定量磁化率图
白质
磁化率
核磁共振
铁蛋白
化学
磁化率加权成像
相关系数
神经影像学
人脑
人类连接体项目
磁共振成像
物理
生物化学
医学
结晶学
数学
统计
放射科
作者
Christian Langkammer,Ferdinand Schweser,Nikolaus Krebs,Andreas Deistung,Walter Goessler,Eva Scheurer,Karsten Sommer,Gernot Reishofer,Kathrin Yen,Franz Fazekas,Stefan Ropele,Jürgen R. Reichenbach
出处
期刊:NeuroImage
[Elsevier BV]
日期:2012-09-01
卷期号:62 (3): 1593-1599
被引量:589
标识
DOI:10.1016/j.neuroimage.2012.05.049
摘要
Quantitative susceptibility mapping (QSM) is a novel technique which allows determining the bulk magnetic susceptibility distribution of tissue in vivo from gradient echo magnetic resonance phase images. It is commonly assumed that paramagnetic iron is the predominant source of susceptibility variations in gray matter as many studies have reported a reasonable correlation of magnetic susceptibility with brain iron concentrations in vivo. Instead of performing direct comparisons, however, all these studies used the putative iron concentrations reported in the hallmark study by Hallgren and Sourander (1958) for their analysis. Consequently, the extent to which QSM can serve to reliably assess brain iron levels is not yet fully clear. To provide such information we investigated the relation between bulk tissue magnetic susceptibility and brain iron concentration in unfixed (in situ) post mortem brains of 13 subjects using MRI and inductively coupled plasma mass spectrometry. A strong linear correlation between chemically determined iron concentration and bulk magnetic susceptibility was found in gray matter structures (r=0.84, p<0.001), whereas the correlation coefficient was much lower in white matter (r=0.27, p<0.001). The slope of the overall linear correlation was consistent with theoretical considerations of the magnetism of ferritin supporting that most of the iron in the brain is bound to ferritin proteins. In conclusion, iron is the dominant source of magnetic susceptibility in deep gray matter and can be assessed with QSM. In white matter regions the estimation of iron concentrations by QSM is less accurate and more complex because the counteracting contribution from diamagnetic myelinated neuronal fibers confounds the interpretation.
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