Krzysztof Klodowski, Ayan Sengupta, Iulius Dragonu, Christopher T Rodgers
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引用次数: 0
摘要
超高磁场(7T)磁共振成像(MRI)能以亚毫米分辨率进行扫描,信噪比(SNR)非常高。随着 7T 磁共振成像技术在临床上的广泛应用,必须克服患者运动带来的挑战。回顾性运动校正已成功用于某些方案,但对于逐片扫描等采集,只有前瞻性运动校正才能充分发挥 7T 磁共振成像的潜力。我们报告了首次为西门子 7T Terra MRI 实施的前瞻性 3D Fat Navigator("FatNav")运动校正。我们为 FatNav 实施了一个模块化序列构件,并将其嵌入到供应商的梯度唤回回波 (GRE) 序列中。我们修改了重建流水线,以在线重建 FatNav 图像,对图像进行核心配准,并在线向主序列发送运动更新。我们在合成 FatNav 数据上测试了五种配准算法的性能和准确性。我们在序列中采用了其中最好的三种,并对它们进行了在线测试。我们采集了健康志愿者的 T1 和 T2* 加权脑部图像,并对每张图像进行运动校正,以直观显示在线运动校正的效果。数据是在头部固定和未固定的情况下采集的。我们还测试了对每次测量进行运动校正时的性能。我们的实施使用了 1.23 秒的 3D FatNav 采集模块,并在不到 3 秒的时间内提供运动更新,这足以满足典型扫描中每隔几条 k 空间线进行一次运动更新的要求。校正后的图像更加清晰,可见运动伪影更少。图像拉普拉奇方差的增加从数量上反映了清晰度的提高,校正后的图像比未校正的图像要好 1.59 倍。校正图像与未校正图像相比,整个大脑镰的轮廓陡峭了 33%。前瞻性 FatNav 提高了脑部 GRE 图像质量。我们的模块化序列构件提供了一种简单的方法,可将运动校正集成到 7T MRI 脉冲序列中。
Prospective 3D Fat Navigator (FatNav) motion correction for 7T Terra MRI.
Ultra-high field (7T) MRI allows scans at sub-millimetre resolution with exquisite signal-to-noise ratio (SNR). As 7T MRI becomes more widely used clinically, the challenge of patient motion must be overcome. Retrospective motion correction is used successfully for some protocols, but for acquisitions such as slice-by-slice scans only prospective motion correction can deliver the full potential of 7T MRI. We report the first implementation of prospective 3D Fat Navigator ("FatNav") motion correction for the Siemens 7T Terra MRI. We implemented a modular Sequence Building Block for FatNav and embedded it into the vendor's gradient-recalled echo (GRE) sequence. We modified the reconstruction pipeline to reconstruct FatNav images online, coregistering them and sending motion updates to the host sequence online. We tested five registration algorithms for performance and accuracy on synthetic FatNav data. We implemented the best three of these in our sequence and tested them online. We acquired T1 and T2* weighted brain images of healthy volunteers correcting every other image for motion to visualise the effectiveness of online motion correction. Data were acquired with and without head immobilisation. We also tested performance while correcting every measurement for motion. Our implementation uses a 1.23 s 3D FatNav acquisition module and delivers motion updates in less than 3 s, which is sufficient for motion updates every few k-space lines in typical scans. Corrected images are crisper with fewer visible motion artefacts. This improved sharpness is reflected quantitatively by an increase in the variance of the image Laplacian which is 1.59 x better for corrected vs uncorrected images. Profiles across the cerebral falx are 33% steeper for corrected vs uncorrected images. Prospective FatNav improves GRE image quality in the brain. Our modular Sequence Building Block provides a simple method to integrate motion correction in 7T MRI pulse sequences.
期刊介绍:
NMR in Biomedicine is a journal devoted to the publication of original full-length papers, rapid communications and review articles describing the development of magnetic resonance spectroscopy or imaging methods or their use to investigate physiological, biochemical, biophysical or medical problems. Topics for submitted papers should be in one of the following general categories: (a) development of methods and instrumentation for MR of biological systems; (b) studies of normal or diseased organs, tissues or cells; (c) diagnosis or treatment of disease. Reports may cover work on patients or healthy human subjects, in vivo animal experiments, studies of isolated organs or cultured cells, analysis of tissue extracts, NMR theory, experimental techniques, or instrumentation.
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