快速弛豫核磁共振成像的测量技术。

Measurement techniques for magnetic resonance imaging of fast relaxing nuclei.

机构信息

Computer Assisted Clinical Medicine, Heidelberg University, Mannheim, Germany.

出版信息

MAGMA. 2014 Feb;27(1):5-19. doi: 10.1007/s10334-013-0394-3. Epub 2013 Jul 24.

Abstract

In this review article, techniques for sodium ((23)Na) magnetic resonance imaging (MRI) are presented. These techniques can also be used to image other nuclei with short relaxation times (e.g., (39)K, (35)Cl, (17)O). Twisted projection imaging, density-adapted 3D projection reconstruction, and 3D cones are preferred because of uniform k-space sampling and ultra-short echo times. Sampling density weighted apodization can be applied if intrinsic filtering is desired. This approach leads to an increased signal-to-noise ratio compared to postfiltered acquisition in cases of short readout durations relative to T 2 (*) relaxation time. Different MR approaches for anisotropic resolution are presented, which are important for imaging of thin structures such as myocardium, cartilage, and skin. The third part of this review article describes different methods to put more weighting either on the intracellular or the extracellular sodium signal by means of contrast agents, relaxation-weighted imaging, or multiple-quantum filtering.

摘要

在这篇综述文章中，介绍了用于钠（(23)Na）磁共振成像（MRI）的技术。这些技术也可用于成像其他弛豫时间较短的核（例如，(39)K、(35)Cl、(17)O）。由于采用了均匀的 k 空间采样和超短回波时间，因此首选扭曲投影成像、密度自适应 3D 投影重建和 3D 锥形。如果需要固有滤波，则可以应用采样密度加权调幅。与相对于 T 2（*）弛豫时间的短读出持续时间的情况下的后滤波采集相比，这种方法导致信号噪声比增加。本文介绍了用于各向异性分辨率的不同 MR 方法，这些方法对于成像心肌、软骨和皮肤等薄结构非常重要。本文的第三部分描述了通过对比剂、弛豫加权成像或多量子滤波，将更多权重分配给细胞内或细胞外钠信号的不同方法。

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快速弛豫核磁共振成像的测量技术。

Measurement techniques for magnetic resonance imaging of fast relaxing nuclei.

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