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单回波 Dixon 脂肪抑制时间分辨对比增强磁共振血管成像。

Time-resolved contrast-enhanced MR angiography with single-echo Dixon fat suppression.

机构信息

Department of Radiology, Mayo Clinic, Rochester, Minnesota.

出版信息

Magn Reson Med. 2018 Oct;80(4):1556-1567. doi: 10.1002/mrm.27152. Epub 2018 Feb 27.

DOI:10.1002/mrm.27152
PMID:29488251
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6097950/
Abstract

PURPOSE

Dixon-based fat suppression has recently gained interest for dynamic contrast-enhanced MRI, but multi-echo techniques require longer scan times and reduce temporal resolution compared to single-echo alternatives without fat suppression. The purpose of this work is to demonstrate accelerated single-echo Dixon imaging with high spatial and temporal resolution.

THEORY AND METHODS

Real-valued water and fat images can be obtained from a single measurement if the shared initial phase and that due to ΔB0 are assumed known a priori. An expression for simultaneous sensitivity encoding (SENSE) unfolding and fat-water separation is derived for the general undersampling case, and simplified under the special case of uniform Cartesian undersampling. In vivo experiments were performed in extremities and brain with SENSE acceleration factors of up to R = 8.

RESULTS

Single-echo Dixon reconstruction of highly undersampled data was successfully demonstrated. Dynamic contrast-enhanced water and fat images provided high spatial and temporal resolution dynamic images with image update times shorter than previous single-echo Dixon work.

CONCLUSION

Time-resolved contrast-enhanced MRI with single-echo Dixon fat suppression shows high image quality, improved vessel delineation, and reduced sensitivity to motion when compared to time-subtraction methods.

摘要

目的

基于 Dixon 的脂肪抑制技术最近在动态对比增强 MRI 中引起了关注,但多回波技术与没有脂肪抑制的单回波替代方案相比,需要更长的扫描时间并降低时间分辨率。本研究的目的是展示具有高空间和时间分辨率的加速单回波 Dixon 成像。

理论和方法

如果假设共享初始相位和由于 ΔB0 引起的相位是已知的,则可以从单次测量中获得真实的水和脂肪图像。本文推导出了一般欠采样情况下的同时灵敏度编码(SENSE)展开和脂肪-水分离的表达式,并在均匀笛卡尔欠采样的特殊情况下进行了简化。在肢体和大脑中进行了体内实验,最大 SENSE 加速因子为 R=8。

结果

成功地展示了高度欠采样数据的单回波 Dixon 重建。动态对比增强的水和脂肪图像提供了具有高空间和时间分辨率的动态图像,图像更新时间短于以前的单回波 Dixon 工作。

结论

与时间减影方法相比,具有单回波 Dixon 脂肪抑制的时间分辨对比增强 MRI 具有更高的图像质量、改善的血管描绘和对运动的敏感性降低。

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本文引用的文献

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Dual echo Dixon imaging with a constrained phase signal model and graph cuts reconstruction.
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