将空间和频谱饱和模块整合到磁共振指纹识别中。

Incorporating Spatial and Spectral Saturation Modules Into MR Fingerprinting.

作者信息

Trimble Christopher G, Sørland Kaia I, Wu Chia-Yin, Riel Max H C van, Bathen Tone F, Elschot Mattijs, Cloos Martijn A

机构信息

Department of Circulation and Medical Imaging, Norwegian University of Science and Technology, Trondheim, Norway.

Department of Radiology and Nuclear Medicine, St. Olavs Hospital, Trondheim University Hospital, Trondheim, Norway.

出版信息

NMR Biomed. 2025 Mar;38(3):e70000. doi: 10.1002/nbm.70000.

DOI:10.1002/nbm.70000

PMID:39865307

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11771585/

Abstract

In this work, we introduce spatial and chemical saturation options for artefact reduction in magnetic resonance fingerprinting (MRF) and assess their impact on T and T mapping accuracy. An existing radial MRF pulse sequence was modified to enable spatial and chemical saturation. Phantom experiments were performed to demonstrate flow artefact reduction and evaluate the accuracy of the T and T maps. As an in vivo demonstration, MRF of the prostate was performed on an asymptomatic volunteer using saturation modules to reduce flow-related artefacts. T, T and B maps obtained with and without saturation modules were compared. Application of spatial saturation in prostate MRF reduced streaking artefacts from the femoral vessels. When saturation is enabled T accuracy is preserved, and T accuracy remains acceptable up to approximately 100 ms. Chemical and spatial saturation can be incorporated into MRF sequences with limited impact on T accuracy. Further sequence optimisation may be needed to accurately estimate long T components. Spatial saturation modules have potential in prostate MRF applications as a means to reduce flow-related artefacts.

摘要

在本研究中，我们引入了空间和化学饱和选项以减少磁共振指纹成像（MRF）中的伪影，并评估它们对T1和T2映射准确性的影响。对现有的径向MRF脉冲序列进行了修改，以实现空间和化学饱和。进行了体模实验，以证明流动伪影的减少，并评估T1和T2图的准确性。作为体内演示，对一名无症状志愿者的前列腺进行了MRF检查，使用饱和模块减少与流动相关的伪影。比较了使用和不使用饱和模块获得的T1、T2和B1图。在前列腺MRF中应用空间饱和减少了来自股血管的条纹伪影。启用饱和时，T1准确性得以保留，并且在大约100毫秒之前T2准确性仍然可以接受。化学和空间饱和可以纳入MRF序列，对T1准确性的影响有限。可能需要进一步的序列优化来准确估计长T2成分。空间饱和模块在前列腺MRF应用中具有潜力，可作为减少与流动相关伪影的一种手段。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cbd4/11771585/75a3327c2579/NBM-38-e70000-g005.jpg

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将空间和频谱饱和模块整合到磁共振指纹识别中。

Incorporating Spatial and Spectral Saturation Modules Into MR Fingerprinting.

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