Precise and rapid whole-head segmentation from magnetic resonance images of older adults using deep learning

Imaging Neuroscience Pub Date : 2024-02-01 DOI:10.1162/imag_a_00090

Skylar E. Stolte, A. Indahlastari, Jason Chen, Alejandro Albizu, Ayden L. Dunn, Samantha Pedersen, Kyle B. See, Adam J. Woods, Ruogu Fang

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Abstract

Abstract Whole-head segmentation from Magnetic Resonance Images (MRI) establishes the foundation for individualized computational models using finite element method (FEM). This foundation paves the path for computer-aided solutions in fields such as non-invasive brain stimulation. Most current automatic head segmentation tools are developed using healthy young adults. Thus, they may neglect the older population that is more prone to age-related structural decline such as brain atrophy. In this work, we present a new deep learning method called GRACE, which stands for General, Rapid, And Comprehensive whole-hEad tissue segmentation. GRACE is trained and validated on a novel dataset that consists of 177 manually corrected MR-derived reference segmentations that have undergone meticulous manual review. Each T1-weighted MRI volume is segmented into 11 tissue types, including white matter, grey matter, eyes, cerebrospinal fluid, air, blood vessel, cancellous bone, cortical bone, skin, fat, and muscle. To the best of our knowledge, this work contains the largest manually corrected dataset to date in terms of number of MRIs and segmented tissues. GRACE outperforms five freely available software tools and a traditional 3D U-Net on a five-tissue segmentation task. On this task, GRACE achieves an average Hausdorff Distance of 0.21, which exceeds the runner-up at an average Hausdorff Distance of 0.36. GRACE can segment a whole-head MRI in about 3 seconds, while the fastest software tool takes about 3 minutes. In summary, GRACE segments a spectrum of tissue types from older adults’ T1-MRI scans at favorable accuracy and speed. The trained GRACE model is optimized on older adult heads to enable high-precision modeling in age-related brain disorders. To support open science, the GRACE code and trained weights are made available online and open to the research community upon publication at https://github.com/lab-smile/GRACE.

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利用深度学习从老年人磁共振图像中精确快速地分割整个头部

摘要从磁共振成像（MRI）中对整个头部进行分割，为使用有限元法（FEM）建立个性化计算模型奠定了基础。这一基础为非侵入性脑部刺激等领域的计算机辅助解决方案铺平了道路。目前大多数自动头部分割工具都是利用健康的年轻人开发的。因此，它们可能会忽略老年人群，而老年人群更容易出现与年龄相关的结构衰退，如脑萎缩。在这项工作中，我们提出了一种名为 GRACE 的新型深度学习方法，它代表通用、快速和全面的全脑组织分割。GRACE 在一个新数据集上进行了训练和验证，该数据集由 177 个经过人工校正的磁共振衍生参考分割组成，这些参考分割都经过了细致的人工审核。每个 T1 加权磁共振成像容积被分割为 11 种组织类型，包括白质、灰质、眼球、脑脊液、空气、血管、松质骨、皮质骨、皮肤、脂肪和肌肉。据我们所知，就核磁共振成像和分割组织的数量而言，这项工作包含了迄今为止最大的人工校正数据集。在五组织分割任务中，GRACE 的表现优于五种免费提供的软件工具和传统的三维 U-Net。在这项任务中，GRACE 的平均豪斯多夫距离为 0.21，超过了平均豪斯多夫距离为 0.36 的亚军。GRACE 可在大约 3 秒钟内分割整个头部核磁共振成像，而最快的软件工具需要大约 3 分钟。总之，GRACE 能从老年人的 T1-MRI 扫描中分割出各种组织类型，准确度和速度都很高。训练有素的 GRACE 模型在老年人头部进行了优化，可对与年龄相关的脑部疾病进行高精度建模。为支持开放科学，GRACE 代码和训练过的权重可在线获取，并在 https://github.com/lab-smile/GRACE 上发布后向研究界开放。

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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Imaging Neuroscience

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