使用部分射频失相梯度回波的弛豫时间和磁化率的三维多参数映射。

Three-dimensional Multi-parameter Mapping of Relaxation Times and Susceptibility Using Partially RF-spoiled Gradient Echo.

机构信息

Innovative Technology Laboratory, FUJIFILM Healthcare Corporation.

FUJIFILM Healthcare Corporation.

出版信息

Magn Reson Med Sci. 2023 Oct 1;22(4):459-468. doi: 10.2463/mrms.mp.2021-0045. Epub 2022 Jul 30.

DOI:10.2463/mrms.mp.2021-0045

PMID:35908880

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10552665/

Abstract

PURPOSE

MR parameter mapping is a technique that obtains distributions of parameters such as relaxation time and proton density (PD) and is starting to be used for disease quantification in clinical diagnoses. Quantitative susceptibility mapping is also promising for the early diagnosis of brain disorders such as degenerative neurological disorders. Therefore, we developed an MR quantitative parameter mapping (QPM) method to map four tissue-related parameters (T, T*, PD, and susceptibility) and B simultaneously by using a 3D partially RF-spoiled gradient echo (pRSGE). We verified the accuracy and repeatability of QPM in phantom and volunteer experiments.

METHODS

Tissue-related parameters are estimated by varying four scan parameters of the 3D pRSGE: flip angle, RF-pulse phase increment, TR and TE, performing multiple image scans, and finding a least-squares fit for an intensity function (which expresses the relationship between the scan parameters and intensity values). The intensity function is analytically complex, but by using a Bloch simulation to create it numerically, the least-squares fitting can be used to estimate the quantitative values. This has the advantage of shortening the image-reconstruction processing time needed to estimate the quantitative values than with methods using pattern matching.

RESULTS

A 1.1-mm isotropic resolution scan covering the whole brain was completed with a scan time of approximately 12 minutes, and the reconstruction time using a GPU was approximately 1 minute. The phantom experiments confirmed that both the accuracy and repeatability of the quantitative values were high. The volunteer scans also confirmed that the accuracy of the quantitative values was comparable to that of conventional methods.

CONCLUSION

The proposed QPM method can map T, T*, PD, susceptibility, and B simultaneously within a scan time that can be applied to human subjects.

摘要

目的

磁共振参数图是一种获取弛豫时间和质子密度（PD）等参数分布的技术，它开始被用于临床诊断中的疾病定量。定量磁化率图也有望用于早期诊断脑退行性神经病变等疾病。因此，我们开发了一种磁共振定量参数映射（QPM）方法，通过使用三维部分射频失谐梯度回波（pRSGE）同时映射四个组织相关参数（T、T*、PD 和磁化率）和 B。我们在体模和志愿者实验中验证了 QPM 的准确性和可重复性。

方法

通过改变 3D pRSGE 的四个扫描参数：翻转角、RF 脉冲相位增量、TR 和 TE，进行多次图像扫描，并对强度函数（表示扫描参数与强度值之间的关系）进行最小二乘拟合，来估计组织相关参数。强度函数解析复杂，但通过使用布洛赫模拟对其进行数值化创建，可以使用最小二乘法来估计定量值。与使用模式匹配的方法相比，这具有缩短估计定量值所需的图像重建处理时间的优势。

结果

使用约 12 分钟的扫描时间完成了覆盖整个大脑的 1.1 毫米各向同性分辨率扫描，使用 GPU 的重建时间约为 1 分钟。体模实验证实了定量值的准确性和重复性都很高。志愿者扫描也证实了定量值的准确性与传统方法相当。

结论

所提出的 QPM 方法可以在适用于人体的扫描时间内同时映射 T、T*、PD、磁化率和 B。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9c4a/10552665/472afe47f200/mrms-22-459-g1.jpg

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使用部分射频失相梯度回波的弛豫时间和磁化率的三维多参数映射。

Three-dimensional Multi-parameter Mapping of Relaxation Times and Susceptibility Using Partially RF-spoiled Gradient Echo.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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