脑缺血的磁共振扩散和灌注成像。

K A Hossmann, M Hoehn-Berlage
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引用次数: 0

摘要

在过去的几年里,扩散和灌注磁共振(MR)成像方法在临床和实验条件下监测脑缺血的影响方面发现了越来越多的用户。通过研究脑血管床的通畅程度(MR血管造影),记录血液与脑间弥散示踪剂的交换([2H]水或[19F]三氟甲烷间隙),或测量循环血液的体积和传递时间(bolus track或自旋标记成像),可以可视化血液灌注。此外,可以利用磁场均匀性的敏感性变化(功能性或血氧水平依赖成像)来可视化血氧水平的变化。扩散成像是基于脑水扩散对信号强度的调制。记录一系列扩散加权图像可以计算表观扩散系数(ADC)并重建定量的ADC图像。脑ADC的变化是细胞内外水稳态的一个功能,因此是离子平衡的敏感标志。由于离子和水稳态的紊乱是脑缺血引起的第一个病理改变,因此弥散成像能够在几分钟内检测到早期损伤。相反,这些改变的逆转能够在几分钟内检测到早期损伤。相反,这些改变的逆转是一个早期和可靠的预测指标。本文综述了灌注和扩散成像技术在局灶性脑缺血后进展性脑梗死的病理生理、病理生化、治疗以及全脑缺血期间和之后缺血性损伤的表现和逆转等方面的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Diffusion and perfusion MR imaging of cerebral ischemia.

Over the last few years, diffusion and perfusion magnetic resonance (MR) imaging methods have found increasing user for monitoring the effects of cerebral ischemia under clinical and experimental conditions. Blood perfusion can be visualized by studying the patency of the cerebrovascular bed (MR angiography), by recording exchange of diffusible tracers between blood and brain ([2H]water or [19F]trifluoromethane clearance), or by measuring the volume and transit time of the circulating blood (bolus track or spin-tagging imaging). In addition, changes in blood oxygenation level can be visualized by taking advantage of the susceptibility changes of the magnetic field homogeneity (functional or blood-oxygenation-level-dependent imaging). Diffusion imaging is based on the modulation of signal intensity by brain water diffusion. Recording a series of diffusion-weighted images allows calculation of the apparent diffusion coefficient (ADC) and the reconstruction of quantitative ADC images. Brain ADC changes are a function of intra-extracellular water homeostasis and therefore are a sensitive marker of ionic equilibrium. Since disturbances of ion and water homeostasis are among the first pathological alterations induced by brain ischemia, diffusion imaging is able to detect the incipient injury within minutes. Conversely, the reversal of these alterations is able to detect the incipient injury within minutes. Conversely, the reversal of these alterations is an early and reliable predictor of postischemic recovery. Applications of perfusion and diffusion imaging are reviewed in relation to the pathophysiology, the pathobiochemistry, and the therapy of evolving brain infarct after focal ischemia and the manifestation and reversal of ischemic injury during and after global ischemia.

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