用于高分辨率脑部三维T1ρ图谱绘制的加权自旋锁定采集优化磁共振脉冲序列。
Optimized MR pulse sequence for high-resolution brain 3D-T1ρ mapping with weighted spin-lock acquisitions.
作者信息
Zibetti Marcelo V W, Menon Rajiv, De Moura Hector L, Keerthivasan Mahesh B, Regatte Ravinder R
机构信息
Center for Biomedical Imaging, Department of Radiology, New York University Grossman School of Medicine, New York, New York, USA.
Siemens Medical Solutions USA Inc., Malvern, Pennsylvania, USA.
出版信息
Magn Reson Med. 2025 Apr;93(4):1458-1470. doi: 10.1002/mrm.30412. Epub 2024 Dec 22.
PURPOSE
To implement and evaluate the feasibility of brain spin-lattice relaxation in the rotating frame (T1ρ) mapping using a novel optimized pulse sequence that incorporates weighted spin-lock acquisitions, enabling high-resolution three-dimensional (3D) mapping.
METHODS
The optimized variable flip-angle framework, previously proposed for knee T1ρ mapping, was enhanced by integrating weighted spin-lock acquisitions. This strategic combination significantly boosts signal-to-noise ratio (SNR) while reducing data acquisition time, facilitating high-resolution 3D-T1ρ mapping of the brain. The proposed sequence was compared with magnetization-prepared angle-modulated partitioned k-space spoiled gradient-echo sequence snapshots (MAPSS).
RESULTS
The newly developed pulse sequence, tested for brain 3D-T1ρ mapping for the first time, obtained maps in 4 min with quality comparable to a 20-min MAPSS sequence. Specifically, the voxel-wise median absolute percentage difference between these MR sequences at a resolution of 0.9 × 0.9 × 3 mm is 13.1%. If high resolution is desired, with a voxel size of 0.5 × 0.5 × 3 mm, the new sequence can acquire T1ρ maps in 8 min, surpassing a 20-min (and resolution of 0.9 × 0.9 × 3 mm) MAPSS in SNR. The weighted spin-lock acquisition combined with optimized variable flip angle improved the SNR over optimized variable flip angle alone by about 28%.
CONCLUSION
Compared with the 20-min MAPSS sequence for brain T1ρ mapping, the proposed learned high-resolution 3D pulse sequence simultaneously achieved a 2.3-fold improvement in effective (3.2-fold nominal) spatial resolution, a 1.1-fold improvement in SNR, and a 2.5-fold reduction in scan time.
目的
使用一种包含加权自旋锁定采集的新型优化脉冲序列,实现并评估旋转坐标系下脑自旋晶格弛豫时间(T1ρ)成像的可行性,以实现高分辨率三维(3D)成像。
方法
通过整合加权自旋锁定采集,对先前提出的用于膝关节T1ρ成像的优化可变翻转角框架进行了改进。这种策略性组合显著提高了信噪比(SNR),同时减少了数据采集时间,有助于进行脑的高分辨率3D-T1ρ成像。将所提出的序列与磁化准备角度调制分区k空间扰相梯度回波序列快照(MAPSS)进行比较。
结果
新开发的脉冲序列首次用于脑3D-T1ρ成像测试,在4分钟内获得了成像,其质量与20分钟的MAPSS序列相当。具体而言,在0.9×0.9×3mm分辨率下,这些磁共振序列之间的体素-wise中位数绝对百分比差异为13.1%。如果需要高分辨率,体素大小为0.5×0.5×3mm时,新序列可在8分钟内采集T1ρ成像,在SNR方面超过20分钟(分辨率为0.9×0.9×3mm)的MAPSS。加权自旋锁定采集与优化可变翻转角相结合,相比单独的优化可变翻转角,SNR提高了约28%。
结论
与用于脑T1ρ成像的20分钟MAPSS序列相比,所提出的高分辨率3D脉冲序列在有效(标称3.2倍)空间分辨率上提高了2.3倍,在SNR上提高了1.1倍,在扫描时间上减少了2.5倍。
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