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Autori principali: Lin, Boheng, Xie, Zizhuo, Zhang, Bo, Wan, Lin, Qiu, Ao, Xie, Qingguo
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2507.13118
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author Lin, Boheng
Xie, Zizhuo
Zhang, Bo
Wan, Lin
Qiu, Ao
Xie, Qingguo
author_facet Lin, Boheng
Xie, Zizhuo
Zhang, Bo
Wan, Lin
Qiu, Ao
Xie, Qingguo
contents In positron emission tomography (PET), a clear theoretical model describing how system sensitivity varies as a source is moved trans-axially within the field of view (FOV) is lacking. The current understanding and practical intuition often suggest that sensitivity is maximum at the center of the FOV, an assumption reflected in standardized protocols. In this work, we derive an analytic model for the trans-axial-plane sensitivity distribution in a cylindrical PET scanner based on solid angle. The model, formulated as a function of trans-axial offset from the center, is validated through both Monte Carlo simulations and physical experiments on a representative system. We find that the derived theoretical distribution is essentially consistent with simulation and experimental results, revealing a non-intuitive feature: sensitivity increases with trans-axial offset, peaks at the edge of the FOV, and drops off sharply beyond it. This study provides the first closed-form model of trans-axial geometric sensitivity in cylindrical PET scanners, offering a vital benchmark for isolating detector technology improvements and revealing a non-intuitive, offset-dependent sensitivity profile that enables new protocol optimization strategies.
format Preprint
id arxiv_https___arxiv_org_abs_2507_13118
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Analytic Model of Trans-axial Sensitivity in Cylindrical PET Systems Based on Solid Angle
Lin, Boheng
Xie, Zizhuo
Zhang, Bo
Wan, Lin
Qiu, Ao
Xie, Qingguo
Medical Physics
In positron emission tomography (PET), a clear theoretical model describing how system sensitivity varies as a source is moved trans-axially within the field of view (FOV) is lacking. The current understanding and practical intuition often suggest that sensitivity is maximum at the center of the FOV, an assumption reflected in standardized protocols. In this work, we derive an analytic model for the trans-axial-plane sensitivity distribution in a cylindrical PET scanner based on solid angle. The model, formulated as a function of trans-axial offset from the center, is validated through both Monte Carlo simulations and physical experiments on a representative system. We find that the derived theoretical distribution is essentially consistent with simulation and experimental results, revealing a non-intuitive feature: sensitivity increases with trans-axial offset, peaks at the edge of the FOV, and drops off sharply beyond it. This study provides the first closed-form model of trans-axial geometric sensitivity in cylindrical PET scanners, offering a vital benchmark for isolating detector technology improvements and revealing a non-intuitive, offset-dependent sensitivity profile that enables new protocol optimization strategies.
title Analytic Model of Trans-axial Sensitivity in Cylindrical PET Systems Based on Solid Angle
topic Medical Physics
url https://arxiv.org/abs/2507.13118