Medical Physics in Radiology, German Cancer Research Center (DKFZ), Heidelberg, Germany.
Faculty of Physics and Astronomy, Ruprecht-Karls University Heidelberg, Heidelberg, Germany.
Magn Reson Med. 2021 Nov;86(5):2412-2425. doi: 10.1002/mrm.28873. Epub 2021 Jun 1.
To develop a framework for 3D sodium ( Na) MR fingerprinting (MRF), based on irreducible spherical tensor operators with tailored flip angle (FA) pattern and time-efficient data acquisition for simultaneous quantification of T , , , and in addition to ΔB .
Na-MRF was implemented in a 3D sequence and irreducible spherical tensor operators were exploited in the simulations. Furthermore, the Cramér Rao lower bound was used to optimize the flip angle pattern. A combination of single and double echo readouts was implemented to increase the readout efficiency. A study was conducted to compare results in a multicompartment phantom acquired with MRF and reference methods. Finally, the relaxation times in the human brain were measured in four healthy volunteers.
Phantom experiments revealed a mean difference of 1.0% between relaxation times acquired with MRF and results determined with the reference methods. Simultaneous quantification of the longitudinal and transverse relaxation times in the human brain was possible within 32 min using 3D Na-MRF with a nominal resolution of (5 mm) . In vivo measurements in four volunteers yielded average relaxation times of: T = (35.0 ± 3.2) ms, = (29.3 ± 3.8) ms and = (5.5 ± 1.3) ms in brain tissue, whereas T = (61.9 ± 2.8) ms and = (46.3 ± 4.5) ms was found in cerebrospinal fluid.
The feasibility of in vivo 3D relaxometric sodium mapping within roughly ½ h is demonstrated using MRF in the human brain, moving sodium relaxometric mapping toward clinically relevant measurement times.
基于具有定制翻转角(FA)图案的不可约球形张量算子,为 3D 钠(Na)磁共振指纹成像(MRF)开发一个框架,并实现高效的数据采集,以便除 ΔB 外,还能同时定量 T 1 、T 2 、T 2 * 、 和 。
在 3D 序列中实现了 Na-MRF,并在模拟中利用不可约球形张量算子。此外,还使用克拉美罗下界优化了翻转角图案。采用单回波和双回波读取的组合来提高读取效率。进行了一项研究,比较了在多腔室体模中使用 MRF 和参考方法获得的结果。最后,在四名健康志愿者中测量了人脑的弛豫时间。
体模实验显示,使用 MRF 获得的弛豫时间与参考方法的结果之间存在 1.0%的平均差异。使用具有(5mm)名义分辨率的 3D Na-MRF 可以在 32 分钟内实现人脑的纵向和横向弛豫时间的同时定量。在四名志愿者的体内测量中,得到的平均弛豫时间为:脑组织中的 T =(35.0 ± 3.2)ms,T 2 =(29.3 ± 3.8)ms 和 T 2 * =(5.5 ± 1.3)ms,而脑脊液中的 T =(61.9 ± 2.8)ms 和 T 1 =(46.3 ± 4.5)ms。
在人体大脑中使用 MRF 证明了在大约半小时内进行体内 3D 弛豫时间 Na 映射的可行性,使 Na 弛豫时间映射朝着临床相关的测量时间迈进。
