Steinstraeter O, Teismann Inga K, Wollbrink A, Suntrup S, Stoeckigt K, Dziewas R, Pantev C
Institute for Biomagnetism and Biosignalanalysis, University of Muenster, Münster, Germany.
Exp Brain Res. 2009 Mar;193(3):387-96. doi: 10.1007/s00221-008-1634-z. Epub 2008 Nov 15.
Synthetic aperture magnetometry (SAM) is a powerful MEG source localization method to analyze evoked as well as induced brain activity. To gain structural information of the underlying sources, especially in group studies, individual magnetic resonance images (MRI) are required for co-registration. During the last few years, the relevance of MEG measurements on understanding the pathophysiology of different diseases has noticeable increased. Unfortunately, especially in patients and small children, structural MRI scans cannot always be performed. Therefore, we developed a new method for group analysis of SAM results without requiring structural MRI data that derives its geometrical information from the individual volume conductor model constructed for the SAM analysis. The normalization procedure is fast, easy to implement and integrates seamlessly into an existing landmark based MEG-MRI co-registration procedure. This new method was evaluated on different simulated points as well as on a pneumatic index finger stimulation paradigm analyzed with SAM. Compared with an established MRI-based normalization procedure (SPM2) the new method shows only minor errors in single subject results as well as in group analysis. The mean difference between the two methods was about 4 mm for the simulated as well as for finger stimulation data. The variation between individual subjects was generally higher than the error induced by the missing MRIs. The method presented here is therefore sufficient for most MEG group studies. It allows accomplishing MEG studies with subject groups where MRI measurements cannot be performed.
合成孔径磁强计(SAM)是一种强大的脑磁图(MEG)源定位方法,可用于分析诱发脑活动和诱导脑活动。为了获取潜在源的结构信息,特别是在群体研究中,需要个体磁共振图像(MRI)进行配准。在过去几年中,MEG测量对于理解不同疾病的病理生理学的相关性显著增加。不幸的是,特别是在患者和幼儿中,有时无法进行结构MRI扫描。因此,我们开发了一种新的方法,用于在不需要结构MRI数据的情况下对SAM结果进行群体分析,该方法从为SAM分析构建的个体容积导体模型中获取几何信息。归一化过程快速、易于实现,并且可以无缝集成到现有的基于地标点的MEG-MRI配准过程中。该新方法在不同的模拟点以及用SAM分析的气动食指刺激范式上进行了评估。与已建立的基于MRI的归一化程序(SPM2)相比,新方法在单受试者结果以及群体分析中仅显示出微小误差。对于模拟数据和手指刺激数据,两种方法之间的平均差异约为4毫米。个体受试者之间的差异通常高于因缺少MRI而引起的误差。因此,本文提出的方法对于大多数MEG群体研究来说已经足够。它允许在无法进行MRI测量的受试者群体中完成MEG研究。
