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心脏电影磁共振指纹技术用于联合射血分数、T 值和 T* 值定量测量。

Cardiac cine magnetic resonance fingerprinting for combined ejection fraction, T and T quantification.

机构信息

Department of Radiology, University of Michigan, Ann Arbor, Michigan, USA.

Department of Biomedical Engineering, Case Western Reserve University, Cleveland, Ohio, USA.

出版信息

NMR Biomed. 2020 Aug;33(8):e4323. doi: 10.1002/nbm.4323. Epub 2020 Jun 5.

DOI:10.1002/nbm.4323
PMID:32500541
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7772953/
Abstract

This study introduces a technique called cine magnetic resonance fingerprinting (cine-MRF) for simultaneous T , T and ejection fraction (EF) quantification. Data acquired with a free-running MRF sequence are retrospectively sorted into different cardiac phases using an external electrocardiogram (ECG) signal. A low-rank reconstruction with a finite difference sparsity constraint along the cardiac motion dimension yields images resolved by cardiac phase. To improve SNR and precision in the parameter maps, these images are nonrigidly registered to the same phase and matched to a dictionary to generate T and T maps. Cine images for computing left ventricular volumes and EF are also derived from the same data. Cine-MRF was tested in simulations using a numerical relaxation phantom. Phantom and in vivo scans of 19 subjects were performed at 3 T during a 10.9 seconds breath-hold with an in-plane resolution of 1.6 x 1.6 mm and 24 cardiac phases. Left ventricular EF values obtained with cine-MRF agreed with the conventional cine images (mean bias -1.0%). Average myocardial T times in diastole/systole were 1398/1391 ms with cine-MRF, 1394/1378 ms with ECG-triggered cardiac MRF (cMRF) and 1234/1212 ms with MOLLI; and T values were 30.7/30.3 ms with cine-MRF, 32.6/32.9 ms with ECG-triggered cMRF and 37.6/41.0 ms with T -prepared FLASH. Cine-MRF and ECG-triggered cMRF relaxation times were in good agreement. Cine-MRF T values were significantly longer than MOLLI, and cine-MRF T values were significantly shorter than T -prepared FLASH. In summary, cine-MRF can potentially streamline cardiac MRI exams by combining left ventricle functional assessment and T -T mapping into one time-efficient acquisition.

摘要

本研究介绍了一种称为电影磁共振指纹识别(cine-MRF)的技术,用于同时定量 T 1 、 T 2 和射血分数(EF)。使用自由运行的 MRF 序列采集的数据使用外部心电图(ECG)信号回溯地分为不同的心脏相位。使用沿心脏运动维度的有限差分稀疏约束进行低秩重建,可生成按心脏相位分辨的图像。为了提高参数图中的 SNR 和精度,将这些图像非刚性地注册到同一相位,并与字典匹配以生成 T 1 和 T 2 图。还从相同数据中得出用于计算左心室容积和 EF 的电影图像。cine-MRF 在使用数值弛豫体模的模拟中进行了测试。在 3 T 下,19 名受试者在 10.9 秒的屏气期间进行了体模和体内扫描,平面分辨率为 1.6 x 1.6 mm,共 24 个心脏相位。cine-MRF 获得的左心室 EF 值与常规 cine 图像一致(平均偏差为-1.0%)。cine-MRF 的舒张/收缩期心肌 T 1 时间分别为 1398/1391 ms,ECG 触发的心脏 MRF(cMRF)为 1394/1378 ms,MOLLI 为 1234/1212 ms;cine-MRF 的 T 1 值为 30.7/30.3 ms,ECG 触发的 cMRF 为 32.6/32.9 ms,T 1 准备的 FLASH 为 37.6/41.0 ms。cine-MRF 和 ECG 触发的 cMRF 弛豫时间具有良好的一致性。cine-MRF 的 T 1 值明显长于 MOLLI,而 cine-MRF 的 T 1 值明显短于 T 1 准备的 FLASH。总之,cine-MRF 可以通过将左心室功能评估和 T 1 -T 2 映射结合到一个高效的采集过程中,有可能简化心脏 MRI 检查。

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