Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams

Real time radioluminescence fibre-based detectors were investigated for application in proton, helium, and carbon therapy dosimetry. The Al(2)O(3):C probes are made of one single crystal (1 mm) and two droplets of micro powder in two sizes (38 μm and 4 μm) mixed with a water-equivalent binder. The f...

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Autores principales: de Freitas Nascimento, Luana, Leblans, Paul, van der Heyden, Brent, Akselrod, Mark, Goossens, Jo, Correa Rocha, Luis Enrique, Vaniqui, Ana, Verellen, Dirk
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2022
Materias:
Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9737660/
https://www.ncbi.nlm.nih.gov/pubmed/36501879
http://dx.doi.org/10.3390/s22239178
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author de Freitas Nascimento, Luana
Leblans, Paul
van der Heyden, Brent
Akselrod, Mark
Goossens, Jo
Correa Rocha, Luis Enrique
Vaniqui, Ana
Verellen, Dirk
author_facet de Freitas Nascimento, Luana
Leblans, Paul
van der Heyden, Brent
Akselrod, Mark
Goossens, Jo
Correa Rocha, Luis Enrique
Vaniqui, Ana
Verellen, Dirk
author_sort de Freitas Nascimento, Luana
collection PubMed
description Real time radioluminescence fibre-based detectors were investigated for application in proton, helium, and carbon therapy dosimetry. The Al(2)O(3):C probes are made of one single crystal (1 mm) and two droplets of micro powder in two sizes (38 μm and 4 μm) mixed with a water-equivalent binder. The fibres were irradiated behind different thicknesses of solid slabs, and the Bragg curves presented a quenching effect attributed to the nonlinear response of the radioluminescence (RL) signal as a function of linear energy transfer (LET). Experimental data and Monte Carlo simulations were utilised to acquire a quenching correction method, adapted from Birks’ formulation, to restore the linear dose–response for particle therapy beams. The method for quenching correction was applied and yielded the best results for the ‘4 μm’ optical fibre probe, with an agreement at the Bragg peak of 1.4% (160 MeV), and 1.5% (230 MeV) for proton-charged particles; 2.4% (150 MeV/u) for helium-charged particles and of 4.8% (290 MeV/u) and 2.9% (400 MeV/u) for the carbon-charged particles. The most substantial deviations for the ‘4 μm’ optical fibre probe were found at the falloff regions, with ~3% (protons), ~5% (helium) and 6% (carbon).
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spelling pubmed-97376602022-12-11 Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams de Freitas Nascimento, Luana Leblans, Paul van der Heyden, Brent Akselrod, Mark Goossens, Jo Correa Rocha, Luis Enrique Vaniqui, Ana Verellen, Dirk Sensors (Basel) Article Real time radioluminescence fibre-based detectors were investigated for application in proton, helium, and carbon therapy dosimetry. The Al(2)O(3):C probes are made of one single crystal (1 mm) and two droplets of micro powder in two sizes (38 μm and 4 μm) mixed with a water-equivalent binder. The fibres were irradiated behind different thicknesses of solid slabs, and the Bragg curves presented a quenching effect attributed to the nonlinear response of the radioluminescence (RL) signal as a function of linear energy transfer (LET). Experimental data and Monte Carlo simulations were utilised to acquire a quenching correction method, adapted from Birks’ formulation, to restore the linear dose–response for particle therapy beams. The method for quenching correction was applied and yielded the best results for the ‘4 μm’ optical fibre probe, with an agreement at the Bragg peak of 1.4% (160 MeV), and 1.5% (230 MeV) for proton-charged particles; 2.4% (150 MeV/u) for helium-charged particles and of 4.8% (290 MeV/u) and 2.9% (400 MeV/u) for the carbon-charged particles. The most substantial deviations for the ‘4 μm’ optical fibre probe were found at the falloff regions, with ~3% (protons), ~5% (helium) and 6% (carbon). MDPI 2022-11-25 /pmc/articles/PMC9737660/ /pubmed/36501879 http://dx.doi.org/10.3390/s22239178 Text en © 2022 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
de Freitas Nascimento, Luana
Leblans, Paul
van der Heyden, Brent
Akselrod, Mark
Goossens, Jo
Correa Rocha, Luis Enrique
Vaniqui, Ana
Verellen, Dirk
Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams
title Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams
title_full Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams
title_fullStr Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams
title_full_unstemmed Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams
title_short Characterisation and Quenching Correction for an Al(2)O(3):C Optical Fibre Real Time System in Therapeutic Proton, Helium, and Carbon-Charged Beams
title_sort characterisation and quenching correction for an al(2)o(3):c optical fibre real time system in therapeutic proton, helium, and carbon-charged beams
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9737660/
https://www.ncbi.nlm.nih.gov/pubmed/36501879
http://dx.doi.org/10.3390/s22239178
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