Towards clinical translation of 7 Tesla MRI in the human brain

IPEM-translation Pub Date : 2024-03-01 DOI:10.1016/j.ipemt.2024.100025

Graeme A. Keith , Rosemary A. Woodward , Tracey Hopkins , Sarah Allwood-Spiers , Jon Trinder , Keith W. Muir , David A. Porter , Natasha E. Fullerton

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Abstract

Clinical translation of 7 tesla (T) MRI of the brain promises high image quality and potentially improved clinical diagnosis for patients compared to current standard lower field-strength MRI at 1.5 and 3T.

Here we describe how physics principles underlying ultra-high field (UHF) strength MRI affect 7T image quality, and how these can be exploited to translate 7T brain imaging into clinical practice. UHF MRI profits from higher inherent signal-to-noise ratio (SNR) and a resultant increase in achievable spatial resolution or acceleration factors; increase in sensitivity to magnetic susceptibility differences and a higher amplitude of the Blood Oxygen Level Dependent (BOLD) signal; increase in longitudinal relaxation time; and increased frequency dispersion and spectral resolution in MR spectroscopy.

Examples are presented of different brain pathologies, which are better illustrated on 7T compared to lower field strength by applying sequences and imaging techniques that exploit these intrinsic strengths of 7T MRI. This includes imaging of various vascular pathologies, epilepsy and brain tumours.

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实现 7 特斯拉核磁共振成像在人脑中的临床转化

与目前标准的 1.5T 和 3T 低磁场强度磁共振成像相比，7 特斯拉 (T) 脑部磁共振成像的临床应用有望获得高图像质量，并可能改善患者的临床诊断。超高频磁共振成像得益于更高的固有信噪比 (SNR)，从而提高了可实现的空间分辨率或加速因子；提高了对磁感应强度差异的灵敏度和更高的血氧水平依赖 (BOLD) 信号振幅；增加了纵向弛豫时间；提高了磁共振光谱的频率弥散和光谱分辨率。其中包括各种血管病变、癫痫和脑肿瘤的成像。

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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来源期刊

IPEM-translation Medicine and Dentistry (General)

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审稿时长

63 days

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