测量脑血容量、脑血流量和通透性的血流动力学磁共振成像技术的理论基础。
Theoretical basis of hemodynamic MR imaging techniques to measure cerebral blood volume, cerebral blood flow, and permeability.
作者信息
Zaharchuk G
机构信息
Neuroradiology Section, Stanford University Medical Center, Stanford, CA 94305-5487, USA.
出版信息
AJNR Am J Neuroradiol. 2007 Nov-Dec;28(10):1850-8. doi: 10.3174/ajnr.A0831.
Abstract
Cerebrovascular hemodynamic assessment adds new information to standard anatomic MR imaging and improves patient care. This article reviews the theoretic underpinnings of several potentially quantitative MR imaging-based methods that shed light on the hemodynamic status of the brain, including cerebral blood flow (CBF), cerebral blood volume (CBV), and contrast agent permeability. Techniques addressed include dynamic susceptibility contrast (which most simply and accurately estimates CBV), arterial spin labeling (a powerful method to measure CBF), and contrast-enhanced methods to derive permeability parameters such as the transport constant Ktrans.
摘要
脑血管血流动力学评估为标准解剖磁共振成像增添了新信息,并改善了患者护理。本文回顾了几种基于磁共振成像的潜在定量方法的理论基础,这些方法有助于了解脑血流动力学状态,包括脑血流量(CBF)、脑血容量(CBV)和造影剂通透性。所涉及的技术包括动态磁敏感对比(能最简单、准确地估计CBV)、动脉自旋标记(一种测量CBF的强大方法)以及用于推导通透性参数(如转运常数Ktrans)的对比增强方法。
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