用于肌肉组织高时间分辨率弛豫时间定量的螺旋磁共振指纹图谱中的水脂分离

Water-fat separation in spiral magnetic resonance fingerprinting for high temporal resolution tissue relaxation time quantification in muscle.

作者信息

Koolstra Kirsten, Webb Andrew G, Veeger Thom T J, Kan Hermien E, Koken Peter, Börnert Peter

机构信息

C.J. Gorter Center for High Field MRI, Radiology, Leiden University Medical Center, Leiden, Netherlands.

Philips Research, Hamburg, Germany.

出版信息

Magn Reson Med. 2020 Aug;84(2):646-662. doi: 10.1002/mrm.28143. Epub 2020 Jan 3.

DOI:10.1002/mrm.28143

PMID:31898834

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7217066/

Abstract

PURPOSE

To minimize the known biases introduced by fat in rapid T and T quantification in muscle using a single-run magnetic resonance fingerprinting (MRF) water-fat separation sequence.

METHODS

The single-run MRF acquisition uses an alternating in-phase/out-of-phase TE pattern to achieve water-fat separation based on a 2-point DIXON method. Conjugate phase reconstruction and fat deblurring were applied to correct for B inhomogeneities and chemical shift blurring. Water and fat signals were matched to the on-resonance MRF dictionary. The method was first tested in a multicompartment phantom. To test whether the approach is capable of measuring small in vivo dynamic changes in relaxation times, experiments were run in 9 healthy volunteers; parameter values were compared with and without water-fat separation during muscle recovery after plantar flexion exercise.

RESULTS

Phantom results show the robustness of the water-fat resolving MRF approach to undersampling. Parameter maps in volunteers show a significant (P < .01) increase in T (105 ± 94 ms) and decrease in T (14 ± 6 ms) when using water-fat-separated MRF, suggesting improved parameter quantification by reducing the well-known biases introduced by fat. Exercise results showed smooth T and T recovery curves.

CONCLUSION

Water-fat separation using conjugate phase reconstruction is possible within a single-run MRF scan. This technique can be used to rapidly map relaxation times in studies requiring dynamic scanning, in which the presence of fat is problematic.

摘要

目的

使用单次磁共振指纹（MRF）水脂分离序列，尽量减少肌肉快速T1和T2定量中脂肪引入的已知偏差。

方法

单次MRF采集采用交替同相/异相TE模式，基于两点DIXON方法实现水脂分离。应用共轭相位重建和脂肪去模糊来校正B不均匀性和化学位移模糊。水和脂肪信号与共振MRF字典匹配。该方法首先在多隔室模型中进行测试。为了测试该方法是否能够测量体内弛豫时间的小动态变化，对9名健康志愿者进行了实验；在跖屈运动后的肌肉恢复过程中，比较了有无水脂分离时的参数值。

结果

模型结果显示了水脂分辨MRF方法对欠采样的鲁棒性。志愿者的参数图显示，使用水脂分离的MRF时，T1显著增加（105±94毫秒），T2显著降低（14±6毫秒）（P<.01），这表明通过减少脂肪引入的已知偏差，参数定量得到了改善。运动结果显示了平滑的T1和T2恢复曲线。

结论

在单次MRF扫描中使用共轭相位重建进行水脂分离是可行的。该技术可用于在需要动态扫描且脂肪存在问题的研究中快速绘制弛豫时间图。

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用于肌肉组织高时间分辨率弛豫时间定量的螺旋磁共振指纹图谱中的水脂分离

Water-fat separation in spiral magnetic resonance fingerprinting for high temporal resolution tissue relaxation time quantification in muscle.

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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