用于定量心脏PET的包含飞行时间和点扩散函数建模的图像重建算法评估：体模研究

Evaluation of image reconstruction algorithms encompassing Time-Of-Flight and Point Spread Function modelling for quantitative cardiac PET: phantom studies.

作者信息

Presotto L, Gianolli L, Gilardi M C, Bettinardi V

机构信息

Nuclear Medicine Unit, IRCCS Ospedale San Raffaele, Milan, Italy,

出版信息

J Nucl Cardiol. 2015 Apr;22(2):351-63. doi: 10.1007/s12350-014-0023-1. Epub 2014 Nov 4.

DOI:10.1007/s12350-014-0023-1

PMID:25367452

Abstract

BACKGROUND

To perform kinetic modelling quantification, PET dynamic data must be acquired in short frames, where different critical conditions are met. The accuracy of reconstructed images influences quantification. The added value of Time-Of-Flight (TOF) and Point Spread Function (PSF) in cardiac image reconstruction was assessed.

METHODS

A static phantom was used to simulate two extreme conditions: (i) the bolus passage and (ii) the steady uptake. Various count statistics and independent noise realisations were considered. A moving phantom filled with two different radionuclides was used to simulate: (i) a great range of contrasts and (ii) the cardio/respiratory motion. Analytical and iterative reconstruction (IR) algorithms also encompassing TOF and PSF modelling were evaluated.

RESULTS

Both analytic and IR algorithms provided good results in all the evaluated conditions. The amount of bias introduced by IR was found to be limited. TOF allowed faster convergence and lower noise levels. PSF achieved near full myocardial activity recovery in static conditions. Motion degraded performances, but the addition of both TOF and PSF maintained the best overall behaviour.

CONCLUSIONS

IR accounting for TOF and PSF can be recommended for the quantification of dynamic cardiac PET studies as they improve the results compared to analytic and standard IR.

摘要

背景

为了进行动力学建模定量分析，必须在满足不同关键条件的短时间帧内采集PET动态数据。重建图像的准确性会影响定量分析。评估了飞行时间（TOF）和点扩散函数（PSF）在心脏图像重建中的附加价值。

方法

使用静态体模模拟两种极端情况：（i）团注通过和（ii）稳定摄取。考虑了各种计数统计和独立的噪声实现。使用填充有两种不同放射性核素的移动体模来模拟：（i）大范围的对比度和（ii）心脏/呼吸运动。还评估了包括TOF和PSF建模的解析和迭代重建（IR）算法。

结果

解析算法和IR算法在所有评估条件下均提供了良好的结果。发现IR引入的偏差量有限。TOF允许更快的收敛和更低的噪声水平。在静态条件下，PSF实现了近乎完全的心肌活性恢复。运动降低了性能，但同时添加TOF和PSF可保持最佳的整体性能。

结论

对于动态心脏PET研究的定量分析，推荐使用考虑TOF和PSF的IR，因为与解析和标准IR相比，它们能改善结果。

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用于定量心脏PET的包含飞行时间和点扩散函数建模的图像重建算法评估：体模研究

Evaluation of image reconstruction algorithms encompassing Time-Of-Flight and Point Spread Function modelling for quantitative cardiac PET: phantom studies.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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