用于13C动力学二维空间/一维谱成像加速的联合空间光谱重建和k-t螺旋技术

Joint spatial-spectral reconstruction and k-t spirals for accelerated 2D spatial/1D spectral imaging of 13C dynamics.

作者信息

Gordon Jeremy W, Niles David J, Fain Sean B, Johnson Kevin M

机构信息

Department of Medical Physics, University of Wisconsin, Madison, Wisconsin, USA.

出版信息

Magn Reson Med. 2014 Apr;71(4):1435-45. doi: 10.1002/mrm.24796. Epub 2013 May 28.

DOI:10.1002/mrm.24796

PMID:23716402

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4011726/

Abstract

PURPOSE

To develop a novel imaging technique to reduce the number of excitations and required scan time for hyperpolarized (13)C imaging.

METHODS

A least-squares based optimization and reconstruction is developed to simultaneously solve for both spatial and spectral encoding. By jointly solving both domains, spectral imaging can potentially be performed with a spatially oversampled single echo spiral acquisition. Digital simulations, phantom experiments, and initial in vivo hyperpolarized [1-(13)C]pyruvate experiments were performed to assess the performance of the algorithm as compared to a multi-echo approach.

RESULTS

Simulations and phantom data indicate that accurate single echo imaging is possible when coupled with oversampling factors greater than six (corresponding to a worst case of pyruvate to metabolite ratio < 9%), even in situations of substantial T(2)* decay and B(0) heterogeneity. With lower oversampling rates, two echoes are required for similar accuracy. These results were confirmed with in vivo data experiments, showing accurate single echo spectral imaging with an oversampling factor of 7 and two echo imaging with an oversampling factor of 4.

CONCLUSION

The proposed k-t approach increases data acquisition efficiency by reducing the number of echoes required to generate spectroscopic images, thereby allowing accelerated acquisition speed, preserved polarization, and/or improved temporal or spatial resolution.

摘要

目的

开发一种新型成像技术，以减少超极化（13）C成像所需的激发次数和扫描时间。

方法

开发了一种基于最小二乘法的优化和重建方法，以同时求解空间和光谱编码。通过联合求解这两个域，光谱成像有可能通过空间过采样的单回波螺旋采集来执行。进行了数字模拟、体模实验和初始体内超极化[1-（13）C]丙酮酸实验，以评估该算法与多回波方法相比的性能。

结果

模拟和体模数据表明，当过采样因子大于6（对应于丙酮酸与代谢物比率<9%的最坏情况）时，即使在T（2）*大量衰减和B（0）不均匀的情况下，也可以进行准确的单回波成像。过采样率较低时，需要两个回波才能达到类似的精度。体内数据实验证实了这些结果，显示过采样因子为7时可进行准确的单回波光谱成像，过采样因子为4时可进行双回波成像。

结论

所提出的k-t方法通过减少生成光谱图像所需的回波数量来提高数据采集效率，从而实现更快的采集速度、保留的极化和/或改善的时间或空间分辨率。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8f50/4011726/e3949690988a/nihms-560234-f0001.jpg

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