MPRAGE：一种从多对比度梯度回波图像生成T1加权图像用于脑部分割的新方法。

MPRAGE: A novel approach to generate T1w images from multi-contrast gradient echo images for brain segmentation.

作者信息

Fortin Marc-Antoine, Stirnberg Rüdiger, Völzke Yannik, Lamalle Laurent, Pracht Eberhard, Löwen Daniel, Stöcker Tony, Goa Pål Erik

机构信息

Department of Physics, Norwegian University of Science and Technology, Trondheim, Trøndelag, Norway.

German Center for Neurodegenerative Diseases (DZNE), Bonn, Germany.

出版信息

Magn Reson Med. 2025 Jul;94(1):134-149. doi: 10.1002/mrm.30453. Epub 2025 Feb 4.

DOI:10.1002/mrm.30453

PMID:39902546

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12021339/

Abstract

PURPOSE

Brain segmentation and multi-parameter mapping (MPM) are important steps in neurodegenerative disease characterization. However, acquiring both a high-resolution T1w sequence like MPRAGE (standard input to brain segmentation) and an MPM in the same neuroimaging protocol increases scan time and patient discomfort, making it difficult to combine both in clinical examinations.

METHODS

A novel approach to synthesize T1w images from MPM images, named MPRAGE, is proposed and compared to the standard technique used to produce synthetic MPRAGE images (synMPRAGE). Twenty-three healthy subjects were scanned with the same imaging protocol at three different 7T sites using universal parallel transmit RF pulses. SNR, CNR, and automatic brain segmentation results from both MPRAGE and synMPRAGE were compared against an acquired MPRAGE.

RESULTS

The proposed MPRAGE technique produced higher SNR values than synMPRAGE for all regions evaluated while also having higher CNR values for subcortical structures. MPRAGE was still the image with the highest SNR values overall. For automatic brain segmentation, MPRAGE outperformed synMPRAGE when compared to MPRAGE (median Dice Similarity Coefficient of 0.90 versus 0.29 and Average Asymmetric Surface Distance of 0.33 versus 2.93 mm, respectively), in addition to being simple, flexible, and considerably more robust to low image quality than synMPRAGE.

CONCLUSION

The MPRAGE technique can provide a better and more reliable alternative to synMPRAGE as a substitute for MPRAGE, especially when automatic brain segmentation is of interest and scan time is limited.

摘要

目的

脑部分割和多参数映射（MPM）是神经退行性疾病特征描述中的重要步骤。然而，在同一神经成像方案中获取像MPRAGE（脑部分割的标准输入）这样的高分辨率T1加权序列和MPM会增加扫描时间和患者不适，使得在临床检查中难以将两者结合。

方法

提出了一种从MPM图像合成T1加权图像的新方法，命名为MPRAGE，并将其与用于生成合成MPRAGE图像（synMPRAGE）的标准技术进行比较。23名健康受试者在三个不同的7T站点使用通用并行发射射频脉冲，按照相同的成像方案进行扫描。将MPRAGE和synMPRAGE的信噪比（SNR）、对比度噪声比（CNR）以及自动脑部分割结果与采集的MPRAGE进行比较。

结果

对于所有评估区域，所提出的MPRAGE技术产生的SNR值均高于synMPRAGE，同时对于皮质下结构具有更高的CNR值。MPRAGE仍然是总体SNR值最高的图像。对于自动脑部分割，与MPRAGE相比，MPRAGE的表现优于synMPRAGE（中位骰子相似系数分别为0.90对0.29，平均不对称表面距离分别为0.33对2.93毫米），此外，它还简单、灵活，并且比synMPRAGE对低图像质量的耐受性更强。

结论

MPRAGE技术可以作为synMPRAGE的更好、更可靠的替代方案来替代MPRAGE，特别是在对自动脑部分割感兴趣且扫描时间有限的情况下。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fe29/12021339/450d4ad01aae/MRM-94-134-g003.jpg

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MPRAGE：一种从多对比度梯度回波图像生成T1加权图像用于脑部分割的新方法。

MPRAGE: A novel approach to generate T1w images from multi-contrast gradient echo images for brain segmentation.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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