最佳平面选择用于测量肠系膜上动脉餐后血流增加：使用 4D 流和计算流体动力学进行分析。

Optimal Plane Selection for Measuring Post-prandial Blood Flow Increase within the Superior Mesenteric Artery: Analysis Using 4D Flow and Computational Fluid Dynamics.

机构信息

Department of Fundamental Development for Advanced Low Invasive Diagnostic Imaging, Nagoya University Graduate School of Medicine.

Department of Radiological Technology, Hamamatsu University Hospital.

出版信息

Magn Reson Med Sci. 2020 Dec 1;19(4):366-374. doi: 10.2463/mrms.mp.2019-0089. Epub 2020 Jan 31.

DOI:10.2463/mrms.mp.2019-0089

PMID:32009062

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7809144/

Abstract

PURPOSE

2D cine phase contrast (PC)-MRI is a standard velocimetry for the superior mesenteric artery (SMA); however, the optimal localization of the measurement plane has never been fully discussed previously. The purpose of this Institutional Review Board approved prospective and single arm study is to test whether flow velocimetry of the SMA with combined use of 2D cine PC-MRI and meal challenge is dependent on the localizations of the measurement planes and to seek optimal section for velocimetry.

METHODS

Seven healthy volunteers underwent cardiac phase resolved ECG gated 2D cine PC-MRI pre- and 30 min post-meal challenge at three measurement planes: proximal, curved mid section and distal straight section of the SMA at 3T. 4D Flow using 3D cine PC-MRI with vastly undersampled isotropic projection imaging (PC VIPR) was also performed right after 2D cine PC-MRI to delineate the flow dynamics within the SMA using streamline analysis. Two radiologists measured flow velocities, and rated the appearances of the abnormal flow in the SMA on streamlines derived from the 4D Flow and the computational fluid dynamics (CFD).

RESULTS

2D cine PC-MRI measured increased temporally averaged flow velocity (mm/s) after the meal challenge only in the proximal (129.3 vs. 97.8, P = 0.0313) and distal section (166.9 vs. 96.2, P = 0.0313), not in the curved mid section (113.1 vs. 85.5, P = 0.0625). The average velocities were highest and their standard errors (8.5-26.5) were smallest at the distal straight section both before and after the meal challenge as compared with other sections. The streamline analysis depicted more frequent appearances of vertical or helical flow in the curved mid section both on 4D Flow and CFD (κ: 0.27-0.68).

CONCLUSION

SMA velocimetry with 2D cine PC-MRI was dependent on the localization of the measurement planes. Distal straight section, not in the curved mid section is recommended for MR velocimetry.

摘要

目的

2D 电影相位对比（PC）-MRI 是肠系膜上动脉（SMA）的标准速度测量方法；然而，测量平面的最佳定位以前从未得到充分讨论。本机构审查委员会批准的前瞻性单臂研究的目的是测试 SMA 的 2D 电影 PC-MRI 和餐挑战联合使用时的流量速度是否取决于测量平面的定位，并寻找最佳的速度测量截面。

方法

七名健康志愿者在 3T 下进行了三个测量平面的心脏相位分辨心电图门控 2D 电影 PC-MRI 扫描：SMA 的近端、弯曲中段和远端直段。在 2D 电影 PC-MRI 之后，还使用 3D 电影 PC-MRI 与大欠采样各向同性投影成像（PC VIPR）进行 4D Flow 扫描，以流线分析描绘 SMA 内的流动动力学。两名放射科医生测量了血流速度，并根据 4D Flow 和计算流体动力学（CFD）得出的流线评估 SMA 中异常血流的外观。

结果

2D 电影 PC-MRI 仅在近端（129.3 对 97.8，P = 0.0313）和远端（166.9 对 96.2，P = 0.0313）测量到餐后时间平均流速增加（mm/s），而在弯曲中段（113.1 对 85.5，P = 0.0625）没有增加。与其他截面相比，近端和远端直段的平均速度最高，餐后和餐前的标准误差（8.5-26.5）最小。流线分析显示，在 4D Flow 和 CFD 上，弯曲中段的垂直或螺旋流动出现频率更高（κ：0.27-0.68）。

结论

2D 电影 PC-MRI 的 SMA 速度测量取决于测量平面的定位。不建议在弯曲中段进行 MR 速度测量，而建议在远端直段进行。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a099/7809144/e3ba0dd4be7d/mrms-19-366-g1.jpg

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最佳平面选择用于测量肠系膜上动脉餐后血流增加：使用 4D 流和计算流体动力学进行分析。

Optimal Plane Selection for Measuring Post-prandial Blood Flow Increase within the Superior Mesenteric Artery: Analysis Using 4D Flow and Computational Fluid Dynamics.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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