通过稳态磁共振波谱成像对31P线圈进行翻转角映射。

Flip-angle mapping of 31P coils by steady-state MR spectroscopic imaging.

作者信息

Chmelík Marek, Považan Michal, Jírů Filip, Just Kukurová Ivica, Dezortová Monika, Krššák Martin, Bogner Wolfgang, Hájek Milan, Trattnig Siegfried, Valkovič Ladislav

机构信息

MR Centre of Excellence, Department of Biomedical Imaging and Image-guided Therapy, Medical University of Vienna, Vienna, Austria.

出版信息

J Magn Reson Imaging. 2014 Aug;40(2):391-7. doi: 10.1002/jmri.24401. Epub 2013 Nov 4.

DOI:10.1002/jmri.24401

PMID:24925600

Abstract

PURPOSE

Phosphorus ((31)P) MR spectroscopic imaging (MRSI) is primarily applied with sensitive, surface radiofrequency (RF) coils that provide inhomogeneous excitation RF field (B1(+)) and rough localization due to their B1(+) and sensitivity (B1(-)) profiles. A careful and time-consuming pulse adjustment and an accurate knowledge of flip angle (FA) are mandatory for quantification corrections.

MATERIALS AND METHODS

In this study, a simple, fast, and universal (31)P B1(+) mapping method is proposed, which requires fast steady-state MRSI (typically one sixth of normal measurement time) in addition to the typical MRSI acquired within the examination protocol. The FA maps are calculated from the ratio of the signal intensities acquired by these two measurements and were used to correct for the influence of B1(+) on the metabolite maps.

RESULTS

In vitro tests were performed on two scanners (3 and 7 Tesla) using a surface and a volume coil. The calculated FA maps were in good agreement with adjusted nominal FAs and the theoretical calculation using the Biot-Savart law. The method was successfully tested in vivo in the calf muscle and the brain of healthy volunteers (n = 4). The corrected metabolite maps show higher homogeneity compared with their noncorrected versions.

CONCLUSION

The calculated FA maps helped with B1(+) inhomogeneity corrections of acquired in vivo data, and should also be useful with optimization and testing of pulse performances, or with the construction quality tests of new dual-channel (1)H/(31)P coils.

摘要

目的

磷（³¹P）磁共振波谱成像（MRSI）主要使用灵敏的表面射频（RF）线圈，这些线圈会提供不均匀的激发射频场（B1⁺），并且由于其B1⁺和灵敏度（B1⁻）分布而导致定位粗略。为了进行定量校正，必须进行仔细且耗时的脉冲调整以及准确了解翻转角（FA）。

材料与方法

在本研究中，提出了一种简单、快速且通用的³¹P B1⁺映射方法，除了在检查方案中获取的典型MRSI外，该方法还需要快速稳态MRSI（通常为正常测量时间的六分之一）。FA图由这两次测量获取的信号强度之比计算得出，并用于校正B1⁺对代谢物图的影响。

结果

使用表面线圈和体线圈在两台扫描仪（3特斯拉和7特斯拉）上进行了体外测试。计算得到的FA图与调整后的标称FA以及使用毕奥 - 萨伐尔定律的理论计算结果高度吻合。该方法在健康志愿者（n = 4）的小腿肌肉和大脑中进行了成功的体内测试。校正后的代谢物图与其未校正版本相比显示出更高的均匀性。

结论

计算得到的FA图有助于对采集的体内数据进行B1⁺不均匀性校正，并且在脉冲性能的优化和测试，或新型双通道¹H/³¹P线圈的构建质量测试中也应有用。

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通过稳态磁共振波谱成像对31P线圈进行翻转角映射。

Flip-angle mapping of 31P coils by steady-state MR spectroscopic imaging.

作者信息

机构信息

出版信息

PURPOSE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料与方法

结果

结论

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