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Main Authors: Wu, Jia-Mian, Liu, Jun, Li, Siqi, Wang, Xiaoya, Yin, Shibai, Luo, Huanyu, Zheng, Lingling, Gao, Qiang, Yang, Jigang, Jiang, Tai-Xiang
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.22894
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author Wu, Jia-Mian
Liu, Jun
Li, Siqi
Wang, Xiaoya
Yin, Shibai
Luo, Huanyu
Zheng, Lingling
Gao, Qiang
Yang, Jigang
Jiang, Tai-Xiang
author_facet Wu, Jia-Mian
Liu, Jun
Li, Siqi
Wang, Xiaoya
Yin, Shibai
Luo, Huanyu
Zheng, Lingling
Gao, Qiang
Yang, Jigang
Jiang, Tai-Xiang
contents Computed tomography (CT)-based attenuation and scatter correction improves quantitative PET but adds radiation exposure that is particularly undesirable in pediatric imaging. Existing CT-free methods are commonly trained in homogeneous settings and often degrade under scanner or radiotracer shifts, which limits their clinical utility. We propose the Generalizable PET Correction Network (GPCN), a dual-domain network for domain-robust CT-free PET attenuation and scatter correction. GPCN combines a multi-band contextual refinement module, which models pediatric anatomical variability through wavelet-based multiscale decomposition and long-range spatial context modeling, with a frequency-aware spectral decoupling module, which performs coordinate-conditioned amplitude/phase refinement in the Fourier domain. By synergizing multi-band spatial contextual modeling with asymmetric frequency-spectrum decoupling, the network explicitly separates invariant topological structures from domain-specific noise, thereby achieving precise quantitative recovery of both anatomical organs and focal lesions. This design aims to separate anatomy-dominant structures from domain-sensitive spectral residuals and to improve robustness across heterogeneous imaging conditions. We train and evaluate the method on 1085 pediatric whole-body PET scans acquired with two scanners and five radiotracers. In both joint training and zero-shot cross-domain evaluation, GPCN outperforms representative baselines and maintains stable quantitative accuracy on unseen scanner-tracer combinations. The method is further supported by ablation, region-wise quantitative analysis, and downstream segmentation experiments. In our cohort, the CT component of the conventional protocol corresponded to an average effective dose of 10.8 mSv, indicating the potential clinical value of reliable CT-free correction for pediatric PET.
format Preprint
id arxiv_https___arxiv_org_abs_2604_22894
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Generalizable CT-Free PET Attenuation and Scatter Correction for Pediatric Patients
Wu, Jia-Mian
Liu, Jun
Li, Siqi
Wang, Xiaoya
Yin, Shibai
Luo, Huanyu
Zheng, Lingling
Gao, Qiang
Yang, Jigang
Jiang, Tai-Xiang
Image and Video Processing
Computer Vision and Pattern Recognition
Computed tomography (CT)-based attenuation and scatter correction improves quantitative PET but adds radiation exposure that is particularly undesirable in pediatric imaging. Existing CT-free methods are commonly trained in homogeneous settings and often degrade under scanner or radiotracer shifts, which limits their clinical utility. We propose the Generalizable PET Correction Network (GPCN), a dual-domain network for domain-robust CT-free PET attenuation and scatter correction. GPCN combines a multi-band contextual refinement module, which models pediatric anatomical variability through wavelet-based multiscale decomposition and long-range spatial context modeling, with a frequency-aware spectral decoupling module, which performs coordinate-conditioned amplitude/phase refinement in the Fourier domain. By synergizing multi-band spatial contextual modeling with asymmetric frequency-spectrum decoupling, the network explicitly separates invariant topological structures from domain-specific noise, thereby achieving precise quantitative recovery of both anatomical organs and focal lesions. This design aims to separate anatomy-dominant structures from domain-sensitive spectral residuals and to improve robustness across heterogeneous imaging conditions. We train and evaluate the method on 1085 pediatric whole-body PET scans acquired with two scanners and five radiotracers. In both joint training and zero-shot cross-domain evaluation, GPCN outperforms representative baselines and maintains stable quantitative accuracy on unseen scanner-tracer combinations. The method is further supported by ablation, region-wise quantitative analysis, and downstream segmentation experiments. In our cohort, the CT component of the conventional protocol corresponded to an average effective dose of 10.8 mSv, indicating the potential clinical value of reliable CT-free correction for pediatric PET.
title Generalizable CT-Free PET Attenuation and Scatter Correction for Pediatric Patients
topic Image and Video Processing
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2604.22894