Sodium quantification in skeletal muscle: comparison between Cartesian gradient-echo and radial ultra-short echo time 23Na MRI techniques.

IF 3.7 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Teresa Gerhalter, Felix Schilling, Nour Zeitouni, Peter Linz, Pierre-Yves Baudin, Dennis Kannenkeril, Christoph Kopp, Anke Dahlmann, Roland Schmieder, Michael Uder, Armin M Nagel, Lena V Gast
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引用次数: 0

Abstract

Background: Clinical magnetic resonance imaging (MRI) studies often use Cartesian gradient-echo (GRE) sequences with ~2-ms echo times (TEs) to monitor apparent total sodium concentration (aTSC). We compared Cartesian GRE and ultra-short echo time three-dimensional (3D) radial-readout sequences for measuring skeletal muscle aTSC.

Methods: We retrospectively evaluated 211 datasets from 112 volunteers aged 62.3 ± 12.1 years (mean ± standard deviation), acquired at 3 T from the lower leg. For 23Na MRI acquisitions, we used a two-dimensional Cartesian GRE sequence and a density-adapted 3D radial readout sequence with cuboid field-of-view (DA-3D-RAD-C). We calibrated the 23Na MR signal using reference tubes either with or without agarose and subsequently performed a relaxation correction. Additionally, we employed a six-echo 1H GRE sequence and a multi-echo spin-echo sequence to calculate proton density fat fraction (PDFF) and water T2. Paired Wilcoxon signed-rank test, Cohen dz for paired samples, and Spearman correlation were used.

Results: Relaxation correction effectively reduced the differences in muscle aTSC between the two acquisition and calibration methods (DA-3D-RAD-C using NaCl/agarose references: 20.05 versus 19.14 mM; dz = 0.395; Cartesian GRE using NaCl/agarose references: 19.50 versus 18.82 mM; dz = 0.427). Both aTSC of the DA-3D-RAD-C and Cartesian GRE acquisitions showed a small but significant correlation with PDFF as well as with water T2.

Conclusions: Different 23Na MRI acquisition and calibration approaches affect aTSC values. Applying relaxation correction is advised to minimize the impact of sequence parameters on quantification, and considering additional fat correction is advisable for patients with increased fat fractions.

Relevance statement: This study highlights relaxation correction's role in improving sodium MRI accuracy, paving the way for better disease assessment and comparability of measured sodium signal in patients.

Key points: • Differences in MRI acquisition methods hamper the comparability of sodium MRI measurements. • Measured sodium values depend on used MRI sequences and calibration method. • Relaxation correction during postprocessing mitigates these discrepancies. • Thus, relaxation correction enhances accuracy of sodium MRI, aiding its clinical use.

Abstract Image

骨骼肌中钠的定量:直角坐标梯度回波和径向超短回波时间 23Na 磁共振成像技术的比较。
背景:临床磁共振成像(MRI)研究通常使用回波时间(TE)约为 2 毫秒的笛卡尔梯度回波(GRE)序列来监测表观总钠浓度(aTSC)。我们比较了笛卡尔 GRE 序列和超短回波时间三维(3D)径向读出序列在测量骨骼肌 aTSC 方面的应用:我们回顾性评估了 112 名志愿者的 211 个数据集,这些志愿者的年龄为 62.3 ± 12.1 岁(平均 ± 标准差),在 3 T 下从小腿采集数据。在 23Na MRI 采集中,我们使用了二维笛卡尔 GRE 序列和密度适配的三维径向读出序列与立方体视场(DA-3D-RAD-C)。我们使用含或不含琼脂糖的参照管校准 23Na MR 信号,然后进行弛豫校正。此外,我们还采用了六回波 1H GRE 序列和多回波自旋回波序列来计算质子密度脂肪分数(PDFF)和水 T2。我们采用了配对 Wilcoxon 符号秩检验、配对样本 Cohen dz 检验和 Spearman 相关检验:结果:弛豫校正有效减少了两种采集和校准方法之间肌肉 aTSC 的差异(DA-3D-RAD-C 使用 NaCl/agarose 参考,20.05 对 19.14):20.05 对 19.14 mM;dz = 0.395;笛卡尔 GRE 使用 NaCl/agarose 作为参考:19.50 与 18.82 毫摩尔;dz = 0.427)。DA-3D-RAD-C 和笛卡尔 GRE 采集的 aTSC 均与 PDFF 以及水 T2 存在微小但显著的相关性:不同的 23Na MRI 采集和校准方法会影响 aTSC 值。建议应用弛豫校正,以尽量减少序列参数对量化的影响,对于脂肪分数增加的患者,建议考虑额外的脂肪校正:本研究强调了弛豫校正在提高钠核磁共振成像准确性方面的作用,为更好地评估疾病和患者钠信号测量的可比性铺平了道路:- 关键点:磁共振成像采集方法的差异阻碍了钠磁共振成像测量的可比性。- 钠的测量值取决于所使用的 MRI 序列和校准方法。- 后处理过程中的松弛校正可减轻这些差异。- 因此,松弛校正提高了钠磁共振成像的准确性,有助于其临床应用。
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来源期刊
European Radiology Experimental
European Radiology Experimental Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
6.70
自引率
2.60%
发文量
56
审稿时长
18 weeks
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