综述:使用临床系统对组织、体液和材料的短 T₂ 和超短 T₂* 分量的 MRI。Agfa Mayneord 讲座
Review. The Agfa Mayneord lecture: MRI of short and ultrashort T₂ and T₂* components of tissues, fluids and materials using clinical systems.
机构信息
Department of Radiology, University of California San Diego, San Diego, CA 92103-8226, USA.
出版信息
Br J Radiol. 2011 Dec;84(1008):1067-82. doi: 10.1259/bjr/74368403.
Abstract
A variety of techniques are now available to directly or indirectly detect signal from tissues, fluids and materials that have short, ultrashort or supershort T₂ or T₂* components. There are also methods of developing image contrast between tissues and fluids in the short T₂ or T₂* range that can provide visualisation of anatomy, which has not been previously seen with MRI. Magnetisation transfer methods can now be applied to previously invisible tissues, providing indirect access to supershort T₂ components. Particular methods have been developed to target susceptibility effects and quantify them after correcting for anatomical distortion. Specific methods have also been developed to image the effects of magnetic iron oxide particles with positive contrast. Major advances have been made in techniques designed to correct for loss of signal and gross image distortion near metal. These methods are likely to substantially increase the range of application for MRI.
摘要
现在有多种技术可用于直接或间接检测具有短、超短或极短 T₂ 或 T₂分量的组织、流体和材料的信号。也有一些方法可以在短 T₂ 或 T₂范围内开发组织和流体之间的图像对比,从而可以提供以前用 MRI 看不到的解剖结构的可视化。现在可以将磁化传递方法应用于以前看不见的组织,从而间接获得极短 T₂ 分量的信息。已经开发了特定的方法来针对磁化率效应,并在纠正解剖变形后对其进行量化。还开发了特定的方法来对具有正对比的磁性氧化铁颗粒的影响进行成像。在旨在纠正金属附近信号损失和图像严重变形的技术方面取得了重大进展。这些方法很可能会大大增加 MRI 的应用范围。
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