Ultra-high-resolution brain MRI at 0.55T: bSTAR and its application to magnetization transfer ratio imaging.

Zeitschrift fur medizinische Physik Pub Date : 2025-01-16 DOI:10.1016/j.zemedi.2024.12.001

Grzegorz Bauman, Roya Afshari, Oliver Bieri

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Abstract

Purpose: This study aims to evaluate the feasibility of structural sub-millimeter isotropic brain MRI at 0.55 T using a 3D half-radial dual-echo balanced steady-state free precession sequence, termed bSTAR and to assess its potential for high-resolution magnetization transfer imaging.

Methods: Phantom and in-vivo imaging of three healthy volunteers was performed on a low-field 0.55 T MR-system with isotropic bSTAR resolution settings of 0.87 × 0.87 × 0.87 mm³ and 0.69 × 0.69 × 0.69 mm³. Furthermore, off-resonance mapping was performed using 3D double-echo spoiled gradient imaging. For magnetization transfer (MT) MRI, the RF pulse duration of the 0.87 mm bSTAR scan was modified. Data were reconstructed using a GPU-accelerated compressed sensing algorithm. Magnetization transfer ratio (MTR) maps were calculated from two bSTAR scans with and without RF pulse prolongation. The MTR scan took 5 minutes and the reproducibility was assessed through repeated scans.

Results: Off-resonance mapping revealed that bSSFP brain imaging with TR < 5ms is essentially free of off-resonance-related artifacts even near the nasal cavities. Phantom and in-vivo scans demonstrated the feasibility of sub-millimeter isotropic bSTAR imaging. MTR maps obtained with high isotropic resolution bSTAR showed contrast between white and gray matter in agreement with expectations from high-field studies. The MTR measurements were highly reproducible with an average inter-scan MTR peak value of 43.3 ± 0.3 percent units.

Conclusions: This study demonstrated the potential of sub-millimeter and artifact-free morphologic brain imaging at 0.55 T using bSTAR leveraging the advantages of low-field MRI, such as reduced susceptibility artifacts and improved radio-frequency field homogeneity. Furthermore, MT-sensitized bSTAR brain MRI enabled whole-brain MTR assessment within clinically feasible times and with high reproducibility.

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0.55T: bSTAR超高分辨率脑MRI及其在磁化转移比成像中的应用。

目的：本研究旨在评估在0.55 T下使用三维半径向双回波平衡稳态自由进动序列（bSTAR）进行结构亚毫米各向同性脑MRI的可行性，并评估其在高分辨率磁化转移成像方面的潜力。方法:幻影和体内成像的三个健康的志愿者进行低场0.55 T mr系统各向同性bSTAR分辨率设置为0.87 ×  0.87×0.87   mm3和0.69×0.69  ×0.69  mm3。此外，使用三维双回波破坏梯度成像进行非共振成像。对于磁化转移（MT） MRI，修改了0.87 mm bSTAR扫描的RF脉冲持续时间。数据重构采用gpu加速压缩感知算法。磁化传递比（MTR）图由两次bSTAR扫描计算，有和没有RF脉冲延长。MTR扫描耗时5分钟，通过重复扫描评估再现性。结果：非共振成像显示，即使在鼻腔附近，当TR < 5ms时，bSSFP脑成像基本上没有与非共振相关的伪影。幻影和活体扫描证明了亚毫米各向同性bSTAR成像的可行性。用高各向同性分辨率bSTAR获得的MTR地图显示了白质和灰质之间的对比，与高场研究的预期一致。MTR测量具有高重复性，平均扫描间MTR峰值为43.3 ± 0.3%单位。结论：本研究证明了在0.55 T时使用bSTAR进行亚毫米和无伪影的脑形态成像的潜力，利用低场MRI的优势，如减少敏感性伪影和改善射频场均匀性。此外，mt致敏的bSTAR脑MRI能够在临床可行的时间内进行全脑MTR评估，并且具有高重复性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Zeitschrift fur medizinische Physik

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