Denecken Esteban, Arrieta Cristóbal, Hernando Diego, Sotelo Julio, Mella Hernán, Uribe Sergio
Biomedical Imaging Center, Pontificia Universidad Católica de Chile, Santiago, Chile; Department of Electrical Engineering, School of Engineering, Pontificia Universidad Católica de Chile, Santiago, Chile.
Faculty of Engineering, Universidad Alberto Hurtado, Santiago, Chile.
Magn Reson Imaging. 2025 May;118:110341. doi: 10.1016/j.mri.2025.110341. Epub 2025 Jan 31.
Phase-contrast MRI (2D PC-MRI) and Dixon techniques share the characteristic that the difference in frequency between water and fat, as well as the velocity, are encoded in the phase of the MR signal. We propose to take advantage of this characteristic to obtain both sets of images simultaneously. Such an acquisition will improve efficiency by obtaining both types of images in the same scan and will provide co-registered images of water-fat species and velocity images. This, in turn, will correct fat artifacts due to chemical shift in PC-MRI based measurements.
This study presents a novel PC multi-echo (PCME-MRI) sequence jointly with a 3-point (3p-) Dixon pipeline that enables reconstruction of water, fat, and velocity images simultaneously. The proposed 3p-Dixon approach preserves the phase information of water-fat images, while velocity images are obtained from the resulting water components.
Numerical phantom tests and 2D MR axial images of the neck acquired in 12 healthy volunteers demonstrated the feasibility of the PC 3p-Dixon method, showing comparable performance to standard techniques. In volunteers the median and range MAE comparing PC 3p-Dixon, and standard 3p-Dixon fat fraction were 0.06 and [0.03, 0.09]. The median and range of velocity for PC 3p-Dixon were 6.15 ml and [3.86, 7.21]ml, compared to 6.43 ml and [4.62, 8.27]ml obtained by 2D PC-MRI.
Numerical phantom experiments and acquisitions from healthy volunteers showed promising results in fat fraction and velocity estimation of PC 3p-Dixon compared with standard 3p-Dixon and 2D PC-MRI, obtaining both data sets in similar times as standard 3p Dixon.
相位对比磁共振成像(二维PC-MRI)和狄克逊技术具有共同特点,即水和脂肪之间的频率差异以及速度都编码在磁共振信号的相位中。我们建议利用这一特性同时获取两组图像。这样的采集方式将通过在同一次扫描中获取两种类型的图像来提高效率,并提供水脂成分的配准图像和速度图像。这反过来将校正基于PC-MRI测量中由于化学位移引起的脂肪伪影。
本研究提出了一种新颖的PC多回波(PCME-MRI)序列以及一个三点(3p-)狄克逊流程,能够同时重建水、脂肪和速度图像。所提出的3p-狄克逊方法保留了水脂图像的相位信息,而速度图像则从所得的水成分中获取。
数值模拟测试以及在12名健康志愿者身上采集的颈部二维磁共振轴向图像证明了PC 3p-狄克逊方法的可行性,其表现与标准技术相当。在志愿者中,比较PC 3p-狄克逊和标准3p-狄克逊脂肪分数的平均绝对误差(MAE)中位数和范围分别为0.06和[0.03, 0.09]。PC 3p-狄克逊的速度中位数和范围为6.15毫升和[3.86, 7.21]毫升,而二维PC-MRI获得的速度分别为6.43毫升和[4.62, 8.27]毫升。
与标准3p-狄克逊和二维PC-MRI相比,数值模拟实验以及对健康志愿者的采集结果表明,PC 3p-狄克逊在脂肪分数和速度估计方面取得了有前景的结果,且获取两组数据集的时间与标准3p狄克逊相近。
