99mTc/123I Dual-Radionuclide Correction for Self-Scatter, Down-Scatter, and Tailing Effect for a CZT SPECT with Varying Tracer Distributions.

IF 4.6 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Alexandre F Velo, Peng Fan, Huidong Xie, Xiongchao Chen, Nabil Boutagy, Attila Feher, Albert J Sinusas, Michael Ljungberg, Chi Liu
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引用次数: 0

Abstract

SPECT systems distinguish radionuclides by using multiple energy windows. For CZT detectors, the energy spectrum has a low energy tail leading to additional crosstalk between the radionuclides. Previous work developed models to correct the scatter and crosstalk for CZT-based dedicated cardiac systems with similar 99mTc/123I tracer distributions. These models estimate the primary and scatter components by solving a set of equations employing the MLEM approach. A penalty term is applied to ensure convergence. The present work estimates the penalty term for any 99mTc/123I activity level. An iterative approach incorporating Monte Carlo into the iterative image reconstruction loops was developed to estimate the penalty terms. We used SIMIND and XCAT phantoms in this study. Distribution of tracers in the myocardial tissue and blood pool were varied to simulate a dynamic acquisition. Evaluations of the estimated and the real penalty terms were performed using simulations and large animal data. The myocardium to blood pool ratio was calculated using ROIs in the myocardial tissue and the blood pool for quantitative analysis. All corrected images yielded a good agreement with the gold standard images. In conclusion, we developed a CZT crosstalk correction method for quantitative imaging of 99mTc/123I activity levels by dynamically estimating the penalty terms.

99mTc/123I 双放射性核素对具有不同示踪剂分布的 CZT SPECT 的自散射、向下散射和尾随效应的校正。
SPECT 系统通过使用多个能量窗口来区分放射性核素。对于 CZT 检测器来说,能谱有一个低能尾,导致放射性核素之间产生额外的串扰。之前的工作开发了一些模型,用于校正基于 CZT 的专用心脏系统的散射和串扰,这些系统具有类似的 99mTc/123I 示踪剂分布。这些模型通过求解一组采用 MLEM 方法的方程来估计主成分和散射成分。为确保收敛性,采用了惩罚项。本研究针对任何 99mTc/123I 放射性活度水平估算惩罚项。为了估算惩罚项,我们开发了一种将蒙特卡罗纳入迭代图像重建循环的迭代方法。我们在这项研究中使用了 SIMIND 和 XCAT 模型。示踪剂在心肌组织和血池中的分布各不相同,以模拟动态采集。利用模拟和大型动物数据对估计和实际惩罚项进行了评估。使用心肌组织和血池中的 ROI 计算心肌与血池的比率,以进行定量分析。所有校正后的图像都与金标准图像有很好的一致性。总之,我们开发了一种 CZT 串扰校正方法,通过动态估算惩罚项对 99mTc/123I 活性水平进行定量成像。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
IEEE Transactions on Radiation and Plasma Medical Sciences
IEEE Transactions on Radiation and Plasma Medical Sciences RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
8.00
自引率
18.20%
发文量
109
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