通过将单个切片配准到解剖学体积中来进行功能磁共振成像中的运动校正。

Motion correction in fMRI via registration of individual slices into an anatomical volume.

作者信息

Kim B, Boes J L, Bland P H, Chenevert T L, Meyer C R

机构信息

Department of Radiology, University of Michigan, Ann Arbor 48109-0553, USA.

出版信息

Magn Reson Med. 1999 May;41(5):964-72. doi: 10.1002/(sici)1522-2594(199905)41:5<964::aid-mrm16>3.0.co;2-d.

DOI:10.1002/(sici)1522-2594(199905)41:5<964::aid-mrm16>3.0.co;2-d

PMID:10332880

Abstract

An automated retrospective image registration based on mutual information is adapted to a multislice functional magnetic resonance imaging (fMRI) acquisition protocol to provide accurate motion correction. Motion correction is performed by mapping each slice to an anatomic volume data set acquired in the same fMRI session to accommodate inter-slice head motion. Accuracy of the registration parameters was assessed by registration of simulated MR data of the known truth. The widely used rigid body volume registration approach based on stacked slices from the time series data may hinder statistical accuracy by introducing inaccurate assumptions of no motion between slices for multislice fMRI data. Improved sensitivity and specificity of the fMRI signal from mapping-each-slice-to-volume method is demonstrated in comparison with a stacked-slice correction method by examining functional data from two normal volunteers. The data presented in a standard anatomical coordinate system suggest the reliability of the mapping-each-slice-to-volume method to detect the activation signals consistent between the two subjects.

摘要

一种基于互信息的自动回顾性图像配准方法被应用于多层功能磁共振成像（fMRI）采集协议，以提供精确的运动校正。通过将每个切片映射到在同一fMRI会话中采集的解剖体积数据集来进行运动校正，以适应切片间的头部运动。通过对已知真值的模拟MR数据进行配准来评估配准参数的准确性。基于时间序列数据的堆叠切片的广泛使用的刚体体积配准方法，可能会因对多层fMRI数据的切片间无运动引入不准确假设而妨碍统计准确性。通过检查两名正常志愿者的功能数据，与堆叠切片校正方法相比，展示了从逐切片到体积映射方法获得的fMRI信号具有更高的灵敏度和特异性。在标准解剖坐标系中呈现的数据表明，逐切片到体积映射方法在检测两名受试者之间一致的激活信号方面具有可靠性。

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通过将单个切片配准到解剖学体积中来进行功能磁共振成像中的运动校正。

Motion correction in fMRI via registration of individual slices into an anatomical volume.

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