衰减校正全身PET的快速贝叶斯技术

1993 IEEE Conference Record Nuclear Science Symposium and Medical Imaging Conference Pub Date : 1993-10-31 DOI:10.1109/NSSMIC.1993.373625

E. Mumcuoglu, R. Leahy, S. Cherry

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引用次数: 1

摘要

作者描述了用于透射和发射PET图像重建的共轭梯度算法。重建基于贝叶斯公式，其中数据被建模为独立泊松随机变量的集合，图像使用马尔可夫随机场建模。为了保证解的非负性，利用罚函数将问题转化为无约束优化问题。使用前置条件提高收敛速度。这些方法通常在15-25次迭代中实现有效的收敛。利用西门子/CTI ECAT931全身系统采集的数据，对/sup 18/FDG全身扫描进行了重建。这些结果表明，与滤波后的反向投影相比，使用贝叶斯方法可以显著改善发射图像的质量，特别是当使用MAP传输图像的重新投影来代替标准衰减校正因子时

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Fast Bayesian techniques for attenuation corrected whole-body PET

The authors describe conjugate gradient algorithms for reconstruction of transmission and emission PET images. The reconstructions are based on a Bayesian formulation where the data are modeled as a collection of independent Poisson random variables and the image is modeled using a Markov random field. To ensure non-negativity of the solution a penalty function is used to convert the problem to one of unconstrained optimization. Preconditioners are used to enhance convergence rates. These methods generally achieve effective convergence in 15-25 iterations. Reconstructions are presented of an /sup 18/FDG whole body scan from data collected using a Siemens/CTI ECAT931 whole body system. These results indicate significant improvements in emission image quality using the Bayesian approach, in comparison to filtered backprojection, particularly when reprojections of the MAP transmission image are used in place of the standard attenuation correction factors.<>

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1993 IEEE Conference Record Nuclear Science Symposium and Medical Imaging Conference

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