A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply

INTRODUCTION: Radiation-induced oxygen depletion in tissue is assumed as a contributor to the FLASH sparing effects. In this study, we simulated the heterogeneous oxygen depletion in the tissue surrounding the vessels and calculated the proton FLASH effective-dose-modifying factor (FEDMF), which cou...

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Autores principales: Zou, Wei, Kim, Haram, Diffenderfer, Eric S., Carlson, David J., Koch, Cameron J., Xiao, Ying, Teo, BoonKeng K., Kim, Michele M., Metz, James M., Fan, Yi, Maity, Amit, Koumenis, Costas, Busch, Theresa M., Wiersma, Rodney, Cengel, Keith A., Dong, Lei
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2022
Materias:
Oncology
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9742361/
https://www.ncbi.nlm.nih.gov/pubmed/36518319
http://dx.doi.org/10.3389/fonc.2022.1004121
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author Zou, Wei
Kim, Haram
Diffenderfer, Eric S.
Carlson, David J.
Koch, Cameron J.
Xiao, Ying
Teo, BoonKeng K.
Kim, Michele M.
Metz, James M.
Fan, Yi
Maity, Amit
Koumenis, Costas
Busch, Theresa M.
Wiersma, Rodney
Cengel, Keith A.
Dong, Lei
author_facet Zou, Wei
Kim, Haram
Diffenderfer, Eric S.
Carlson, David J.
Koch, Cameron J.
Xiao, Ying
Teo, BoonKeng K.
Kim, Michele M.
Metz, James M.
Fan, Yi
Maity, Amit
Koumenis, Costas
Busch, Theresa M.
Wiersma, Rodney
Cengel, Keith A.
Dong, Lei
author_sort Zou, Wei
collection PubMed
description INTRODUCTION: Radiation-induced oxygen depletion in tissue is assumed as a contributor to the FLASH sparing effects. In this study, we simulated the heterogeneous oxygen depletion in the tissue surrounding the vessels and calculated the proton FLASH effective-dose-modifying factor (FEDMF), which could be used for biology-based treatment planning. METHODS: The dose and dose-weighted linear energy transfer (LET) of a small animal proton irradiator was simulated with Monte Carlo simulation. We deployed a parabolic partial differential equation to account for the generalized radiation oxygen depletion, tissue oxygen diffusion, and metabolic processes to investigate oxygen distribution in 1D, 2D, and 3D solution space. Dose and dose rates, particle LET, vasculature spacing, and blood oxygen supplies were considered. Using a similar framework for the hypoxic reduction factor (HRF) developed previously, the FEDMF was derived as the ratio of the cumulative normoxic-equivalent dose (CNED) between CONV and UHDR deliveries. RESULTS: Dynamic equilibrium between oxygen diffusion and tissue metabolism can result in tissue hypoxia. The hypoxic region displayed enhanced radio-resistance and resulted in lower CNED under UHDR deliveries. In 1D solution, comparing 15 Gy proton dose delivered at CONV 0.5 and UHDR 125 Gy/s, 61.5% of the tissue exhibited ≥20% FEDMF at 175 μm vasculature spacing and 18.9 μM boundary condition. This percentage reduced to 34.5% and 0% for 8 and 2 Gy deliveries, respectively. Similar trends were observed in the 3D solution space. The FLASH versus CONV differential effect remained at larger vasculature spacings. A higher FLASH dose rate showed an increased region with ≥20% FEDMF. A higher LET near the proton Bragg peak region did not appear to alter the FLASH effect. CONCLUSION: We developed 1D, 2D, and 3D oxygen depletion simulation process to obtain the dynamic HRF and derive the proton FEDMF related to the dose delivery parameters and the local tissue vasculature information. The phenomenological model can be used to simulate or predict FLASH effects based on tissue vasculature and oxygen concentration data obtained from other experiments.
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spelling pubmed-97423612022-12-13 A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply Zou, Wei Kim, Haram Diffenderfer, Eric S. Carlson, David J. Koch, Cameron J. Xiao, Ying Teo, BoonKeng K. Kim, Michele M. Metz, James M. Fan, Yi Maity, Amit Koumenis, Costas Busch, Theresa M. Wiersma, Rodney Cengel, Keith A. Dong, Lei Front Oncol Oncology INTRODUCTION: Radiation-induced oxygen depletion in tissue is assumed as a contributor to the FLASH sparing effects. In this study, we simulated the heterogeneous oxygen depletion in the tissue surrounding the vessels and calculated the proton FLASH effective-dose-modifying factor (FEDMF), which could be used for biology-based treatment planning. METHODS: The dose and dose-weighted linear energy transfer (LET) of a small animal proton irradiator was simulated with Monte Carlo simulation. We deployed a parabolic partial differential equation to account for the generalized radiation oxygen depletion, tissue oxygen diffusion, and metabolic processes to investigate oxygen distribution in 1D, 2D, and 3D solution space. Dose and dose rates, particle LET, vasculature spacing, and blood oxygen supplies were considered. Using a similar framework for the hypoxic reduction factor (HRF) developed previously, the FEDMF was derived as the ratio of the cumulative normoxic-equivalent dose (CNED) between CONV and UHDR deliveries. RESULTS: Dynamic equilibrium between oxygen diffusion and tissue metabolism can result in tissue hypoxia. The hypoxic region displayed enhanced radio-resistance and resulted in lower CNED under UHDR deliveries. In 1D solution, comparing 15 Gy proton dose delivered at CONV 0.5 and UHDR 125 Gy/s, 61.5% of the tissue exhibited ≥20% FEDMF at 175 μm vasculature spacing and 18.9 μM boundary condition. This percentage reduced to 34.5% and 0% for 8 and 2 Gy deliveries, respectively. Similar trends were observed in the 3D solution space. The FLASH versus CONV differential effect remained at larger vasculature spacings. A higher FLASH dose rate showed an increased region with ≥20% FEDMF. A higher LET near the proton Bragg peak region did not appear to alter the FLASH effect. CONCLUSION: We developed 1D, 2D, and 3D oxygen depletion simulation process to obtain the dynamic HRF and derive the proton FEDMF related to the dose delivery parameters and the local tissue vasculature information. The phenomenological model can be used to simulate or predict FLASH effects based on tissue vasculature and oxygen concentration data obtained from other experiments. Frontiers Media S.A. 2022-11-28 /pmc/articles/PMC9742361/ /pubmed/36518319 http://dx.doi.org/10.3389/fonc.2022.1004121 Text en Copyright © 2022 Zou, Kim, Diffenderfer, Carlson, Koch, Xiao, Teo, Kim, Metz, Fan, Maity, Koumenis, Busch, Wiersma, Cengel and Dong https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Oncology
Zou, Wei
Kim, Haram
Diffenderfer, Eric S.
Carlson, David J.
Koch, Cameron J.
Xiao, Ying
Teo, BoonKeng K.
Kim, Michele M.
Metz, James M.
Fan, Yi
Maity, Amit
Koumenis, Costas
Busch, Theresa M.
Wiersma, Rodney
Cengel, Keith A.
Dong, Lei
A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply
title A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply
title_full A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply
title_fullStr A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply
title_full_unstemmed A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply
title_short A phenomenological model of proton FLASH oxygen depletion effects depending on tissue vasculature and oxygen supply
title_sort phenomenological model of proton flash oxygen depletion effects depending on tissue vasculature and oxygen supply
topic Oncology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9742361/
https://www.ncbi.nlm.nih.gov/pubmed/36518319
http://dx.doi.org/10.3389/fonc.2022.1004121
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