A computational model of radiolytic oxygen depletion during FLASH irradiation and its effect on the oxygen enhancement ratio
Guillem Pratx, Daniel S Kapp

TL;DR
This paper presents a computational model explaining the FLASH irradiation effect as resulting from radiolytic oxygen depletion, which temporarily reduces cellular radiosensitivity, especially in hypoxic tissues, potentially reducing normal tissue toxicity.
Contribution
It introduces a new model linking radiolytic oxygen depletion to the FLASH effect, providing testable predictions about irradiation parameters and tissue oxygenation.
Findings
FLASH effect diminishes with longer pulse durations
Fewer radiation pulses enhance the FLASH effect
Hypoxic cells are more likely to exhibit the FLASH effect
Abstract
Recent results from animal irradiation studies have rekindled interest in the potential of ultra-high dose rate irradiation (also known as FLASH) for reducing normal tissue toxicity. However, despite mounting evidence of a "FLASH effect", a mechanism has yet to be elucidated. This article hypothesizes that the radioprotecting effect of FLASH irradiation could be due to the specific sparing of hypoxic stem cell niches, which have been identified in several organs including the bone marrow and the brain. To explore this hypothesis, a new computational model is presented that frames transient radiolytic oxygen depletion (ROD) during FLASH irradiation in terms of its effect on the oxygen enhancement ratio (OER). The model takes into consideration oxygen diffusion through the tissue, its consumption by metabolic cells, and its radiolytic depletion to estimate the relative decrease in…
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