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快速射频稳态(FRESS)自旋回波 MRI 用于定量 T2 映射:最小化快速 T2 测量的表观重复时间(TR)依赖性。

Fast radio-frequency enforced steady state (FRESS) spin echo MRI for quantitative T2 mapping: minimizing the apparent repetition time (TR) dependence for fast T2 measurement.

机构信息

Athinoula A. Martinos Center for Biomedical Imaging, Department of Radiology, Massachusetts General Hospital and Harvard Medical School, Charlestown, MA 02129, USA.

出版信息

NMR Biomed. 2012 Feb;25(2):189-94. doi: 10.1002/nbm.1729. Epub 2011 Jul 14.

DOI:10.1002/nbm.1729
PMID:21755552
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3712835/
Abstract

Transverse relaxation time (T(2)) is a basic but very informative MRI parameter, widely used in imaging to examine a host of diseases, including multiple sclerosis, stroke, and tumor. However, short repetition time (TR) is often used to minimize scan time, which may introduce non-negligible errors in T(2) measurement. Specifically, due to the use of refocusing pulse, the steady state magnetization depends not only on TR but also on the TE. Hence, if the TE dependence is not properly accounted for, it may be mistaken as T(2)-induced signal attenuation, leading to non-negligible T(2) underestimation. Our study proposed a fast radio-frequency enforced steady state (FRESS) spin echo (SE) MRI sequence, which saturates the magnetization after the echo and ensures a TE-independent steady state. The proposed FRESS-SE MRI was evaluated with numerical simulation, implemented with echo planar imaging readout, and validated by both phantom and in vivo experiments. In summary, FRESS-SE T(2) MRI technique was developed for fast and accurate T(2) imaging, suitable for in vivo applications.

摘要

横向弛豫时间(T(2))是一种基本但非常有用的 MRI 参数,广泛用于成像以检查多种疾病,包括多发性硬化症、中风和肿瘤。然而,短重复时间(TR)常用于最小化扫描时间,这可能会在 T(2)测量中引入不可忽略的误差。具体来说,由于使用了重聚焦脉冲,稳态磁化强度不仅取决于 TR,还取决于 TE。因此,如果没有正确考虑 TE 的依赖性,它可能会被误认为是 T(2)引起的信号衰减,从而导致不可忽略的 T(2)低估。我们的研究提出了一种快速射频强制稳态(FRESS)自旋回波(SE)MRI 序列,该序列在回波后使磁化饱和,并确保 TE 独立的稳态。所提出的 FRESS-SE MRI 通过数值模拟进行了评估,使用了回波平面成像读出进行了实现,并通过体模和体内实验进行了验证。总之,FRESS-SE T(2)MRI 技术是为快速准确的 T(2)成像而开发的,适用于体内应用。

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