Gholipour Ali, Kehtarnavaz Nasser, Scherrer Benoit, Warfield Simon K
Computational Radiology Lab, Department of Radiology at Children’s Hospital Boston, and Harvard Medical School, Boston, MA 02115, USA.
Annu Int Conf IEEE Eng Med Biol Soc. 2011;2011:6997-7000. doi: 10.1109/IEMBS.2011.6091769.
Rapid and efficient imaging of the brain to monitor brain activity and neural connectivity is performed through functional MRI and diffusion tensor imaging (DTI) using the Echo-planar imaging (EPI) sequence. An entire volume of the brain is imaged by EPI in a few seconds through the measurement of all k-space lines within one repetition time. However, this makes the sequence extremely sensitive to imperfections of magnetic field. In particular, the error caused by susceptibility induced magnetic field inhomogeneity accumulates over the duration of phase encoding, which in turn results in severe geometric distortion (warping) in EPI scans. EPI distortion correction through unwarping can be performed by field map based or image based techniques. However, due to the lack of ground truth it has been difficult to compare and validate different approaches. In this paper we propose a hybrid field map guided constrained deformable registration approach and compare it to field map based and image based unwarping approaches through a novel in-vivo validation framework which is based on the acquisition and alignment of EPI scans with different phase encoding directions. The quantitative evaluation results show that our hybrid approach of field map guided deformable registration to an undistorted T2-weighted image outperforms the other approaches.
通过功能磁共振成像(functional MRI)和使用回波平面成像(EPI)序列的扩散张量成像(DTI),可以对大脑进行快速高效的成像,以监测大脑活动和神经连接。在一个重复时间内通过测量所有k空间线,EPI能在几秒钟内对整个大脑体积进行成像。然而,这使得该序列对磁场的不完善极其敏感。特别是,由磁化率引起的磁场不均匀性所导致的误差会在相位编码期间累积,进而在EPI扫描中导致严重的几何失真(扭曲)。通过去扭曲进行的EPI失真校正可以通过基于场图或基于图像的技术来执行。然而,由于缺乏地面真值,很难比较和验证不同的方法。在本文中,我们提出了一种混合场图引导的约束可变形配准方法,并通过一个基于不同相位编码方向的EPI扫描采集和对齐的新型体内验证框架,将其与基于场图和基于图像的去扭曲方法进行比较。定量评估结果表明,我们将场图引导的可变形配准到未失真的T2加权图像的混合方法优于其他方法。