通过利用速度-时空相关性实现加速动态傅里叶速度编码

Accelerated dynamic Fourier velocity encoding by exploiting velocity-spatio-temporal correlations.

作者信息

Hansen Michael S, Baltes Christof, Tsao Jeffrey, Kozerke Sebastian, Pruessmann Klaas P, Boesiger Peter, Pedersen Erik M

机构信息

Institute for Biomedical Engineering, Swiss Federal Institute of Technology (ETH), University of Zurich, Zurich, Switzerland.

出版信息

MAGMA. 2004 Nov;17(2):86-94. doi: 10.1007/s10334-004-0062-8. Epub 2004 Nov 9.

DOI:10.1007/s10334-004-0062-8

PMID:15565503

Abstract

OBJECTIVE

To describe how the information content in a Fourier velocity encoding (FVE) scan can be transformed into a very sparse representation and to develop a method that exploits the compactness of the data to significantly accelerate the acquisition.

MATERIALS AND METHODS

For validation, fully sampled FVE datasets were acquired in phantom and in vivo experiments. Fivefold and eightfold acceleration was simulated by using only one fifth or one eighth of the data for reconstruction in the proposed method based on the k-t BLAST framework. Reconstructed images were compared quantitatively to those from the fully sampled data.

RESULTS

Velocity spectra in the accelerated datasets were comparable to the spectra from fully sampled datasets. The detected peak velocities remained accurate even at eightfold acceleration, and the overall shape of the spectra was well preserved. Slight temporal smoothing was seen in the accelerated datasets.

CONCLUSION

A novel technique for accelerating time-resolved FVE scan is presented. It is possible to accelerate FVE to acquisition speeds comparable to a standard time-resolved phase-contrast scan.

摘要

目的

描述如何将傅里叶速度编码（FVE）扫描中的信息内容转换为非常稀疏的表示形式，并开发一种利用数据紧凑性来显著加速采集的方法。

材料与方法

为进行验证，在体模和体内实验中采集了全采样FVE数据集。基于k-t BLAST框架的所提方法中，通过仅使用五分之一或八分之一的数据进行重建，模拟了五倍和八倍加速。将重建图像与全采样数据得到的图像进行定量比较。

结果

加速数据集中的速度谱与全采样数据集中的谱相当。即使在八倍加速时，检测到的峰值速度仍保持准确，并且谱的整体形状得到了很好的保留。在加速数据集中可见轻微的时间平滑。

结论

提出了一种加速时间分辨FVE扫描的新技术。将FVE加速到与标准时间分辨相位对比扫描相当的采集速度是可能的。

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通过利用速度-时空相关性实现加速动态傅里叶速度编码

Accelerated dynamic Fourier velocity encoding by exploiting velocity-spatio-temporal correlations.

作者信息

机构信息

出版信息

OBJECTIVE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料与方法

结果

结论

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