基于深度学习的脑MRI血管周围间隙扩大检测

Q4 Neuroscience
Tanweer Rashid , Hangfan Liu , Jeffrey B. Ware , Karl Li , Jose Rafael Romero , Elyas Fadaee , Ilya M. Nasrallah , Saima Hilal , R. Nick Bryan , Timothy M. Hughes , Christos Davatzikos , Lenore Launer , Sudha Seshadri , Susan R. Heckbert , Mohamad Habes
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引用次数: 0

摘要

深度学习已被证明在许多神经成像应用中是有效的。然而,在许多情况下,捕获与小血管疾病病变相关信息的成像序列数量不足以支持数据驱动技术。此外,基于队列的研究可能并不总是具有用于精确病变检测的最佳或必要的成像序列。因此,有必要确定哪些成像序列对精确检测至关重要。本研究引入了一种深度学习框架来检测扩大的血管周围间隙(ePVS),旨在为基于深度学习的量化找到MRI序列的最佳组合。我们实现了一种适用于ePVS检测的有效的轻量级U-Net,并全面研究了来自SWI、FLAIR、T1加权(T1w)和T2加权(T2w)MRI序列的不同信息组合。实验结果表明T2w MRI对于准确检测ePVS是最重要的,深度神经网络中的FLAIR和T1w MRI在准确性上有微小的改进,并产生了最高的灵敏度和精度(灵敏度=0.82,精度=0.83)。与手动读取相比,所提出的方法以最小的时间成本实现了相当的精度。所提出的自动化流水线能够从MR扫描中稳健且高效地读取ePVS,并证明了T2w MRI对ePVS检测的重要性以及使用多模式图像的潜在好处。此外,该模型提供了ePVS的全脑图谱,与仅在几个大脑区域内的临床评级方法相比,能够更好地了解其临床相关性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep learning based detection of enlarged perivascular spaces on brain MRI

Deep learning has been demonstrated effective in many neuroimaging applications. However, in many scenarios, the number of imaging sequences capturing information related to small vessel disease lesions is insufficient to support data-driven techniques. Additionally, cohort-based studies may not always have the optimal or essential imaging sequences for accurate lesion detection. Therefore, it is necessary to determine which imaging sequences are crucial for precise detection. This study introduces a deep learning framework to detect enlarged perivascular spaces (ePVS) and aims to find the optimal combination of MRI sequences for deep learning-based quantification. We implemented an effective lightweight U-Net adapted for ePVS detection and comprehensively investigated different combinations of information from SWI, FLAIR, T1-weighted (T1w), and T2-weighted (T2w) MRI sequences. The experimental results showed that T2w MRI is the most important for accurate ePVS detection, and the incorporation of SWI, FLAIR and T1w MRI in the deep neural network had minor improvements in accuracy and resulted in the highest sensitivity and precision (sensitivity = 0.82, precision = 0.83). The proposed method achieved comparable accuracy at a minimal time cost compared to manual reading. The proposed automated pipeline enables robust and time-efficient readings of ePVS from MR scans and demonstrates the importance of T2w MRI for ePVS detection and the potential benefits of using multimodal images. Furthermore, the model provides whole-brain maps of ePVS, enabling a better understanding of their clinical correlates compared to the clinical rating methods within only a couple of brain regions.

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来源期刊
Neuroimage. Reports
Neuroimage. Reports Neuroscience (General)
CiteScore
1.90
自引率
0.00%
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0
审稿时长
87 days
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