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Main Authors: Pour, Seyed Amir Zaman, Rezaei, Ahmadreza, Jansen, Floris, Baete, Kristof, Schramm, Georg, Nuyts, Johan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.15969
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author Pour, Seyed Amir Zaman
Rezaei, Ahmadreza
Jansen, Floris
Baete, Kristof
Schramm, Georg
Nuyts, Johan
author_facet Pour, Seyed Amir Zaman
Rezaei, Ahmadreza
Jansen, Floris
Baete, Kristof
Schramm, Georg
Nuyts, Johan
contents PET requires accurate, precise, and efficient scatter correction techniques. Conventional scatter estimation typically relies on tail-fitted single-scatter simulation (SSS) strategy. However, the accuracy of tail-fitted SSS is limited, for example, by mismatches between the attenuation image and the PET emission data or by the presence of activity outside the FOV. These shortcomings can be addressed using energy-based scatter estimation (EBSE), as recently proposed by Efthimiou et al. and Hamill et al. The aim of this work is to 1. improve the accuracy of EBSE by accounting for the LOR dependence of the energy spectrum of unscattered photons, 2. improve the computational speed of EBSE through better initialization and a more efficient optimization algorithm. The proposed improved EBSE method models the energy probability density function (PDF) of both single and multiple scattered photons, and incorporates a position-dependent energy PDF for unscattered photons. These energy PDFs form the basis of two forward models used for scatter estimation based on 2D energy histograms. The performance of these models were evaluated using GATE Monte Carlo simulations and a NEMA phantom acquisition on a GE SIGNA PET/MR scanner. Furthermore, we assessed the stability of EBSE across the forward models by varying the number of counts in the 2D energy histograms via data mashing. EBSE outperformed tail-fitted SSS, particularly in regions near out-of-FOV activity. Our GATE simulations showed that incorporating a local energy for unscattered photons improves off-center regional quantification by approximately 2% points. Additionally, improved initialization combined with the NEGML optimizer enabling execution on a mashed TOF sinogram in 12 minutes on six-core CPU. The proposed method enhances both the accuracy and computational efficiency of EBSE, making it well-suited for clinical applications.
format Preprint
id arxiv_https___arxiv_org_abs_2504_15969
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Improved energy-based scatter estimation by incorporating local energy spectra and accelerating the parametric fitting
Pour, Seyed Amir Zaman
Rezaei, Ahmadreza
Jansen, Floris
Baete, Kristof
Schramm, Georg
Nuyts, Johan
Medical Physics
PET requires accurate, precise, and efficient scatter correction techniques. Conventional scatter estimation typically relies on tail-fitted single-scatter simulation (SSS) strategy. However, the accuracy of tail-fitted SSS is limited, for example, by mismatches between the attenuation image and the PET emission data or by the presence of activity outside the FOV. These shortcomings can be addressed using energy-based scatter estimation (EBSE), as recently proposed by Efthimiou et al. and Hamill et al. The aim of this work is to 1. improve the accuracy of EBSE by accounting for the LOR dependence of the energy spectrum of unscattered photons, 2. improve the computational speed of EBSE through better initialization and a more efficient optimization algorithm. The proposed improved EBSE method models the energy probability density function (PDF) of both single and multiple scattered photons, and incorporates a position-dependent energy PDF for unscattered photons. These energy PDFs form the basis of two forward models used for scatter estimation based on 2D energy histograms. The performance of these models were evaluated using GATE Monte Carlo simulations and a NEMA phantom acquisition on a GE SIGNA PET/MR scanner. Furthermore, we assessed the stability of EBSE across the forward models by varying the number of counts in the 2D energy histograms via data mashing. EBSE outperformed tail-fitted SSS, particularly in regions near out-of-FOV activity. Our GATE simulations showed that incorporating a local energy for unscattered photons improves off-center regional quantification by approximately 2% points. Additionally, improved initialization combined with the NEGML optimizer enabling execution on a mashed TOF sinogram in 12 minutes on six-core CPU. The proposed method enhances both the accuracy and computational efficiency of EBSE, making it well-suited for clinical applications.
title Improved energy-based scatter estimation by incorporating local energy spectra and accelerating the parametric fitting
topic Medical Physics
url https://arxiv.org/abs/2504.15969