Direct Reconstruction of CT-based Attenuation Correction Images for PET with Cluster-Based Penalties.

Soo Mee Kim, Adam M Alessio, Bruno De Man, Evren Asma, Paul E Kinahan
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引用次数: 3

Abstract

Extremely low-dose CT acquisitions for the purpose of PET attenuation correction will have a high level of noise and biasing artifacts due to factors such as photon starvation. This work explores a priori knowledge appropriate for CT iterative image reconstruction for PET attenuation correction. We investigate the maximum a posteriori (MAP) framework with cluster-based, multinomial priors for the direct reconstruction of the PET attenuation map. The objective function for direct iterative attenuation map reconstruction was modeled as a Poisson log-likelihood with prior terms consisting of quadratic (Q) and mixture (M) distributions. The attenuation map is assumed to have values in 4 clusters: air+background, lung, soft tissue, and bone. Under this assumption, the MP was a mixture probability density function consisting of one exponential and three Gaussian distributions. The relative proportion of each cluster was jointly estimated during each voxel update of direct iterative coordinate decent (dICD) method. Noise-free data were generated from NCAT phantom and Poisson noise was added. Reconstruction with FBP (ramp filter) was performed on the noise-free (ground truth) and noisy data. For the noisy data, dICD reconstruction was performed with the combination of different prior strength parameters (β and γ) of Q- and M-penalties. The combined quadratic and mixture penalties reduces the RMSE by 18.7% compared to post-smoothed iterative reconstruction and only 0.7% compared to quadratic alone. For direct PET attenuation map reconstruction from ultra-low dose CT acquisitions, the combination of quadratic and mixture priors offers regularization of both variance and bias and is a potential method to derive attenuation maps with negligible patient dose. However, the small improvement in quantitative accuracy relative to the substantial increase in algorithm complexity does not currently justify the use of mixture-based PET attenuation priors for reconstruction of CT images for PET attenuation correction.

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基于聚类惩罚的PET ct衰减校正图像直接重建
由于光子饥饿等因素,用于PET衰减校正的极低剂量CT采集将具有高水平的噪声和偏置伪影。本研究探索了一种适用于PET衰减校正的CT迭代图像重建的先验知识。我们研究了基于聚类的多项式先验的最大后验(MAP)框架,用于PET衰减图的直接重建。直接迭代衰减图重建的目标函数采用泊松对数似然模型,先验项由二次分布(Q)和混合分布(M)组成。衰减图假定在4个簇中有值:空气+背景、肺、软组织和骨。在此假设下,mps是由一个指数分布和三个高斯分布组成的混合概率密度函数。直接迭代坐标变换(dICD)方法在每次体素更新时,联合估计每个聚类的相对比例。利用NCAT模型生成无噪声数据,并加入泊松噪声。对无噪声(地真值)和有噪声数据分别进行了斜坡滤波重构。对于噪声数据,结合Q和m惩罚的不同先验强度参数(β和γ)进行dICD重建。与后平滑迭代重建相比,二次元惩罚和混合惩罚相结合的RMSE降低了18.7%,而与单独二次元惩罚相比,RMSE仅降低了0.7%。对于从超低剂量CT采集中直接重建PET衰减图,二次先验和混合先验的组合提供了方差和偏差的正则化,是一种推导患者剂量可忽略的衰减图的潜在方法。然而,相对于算法复杂度的大幅增加,定量精度的小幅提高目前不足以证明使用基于混合的PET衰减先验来重建CT图像以进行PET衰减校正。
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