Enregistré dans:
Détails bibliographiques
Auteurs principaux: Bauer, Cornelius J., Schneider, Frank, Göbel, Ida D., Oppitz, Hans, Giordano, Frank A., Fleckenstein, Jens
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2509.04933
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866918498783985664
author Bauer, Cornelius J.
Schneider, Frank
Göbel, Ida D.
Oppitz, Hans
Giordano, Frank A.
Fleckenstein, Jens
author_facet Bauer, Cornelius J.
Schneider, Frank
Göbel, Ida D.
Oppitz, Hans
Giordano, Frank A.
Fleckenstein, Jens
contents Introduction: Real-time dosimetry of surface doses in electron beams has not been widely established yet. Plastic scintillation detectors (PSD) promise high spatial resolution and real-time dosimetry with minimum perturbation of the radiation field. This study characterizes a novel PSD in an electron beam to determine its suitability for in vivo dosimetry. Methods: Dual-channel Cherenkov radiation correction and dosimetric characterization of the PSD were investigated using reference ionization chambers. Percentage depth-dose curves, lateral profiles, and output factors were compared with reference ionization chamber measurements. Surface doses were measured on solid water and on an anthropomorphic phantom and were compared to ionization chamber and radiochromic film measurements. Results: The investigated PSD demonstrated clinically acceptable linearity, dose rate independence, isotropy and reproducibility (total variation <2%). Dosimetric deviation in R50 and R80 were below 1.0 mm and lateral profiles agreed with a mean absolute error below 1.5%. Small field measurements were within 2% of the reference ionization chamber results. Surface dose measurements had mean relative deviations of 1.3% from ionization chamber measurements and 2.1% from radiochromic film measurements. Conclusion: The PSD investigated in this study is suitable for clinically acceptable electron beam dosimetry and provides accurate dosimetric results for surface dose measurements. It has the potential to be used for real-time in vivo dosimetry.
format Preprint
id arxiv_https___arxiv_org_abs_2509_04933
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Characterization of a novel plastic scintillation detector for in vivo electron dosimetry
Bauer, Cornelius J.
Schneider, Frank
Göbel, Ida D.
Oppitz, Hans
Giordano, Frank A.
Fleckenstein, Jens
Medical Physics
Introduction: Real-time dosimetry of surface doses in electron beams has not been widely established yet. Plastic scintillation detectors (PSD) promise high spatial resolution and real-time dosimetry with minimum perturbation of the radiation field. This study characterizes a novel PSD in an electron beam to determine its suitability for in vivo dosimetry. Methods: Dual-channel Cherenkov radiation correction and dosimetric characterization of the PSD were investigated using reference ionization chambers. Percentage depth-dose curves, lateral profiles, and output factors were compared with reference ionization chamber measurements. Surface doses were measured on solid water and on an anthropomorphic phantom and were compared to ionization chamber and radiochromic film measurements. Results: The investigated PSD demonstrated clinically acceptable linearity, dose rate independence, isotropy and reproducibility (total variation <2%). Dosimetric deviation in R50 and R80 were below 1.0 mm and lateral profiles agreed with a mean absolute error below 1.5%. Small field measurements were within 2% of the reference ionization chamber results. Surface dose measurements had mean relative deviations of 1.3% from ionization chamber measurements and 2.1% from radiochromic film measurements. Conclusion: The PSD investigated in this study is suitable for clinically acceptable electron beam dosimetry and provides accurate dosimetric results for surface dose measurements. It has the potential to be used for real-time in vivo dosimetry.
title Characterization of a novel plastic scintillation detector for in vivo electron dosimetry
topic Medical Physics
url https://arxiv.org/abs/2509.04933