原始形状图全局结构的低复杂度表示法。本文利用层次聚类程序开发了一个降低图形复杂性的框架，该程序用更简单的代表来代替节点和边的组。本文使用二维视网膜血管图和三维神经元图演示了这一框架。论文还介绍了使用逐步降低的图形复杂度对形状图进行分类的实验。当复杂度降低时，视网膜血管病变检测的准确度迅速下降，尤其是在舍弃末端边缘时，准确度下降尤为明显。神经细胞类型的识别准确率随着复杂度的降低而保持稳定。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Reducing Shape-Graph Complexity with Application to Classification of Retinal Blood Vessels and Neurons

Shape graphs are complex geometrical structures commonly found in biological and anatomical systems. A shape graph is a collection of nodes, some connected by curvilinear edges with arbitrary shapes. Their high complexity stems from the large number of nodes and edges and the complex shapes of edges. With an eye for statistical analysis, one seeks low-complexity representations that retain as much of the global structures of the original shape graphs as possible. This paper develops a framework for reducing graph complexity using hierarchical clustering procedures that replace groups of nodes and edges with their simpler representatives. It demonstrates this framework using graphs of retinal blood vessels in two dimensions and neurons in three dimensions. The paper also presents experiments on classifications of shape graphs using progressively reduced levels of graph complexity. The accuracy of disease detection in retinal blood vessels drops quickly when the complexity is reduced, with accuracy loss particularly associated with discarding terminal edges. Accuracy in identifying neural cell types remains stable with complexity reduction.

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arXiv - STAT - Computation

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