新生儿的高分辨率和对比度 7 特斯拉磁共振脑成像

Pip Bridgen, Raphaël Tomi-Tricot, Alena Uus, Daniel Cromb, Megan Quirke, J. Almalbis, Beya Bonse, Miguel De la Fuente Botella, Alessandra Maggioni, Pierluigi Di Cio, Pauline A. Cawley, Chiara Casella, A. S. Dokumacı, Alice R. Thomson, Jucha Willers Moore, Devi Bridglal, Joao Saravia, Thomas Finck, Anthony N. Price, Elisabeth Pickles, Lucilio Cordero-Grande, Alexia Egloff, J. O’Muircheartaigh, S. Counsell, Sharon Giles, M. Deprez, Enrico De Vita, M. Rutherford, A. D. Edwards, J. Hajnal, Shaihan J. Malik, T. Arichi
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引用次数: 0

摘要

超高磁场磁共振成像在信噪比、空间分辨率和对比度方面都有显著提高,从而提高了病理和解剖敏感性。这些优势对新生儿大脑尤为重要,因为新生儿大脑发育迅速,对损伤敏感。然而,出于监管、安全和实际操作方面的考虑,在 7T 下对新生儿进行成像的经验一直很有限。我们的目标是建立一套在 7T 系统上安全获取高分辨率和高对比度新生儿大脑图像的程序。我们在 44 次扫描中获取了 35 名新生儿的图像(中位年龄为月经后 39+6 周,范围为 33+4 至 52+6 ;中位体重为 2.93 千克,范围为 1.57 至 5.3 千克),中位时间为 49 分 30 秒。扫描序列包括 T2 加权成像(TSE)、实际翻转角度成像(AFI)、功能磁共振成像(BOLD EPI)、电感加权成像(SWI)和磁共振波谱成像(STEAM)。解剖成像对海马、小脑和血管等通常在较低场强下难以观察到的结构具有极高的灵敏度。我们证明了在超高磁场下对脆弱的新生儿进行成像的安全性和可行性,并强调了在生命早期的这一关键阶段对大脑发育和病理过程提供重要新见解的尚未开发的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High resolution and contrast 7 tesla MR brain imaging of the neonate
Ultra-high field MR imaging offers marked gains in signal-to-noise ratio, spatial resolution, and contrast which translate to improved pathological and anatomical sensitivity. These benefits are particularly relevant for the neonatal brain which is rapidly developing and sensitive to injury. However, experience of imaging neonates at 7T has been limited due to regulatory, safety, and practical considerations. We aimed to establish a program for safely acquiring high resolution and contrast brain images from neonates on a 7T system.Images were acquired from 35 neonates on 44 occasions (median age 39 + 6 postmenstrual weeks, range 33 + 4 to 52 + 6; median body weight 2.93 kg, range 1.57 to 5.3 kg) over a median time of 49 mins 30 s. Peripheral body temperature and physiological measures were recorded throughout scanning. Acquired sequences included T2 weighted (TSE), Actual Flip angle Imaging (AFI), functional MRI (BOLD EPI), susceptibility weighted imaging (SWI), and MR spectroscopy (STEAM).There was no significant difference between temperature before and after scanning (p = 0.76) and image quality assessment compared favorably to state-of-the-art 3T acquisitions. Anatomical imaging demonstrated excellent sensitivity to structures which are typically hard to visualize at lower field strengths including the hippocampus, cerebellum, and vasculature. Images were also acquired with contrast mechanisms which are enhanced at ultra-high field including susceptibility weighted imaging, functional MRI, and MR spectroscopy.We demonstrate safety and feasibility of imaging vulnerable neonates at ultra-high field and highlight the untapped potential for providing important new insights into brain development and pathological processes during this critical phase of early life.
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