Contrast-enhanced magnetic resonance angiography: development and optimization of techniques for paramagnetic and hyperpolarized contrast media.

Jonas Svensson
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引用次数: 13

Abstract

Contrast-enhanced magnetic resonance angiography (CE-MRA) is a diagnostic method for imaging of vascular structures based on nuclear magnetic resonance. Vascular enhancement is achieved by injection of a contrast medium (CM). Studies were performed using two different types of CM: conventional paramagnetic CM, and a new type of CM based on hyperpolarized (HP) nuclei. The effects of varying CM concentration with time during image acquisition were studied by means of computer simulations using two different models. It was shown that a rapid concentration variation during encoding of the central parts of k-space could result in signal loss and severe image artifacts. The results were confirmed qualitatively with phantom experiments. A postprocessing method was developed to address problems with simultaneous enhancement of arteries and veins in CE-MRA of the lower extremities. The method was based on the difference in flow-induced phase in the two vessel types. Evaluation of the method was performed with flow phantom measurements and with CE-MRA in two volunteers using standard pulse sequences. The flow-induced phase in the vessels of interest was sufficient to distinguish arteries from veins in the superior-inferior direction. Using this method, the venous enhancement could be extinguished. The possibility of using HP nuclei as CM for CE-MRA was evaluated. Signal expressions for a flow of HP CM imaged with a gradient echo sequence were derived. These signal expressions were confirmed in phantom experiments using HP 129Xe dissolved in ethanol. Studies were also performed with a new CM based on HP 13C. The CM had very long relaxation times (T1, in vivo/T2, in vivo approximately 38/1.3 s). The long relaxation times were utilized in imaging with a fully balanced steady-state free precession pulse sequence (trueFISP), where the optimal flip angle was found to be 180 degrees. CE-MRA with the 13C-based CM in rats resulted in images with high vascular SNR (approximately 500). CE-MRA is a useful clinical tool for diagnosing vascular disease. With the development of new contrast media, based on hyperpolarized nuclei for example, there is a potential for further improvement in the signal levels that can be achieved, enabling a standard of imaging of vessels that is not possible today.

增强磁共振血管造影术:顺磁和超极化造影剂技术的发展和优化。
磁共振血管造影(CE-MRA)是一种基于核磁共振成像的血管结构诊断方法。血管增强是通过注射造影剂(CM)来实现的。研究使用了两种不同类型的CM:常规顺磁CM和基于超极化(HP)核的新型CM。采用两种不同的模型,通过计算机模拟研究了CM浓度随时间变化对图像采集的影响。结果表明,在k空间中心部分的编码过程中,快速的浓度变化可能导致信号丢失和严重的图像伪影。模拟实验定性地证实了这一结果。提出了一种后处理方法来解决下肢CE-MRA中动脉和静脉同时增强的问题。该方法是基于两种容器类型中流致相的差异。对两名使用标准脉冲序列的志愿者进行了流动幻影测量和CE-MRA评估。感兴趣的血管的血流诱导阶段足以区分上下方向的动脉和静脉。使用该方法可以消除静脉增强。评估了HP核作为CE-MRA CM的可能性。推导了梯度回波序列对高压CM流成像的信号表达式。用hp129xe溶解在乙醇中的模拟实验证实了这些信号的表达。研究还进行了基于hp13c的新CM。CM具有很长的弛豫时间(T1,体内/T2,体内约38/1.3 s),长弛豫时间用于完全平衡的稳态自由进动脉冲序列(trueFISP)成像,其中发现最佳翻转角为180度。大鼠13c基CM的CE-MRA成像血管信噪比高(约500)。CE-MRA是诊断血管疾病的有效临床工具。随着新型造影剂的发展,例如基于超极化核的造影剂,有可能进一步提高可以达到的信号水平,使血管成像达到今天不可能达到的标准。
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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