使用并行化的多网络U-Net卷积神经网络从仅幅度的磁共振成像数据中合成磁共振指纹信息。

Synthesis of MR fingerprinting information from magnitude-only MR imaging data using a parallelized, multi network U-Net convolutional neural network.

作者信息

McGee Kiaran P, Sui Yi, Witte Robert J, Panda Ananya, Campeau Norbert G, Mostardeiro Thomaz R, Sobh Nahil, Ravaioli Umberto, Zhang Shuyue Lucia, Falahkheirkhah Kianoush, Larson Nicholas B, Schwarz Christopher G, Gunter Jeffrey L

机构信息

Department of Radiology, Mayo Clinic, Rochester, MN, United States.

Department of Radiology, University of Iowa, Iowa City, IA, United States.

出版信息

Front Radiol. 2024 Dec 16;4:1498411. doi: 10.3389/fradi.2024.1498411. eCollection 2024.

DOI:10.3389/fradi.2024.1498411

PMID:39742349

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11686891/

Abstract

BACKGROUND

MR fingerprinting (MRF) is a novel method for quantitative assessment of MR relaxometry that has shown high precision and accuracy. However, the method requires data acquisition using customized, complex acquisition strategies and dedicated post processing methods thereby limiting its widespread application.

OBJECTIVE

To develop a deep learning (DL) network for synthesizing MRF signals from conventional magnitude-only MR imaging data and to compare the results to the actual MRF signal acquired.

METHODS

A U-Net DL network was developed to synthesize MRF signals from magnitude-only 3D -weighted brain MRI data acquired from 37 volunteers aged between 21 and 62 years of age. Network performance was evaluated by comparison of the relaxometry data ( , ) generated from dictionary matching of the deep learning synthesized and actual MRF data from 47 segmented anatomic regions. Clustered bootstrapping involving 10,000 bootstraps followed by calculation of the concordance correlation coefficient were performed for both and MRF data pairs. 95% confidence limits and the mean difference between true and DL relaxometry values were also calculated.

RESULTS

The concordance correlation coefficient (and 95% confidence limits) for and MRF data pairs over the 47 anatomic segments were 0.8793 (0.8136-0.9383) and 0.9078 (0.8981-0.9145) respectively. The mean difference (and 95% confidence limits) were 48.23 (23.0-77.3) s and 2.02 (-1.4 to 4.8) s.

CONCLUSION

It is possible to synthesize MRF signals from MRI data using a DL network, thereby creating the potential for performing quantitative relaxometry assessment without the need for a dedicated MRF pulse sequence.

摘要

背景

磁共振指纹成像（MRF）是一种用于定量评估磁共振弛豫测量的新方法，已显示出高精度和准确性。然而，该方法需要使用定制的、复杂的采集策略和专用的后处理方法来采集数据，从而限制了其广泛应用。

目的

开发一种深度学习（DL）网络，用于从传统的仅幅度磁共振成像数据中合成MRF信号，并将结果与实际采集的MRF信号进行比较。

方法

开发了一个U-Net DL网络，以从37名年龄在21至62岁之间的志愿者获取的仅幅度三维加权脑MRI数据中合成MRF信号。通过比较从深度学习合成的和实际MRF数据的字典匹配中生成的弛豫测量数据（T1、T2），对47个分割的解剖区域进行网络性能评估。对T1和T2 MRF数据对进行了涉及10000次自举的聚类自举，随后计算一致性相关系数。还计算了真实值与DL弛豫测量值之间的95%置信限和平均差异。

结果

47个解剖段上T1和T2 MRF数据对的一致性相关系数（及95%置信限）分别为0.8793（0.8136 - 0.9383）和0.9078（0.8981 - 0.9145）。平均差异（及95%置信限）分别为48.23（23.0 - 77.3）s和2.02（-1.4至4.8）s。

结论

使用DL网络从MRI数据中合成MRF信号是可行的，从而为无需专用MRF脉冲序列进行定量弛豫测量评估创造了潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1fee/11686891/5b9fd97a945c/fradi-04-1498411-g001.jpg

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使用并行化的多网络U-Net卷积神经网络从仅幅度的磁共振成像数据中合成磁共振指纹信息。

Synthesis of MR fingerprinting information from magnitude-only MR imaging data using a parallelized, multi network U-Net convolutional neural network.

作者信息

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出版信息

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OBJECTIVE

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RESULTS

CONCLUSION

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方法

结果

结论

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