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评估平行水平集和鲍舍方法作为飞行时间 PET 重建的无分割解剖先验。

Evaluation of Parallel Level Sets and Bowsher's Method as Segmentation-Free Anatomical Priors for Time-of-Flight PET Reconstruction.

出版信息

IEEE Trans Med Imaging. 2018 Feb;37(2):590-603. doi: 10.1109/TMI.2017.2767940.

DOI:10.1109/TMI.2017.2767940
PMID:29408787
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5821901/
Abstract

In this article, we evaluate Parallel Level Sets (PLS) and Bowsher's method as segmentation-free anatomical priors for regularized brain positron emission tomography (PET) reconstruction. We derive the proximity operators for two PLS priors and use the EM-TV algorithm in combination with the first order primal-dual algorithm by Chambolle and Pock to solve the non-smooth optimization problem for PET reconstruction with PLS regularization. In addition, we compare the performance of two PLS versions against the symmetric and asymmetric Bowsher priors with quadratic and relative difference penalty function. For this aim, we first evaluate reconstructions of 30 noise realizations of simulated PET data derived from a real hybrid positron emission tomography/magnetic resonance imaging (PET/MR) acquisition in terms of regional bias and noise. Second, we evaluate reconstructions of a real brain PET/MR data set acquired on a GE Signa time-of-flight PET/MR in a similar way. The reconstructions of simulated and real 3D PET/MR data show that all priors were superior to post-smoothed maximum likelihood expectation maximization with ordered subsets (OSEM) in terms of bias-noise characteristics in different regions of interest where the PET uptake follows anatomical boundaries. Our implementation of the asymmetric Bowsher prior showed slightly superior performance compared with the two versions of PLS and the symmetric Bowsher prior. At very high regularization weights, all investigated anatomical priors suffer from the transfer of non-shared gradients.

摘要

在本文中,我们评估了平行水平集(PLS)和鲍舍方法作为正则化脑正电子发射断层扫描(PET)重建的无分割解剖先验。我们推导出了两个 PLS 先验的逼近算子,并使用 EM-TV 算法结合 Chambolle 和 Pock 的一阶原始对偶算法来解决具有 PLS 正则化的 PET 重建的非光滑优化问题。此外,我们将两种 PLS 版本的性能与具有二次和相对差罚函数的对称和不对称鲍舍先验进行了比较。为此,我们首先根据区域偏差和噪声评估了从真实混合正电子发射断层扫描/磁共振成像(PET/MR)采集中获得的 30 个模拟 PET 数据噪声实现的重建。其次,我们以类似的方式评估了在 GE Signa 飞行时间 PET/MR 上获得的真实脑 PET/MR 数据集的重建。模拟和真实的 3D PET/MR 数据的重建表明,所有先验都优于后平滑最大似然期望最大化有序子集(OSEM),在不同的感兴趣区域中,PET 摄取遵循解剖边界,其偏差噪声特性。我们对不对称鲍舍先验的实现表现出与两种 PLS 版本和对称鲍舍先验相比略优的性能。在非常高的正则化权重下,所有研究的解剖先验都受到非共享梯度转移的影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4426/5821901/de5fba721917/nihms940748f8.jpg
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