Assessing the feasibility of estimating axon diameter using diffusion models and machine learning

2017 IEEE 14th International Symposium on Biomedical Imaging (ISBI 2017) Pub Date : 2017-04-18 DOI:10.1109/ISBI.2017.7950631

Rutger Fick, N. Sepasian, M. Pizzolato, A. Ianuş, R. Deriche

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引用次数: 6

Abstract

Axon diameter estimation has been a focus of the diffusion MRI community for the past decade. The main argument has been that while diffusion models always overestimate the true axon diameter, their estimation still correlates with changes in true value. Until now, this remains more as a discussion point. The aim of this paper is to clarify this hypothesis using a recently acquired cat spinal cord data set, where the diffusion MRI signal of both a multi-shell and Ax-Caliber acquisition have been registered with the underlying histology values. We find that the axon diameter as estimated by signal models and AxCaliber does not correlate with their true sizes for axon diameters smaller than 3 µm. On the other hand, we also train a random forest machine learning algorithm to map signal-based features to histology values of axon diameter and volume fraction. The results show that, in this dataset, this approach leads to a more reliable estimation of physically relevant axon diameters than using sophisticated diffusion models.

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评估使用扩散模型和机器学习估计轴突直径的可行性

轴突直径估计是过去十年来扩散核磁共振界关注的焦点。主要的论点是，虽然扩散模型总是高估真实轴突直径，但它们的估计仍然与真实值的变化相关。到目前为止，这还只是一个讨论点。本文的目的是利用最近获得的猫脊髓数据集来澄清这一假设，其中多壳和Ax-Caliber采集的弥散MRI信号已经与潜在的组织学值进行了登记。我们发现，当轴突直径小于3µm时，信号模型和AxCaliber估计的轴突直径与它们的真实尺寸不相关。另一方面，我们还训练了随机森林机器学习算法，将基于信号的特征映射到轴突直径和体积分数的组织学值。结果表明，在这个数据集中，这种方法比使用复杂的扩散模型更可靠地估计物理相关的轴突直径。

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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2017 IEEE 14th International Symposium on Biomedical Imaging (ISBI 2017)

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