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基于模型的回波链 MRI 重建。

Model-based reconstruction for looping-star MRI.

机构信息

EECS, University of Michigan, Ann Arbor, Michigan, USA.

Biomedical Engineering, University of Michigan, Ann Arbor, Michigan, USA.

出版信息

Magn Reson Med. 2024 May;91(5):2104-2113. doi: 10.1002/mrm.29927. Epub 2024 Jan 28.

DOI:10.1002/mrm.29927
PMID:38282253
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10950512/
Abstract

PURPOSE

The aim of this study was to develop a reconstruction method that more fully models the signals and reconstructs gradient echo (GRE) images without sacrificing the signal to noise ratio and spatial resolution, compared to conventional gridding and model-based image reconstruction method.

METHODS

By modeling the trajectories for every spoke and simplifying the scenario to only echo-in and echo-out mixture, the approach explicitly models the overlapping echoes. After modeling the overlapping echoes with two system matrices, we use the conjugate gradient algorithm (CG-SENSE) with the nonuniform FFT (NUFFT) to optimize the image reconstruction cost function.

RESULTS

The proposed method is demonstrated in phantoms and in-vivo volunteer experiments for three-dimensional, high-resolution T2*-weighted imaging and functional MRI tasks. Compared to the gridding method, the high resolution protocol exhibits improved spatial resolution and reduced signal loss as a result of less intra-voxel dephasing. The fMRI task shows that the proposed model-based method produced images with reduced artifacts and blurring as well as more stable and prominent time courses.

CONCLUSION

The proposed model-based reconstruction results shows improved spatial resolution and reduced artifacts. The fMRI task shows improved time series and activation map due to the reduced overlapping echoes and under-sampling artifacts.

摘要

目的

本研究旨在开发一种重建方法,与传统的网格化和基于模型的图像重建方法相比,该方法能更全面地模拟信号,并重建梯度回波(GRE)图像,同时保持信噪比和空间分辨率不变。

方法

通过对每个辐射线轨迹进行建模,并将场景简化为仅包含回波输入和输出的混合情况,该方法明确地对重叠回波进行建模。在用两个系统矩阵对重叠回波进行建模后,我们使用共轭梯度算法(CG-SENSE)和非均匀快速傅里叶变换(NUFFT)来优化图像重建代价函数。

结果

该方法在体模和体内志愿者实验中进行了三维高分辨率 T2*-加权成像和功能磁共振成像任务的演示。与网格化方法相比,高分辨率协议由于较少的体素内去相位而表现出改进的空间分辨率和减少的信号损失。功能磁共振成像任务表明,所提出的基于模型的方法产生的图像具有更少的伪影和模糊,以及更稳定和突出的时间过程。

结论

所提出的基于模型的重建结果显示出改进的空间分辨率和减少的伪影。功能磁共振成像任务显示出由于重叠回波和欠采样伪影的减少,时间序列和激活图得到了改善。

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