King's College London, Division of Imaging Sciences, London, United Kingdom.
J Magn Reson Imaging. 2012 Dec;36(6):1362-71. doi: 10.1002/jmri.23763. Epub 2012 Aug 3.
To accelerate the acquisition of three-dimensional (3D) high-resolution cardiovascular molecular MRI by using Compressed Sensing (CS) reconstruction.
Molecular MRI is an emerging technique for the early assessment of cardiovascular disease. This technique provides excellent soft tissue differentiation at a molecular and cellular level using target-specific contrast agents (CAs). However, long scan times are required for 3D molecular MRI. Parallel imaging can be used to speed-up these acquisitions, but hardware considerations limit the maximum acceleration factor. This limitation is important in small-animal studies, where single-coils are commonly used. Here we exploit the sparse nature of molecular MR images, which are characterized by localized and high-contrast biological target-enhancement, to accelerate data acquisition. CS was applied to detect: (a) venous thromboembolism and (b) coronary injury and aortic vessel wall in single- and multiple-coils acquisitions, respectively.
Retrospective undersampling showed good overall image quality with accelerations up to four for thrombus and aortic images, and up to three for coronary artery images. For higher acceleration factors, features with high CA uptake were still well recovered while low affinity targets were less preserved with increased CS undersampling artifacts. Prospective undersampling was performed in an aortic image with acceleration of two, showing good contrast and well-defined tissue boundaries in the contrast-enhanced regions.
We demonstrate the successful application of CS to preclinical molecular MR with target specific gadolinium-based CAs using retrospective (accelerations up to four) and prospective (acceleration of two) undersampling.
利用压缩感知(CS)重建技术加速获得三维(3D)高分辨率心血管分子 MRI。
分子 MRI 是一种新兴的心血管疾病早期评估技术。该技术使用靶向特异性对比剂(CAs)在分子和细胞水平上提供出色的软组织区分。然而,3D 分子 MRI 需要较长的扫描时间。并行成像可用于加速这些采集,但硬件考虑因素限制了最大加速因子。在小动物研究中,这一限制很重要,因为通常使用单线圈。在这里,我们利用分子 MR 图像的稀疏特性,这些图像的特征是局部和高对比度的生物靶标增强,以加速数据采集。CS 用于分别检测:(a)静脉血栓栓塞和(b)单线圈和多线圈采集的冠状动脉损伤和主动脉血管壁。
回顾性欠采样显示,血栓和主动脉图像的整体图像质量良好,加速因子高达 4,冠状动脉图像的加速因子高达 3。对于更高的加速因子,具有高 CA 摄取的特征仍然可以很好地恢复,而具有低亲和力的靶标在 CS 欠采样伪影增加的情况下保留较少。在一个加速因子为 2 的主动脉图像中进行了前瞻性欠采样,显示出对比度增强区域的对比度良好且组织边界清晰。
我们成功地将 CS 应用于使用靶向特异性基于钆的 CAs 的临床前分子 MR,采用回顾性(加速高达 4)和前瞻性(加速 2)欠采样。
