KU Leuven - University of Leuven, Department of Imaging & Pathology, Nuclear Medicine & Molecular Imaging, Herestraat 49, B-3000 Leuven, Belgium; KU Leuven - University of Leuven, University Hospitals Leuven, Medical Imaging Research Center (MIRC), Herestraat 49, B-3000 Leuven, Belgium.
KU Leuven - University of Leuven, University Hospitals Leuven, Medical Imaging Research Center (MIRC), Herestraat 49, B-3000 Leuven, Belgium; KU Leuven - University of Leuven, Department of Neurosciences, Lab. for Cognitive Neurology, Herestraat 49, B-3000 Leuven, Belgium.
Neuroimage. 2014 Nov 15;102 Pt 2:875-84. doi: 10.1016/j.neuroimage.2014.06.068. Epub 2014 Jul 6.
The resolution of a PET scanner (2.5-4.5mm for brain imaging) is similar to the thickness of the cortex in the (human) brain (2.5mm on average), hampering accurate activity distribution reconstruction. Many techniques to compensate for the limited resolution during or post-reconstruction have been proposed in the past and have been shown to improve the quantitative accuracy. In this study, state-of-the-art reconstruction techniques are compared on a voxel-basis for quantification accuracy and group analysis using both simulated and measured data of healthy volunteers and patients with epilepsy.
Maximum a posteriori (MAP) reconstructions using either a segmentation-based or a segmentation-less anatomical prior were compared to maximum likelihood expectation maximization (MLEM) reconstruction with resolution recovery. As anatomical information, a spatially aligned 3D T1-weighted magnetic resonance image was used. Firstly, the algorithms were compared using normal brain images to detect systematic bias with respect to the true activity distribution, as well as systematic differences between two methods. Secondly, it was verified whether the algorithms yielded similar results in a group comparison study.
Significant differences were observed between the reconstructed and the true activity, with the largest errors when using (post-smoothed) MLEM. Only 5-10% underestimation in cortical gray matter voxel activity was found for both MAP reconstructions. Higher errors were observed at GM edges. MAP with the segmentation-based prior also resulted in a significant bias in the subcortical regions due to segmentation inaccuracies, while MAP with the anatomical prior which does not need segmentation did not. Significant differences in reconstructed activity were also found between the algorithms at similar locations (mainly in gray matter edge voxels and in cerebrospinal fluid voxels) in the simulated as well as in the clinical data sets. Nevertheless, when comparing two groups, very similar regions of significant hypometabolism were detected by all algorithms.
Including anatomical a priori information during reconstruction in combination with resolution modeling yielded accurate gray matter activity estimates, and a significant improvement in quantification accuracy was found when compared to post-smoothed MLEM reconstruction with resolution modeling. AsymBowsher provided the most accurate subcortical GM activity estimates. It is also reassuring that the differences found between the algorithms did not hamper the detection of hypometabolic regions in the gray matter when performing a voxel-based group comparison. Nevertheless, the size of the detected clusters differed. More elaborated and application-specific studies are required to decide which algorithm is best for a group analysis.
正电子发射断层扫描(PET)扫描仪的分辨率(大脑成像为 2.5-4.5mm)与大脑皮层的厚度相似(平均为 2.5mm),这妨碍了准确的活性分布重建。过去已经提出了许多在重建过程中或之后补偿有限分辨率的技术,并且已经证明这些技术可以提高定量准确性。在这项研究中,使用模拟和健康志愿者以及癫痫患者的测量数据,在体素基础上比较了最先进的重建技术的定量准确性和组分析。
比较了基于分割的最大后验(MAP)重建与具有分辨率恢复的最大似然期望最大化(MLEM)重建,使用空间对齐的 3D T1 加权磁共振图像作为解剖学信息。首先,使用正常脑图像比较算法,以检测相对于真实活性分布的系统偏差以及两种方法之间的系统差异。其次,验证算法在组比较研究中是否产生相似的结果。
在重建和真实活性之间观察到显著差异,使用(后平滑)MLEM 时误差最大。对于两种 MAP 重建,皮质灰质体素活性的低估仅为 5-10%。GM 边缘处观察到更高的误差。由于分割不准确,基于分割的先验的 MAP 重建也导致皮质下区域的显著偏差,而不需要分割的基于解剖学先验的 MAP 重建则没有。在模拟和临床数据集上,在类似位置(主要在灰质边缘体素和脑脊液体素中)也发现了算法之间的重建活性存在显著差异。尽管如此,当比较两个组时,所有算法都检测到非常相似的低代谢区域。
在重建过程中结合分辨率建模纳入解剖学先验信息,与使用分辨率建模的后平滑 MLEM 重建相比,可获得准确的灰质活性估计值,并可显著提高定量准确性。AsymBowsher 提供了最准确的皮质下 GM 活性估计值。令人放心的是,在进行基于体素的组比较时,在算法之间发现的差异并没有妨碍在灰质中检测到低代谢区域。然而,检测到的簇的大小不同。需要进行更详细和特定于应用的研究,以确定哪种算法最适合组分析。
