Modelling radiobiology

Lydia L Gardner; Shannon J Thompson; John D O'Connor; Stephen J McMahon

doi:10.1088/1361-6560/ad70f0

Modelling radiobiology

Lydia L Gardner
, Shannon J Thompson
, John D O'Connor
, Stephen J McMahon^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

10 Citations (Scopus)

38 Downloads (Pure)

Abstract

Radiotherapy has played an essential role in cancer treatment for over a century, and remains one of the best-studied methods of cancer treatment. Because of its close links with the physical sciences, it has been the subject of extensive quantitative mathematical modelling, but a complete understanding of the mechanisms of radiotherapy has remained elusive. In part this is because of the complexity and range of scales involved in radiotherapy—from physical radiation interactions occurring over nanometres to evolution of patient responses over months and years. This review presents the current status and ongoing research in modelling radiotherapy responses across these scales, including basic physical mechanisms of DNA damage, the immediate biological responses this triggers, and genetic- and patient-level determinants of response. Finally, some of the major challenges in this field and potential avenues for future improvements are also discussed.

Original language	English
Article number	18TR01
Number of pages	40
Journal	Physics in Medicine & Biology
Volume	69
Issue number	18
Early online date	02 Sept 2024
DOIs	https://doi.org/10.1088/1361-6560/ad70f0
Publication status	Published - 21 Sept 2024

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

DNA repair
Monte Carlo
cell death
modelling
radiobiology

Access to Document

10.1088/1361-6560/ad70f0Licence: CC BY

Modelling radiobiology
Copyright 2024 The Authors. This is an open access article published under a Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium, provided the author and source are cited.
Final published version, 2.58 MBLicence: CC BY

Quantifying the impact of DNA repair dysregulation on intrinsic radiation sensitivity
Gardner, L. (Author), McMahon, S. (Supervisor) & Butterworth, K. (Supervisor), Dec 2025
Student thesis: Doctoral Thesis › Doctor of Philosophy

Cite this

@article{4feef6dedba2473b9aa86fd99b5230be,

title = "Modelling radiobiology",

abstract = "Radiotherapy has played an essential role in cancer treatment for over a century, and remains one of the best-studied methods of cancer treatment. Because of its close links with the physical sciences, it has been the subject of extensive quantitative mathematical modelling, but a complete understanding of the mechanisms of radiotherapy has remained elusive. In part this is because of the complexity and range of scales involved in radiotherapy—from physical radiation interactions occurring over nanometres to evolution of patient responses over months and years. This review presents the current status and ongoing research in modelling radiotherapy responses across these scales, including basic physical mechanisms of DNA damage, the immediate biological responses this triggers, and genetic- and patient-level determinants of response. Finally, some of the major challenges in this field and potential avenues for future improvements are also discussed. ",

keywords = "DNA repair, Monte Carlo, cell death, modelling, radiobiology",

author = "Gardner, \{Lydia L\} and Thompson, \{Shannon J\} and O'Connor, \{John D\} and McMahon, \{Stephen J\}",

year = "2024",

month = sep,

day = "21",

doi = "10.1088/1361-6560/ad70f0",

language = "English",

volume = "69",

journal = "Physics in Medicine \& Biology",

issn = "1361-6560",

publisher = "IOP Publishing Ltd",

number = "18",

}

TY - JOUR

T1 - Modelling radiobiology

AU - Gardner, Lydia L

AU - Thompson, Shannon J

AU - O'Connor, John D

AU - McMahon, Stephen J

PY - 2024/9/21

Y1 - 2024/9/21

N2 - Radiotherapy has played an essential role in cancer treatment for over a century, and remains one of the best-studied methods of cancer treatment. Because of its close links with the physical sciences, it has been the subject of extensive quantitative mathematical modelling, but a complete understanding of the mechanisms of radiotherapy has remained elusive. In part this is because of the complexity and range of scales involved in radiotherapy—from physical radiation interactions occurring over nanometres to evolution of patient responses over months and years. This review presents the current status and ongoing research in modelling radiotherapy responses across these scales, including basic physical mechanisms of DNA damage, the immediate biological responses this triggers, and genetic- and patient-level determinants of response. Finally, some of the major challenges in this field and potential avenues for future improvements are also discussed.

AB - Radiotherapy has played an essential role in cancer treatment for over a century, and remains one of the best-studied methods of cancer treatment. Because of its close links with the physical sciences, it has been the subject of extensive quantitative mathematical modelling, but a complete understanding of the mechanisms of radiotherapy has remained elusive. In part this is because of the complexity and range of scales involved in radiotherapy—from physical radiation interactions occurring over nanometres to evolution of patient responses over months and years. This review presents the current status and ongoing research in modelling radiotherapy responses across these scales, including basic physical mechanisms of DNA damage, the immediate biological responses this triggers, and genetic- and patient-level determinants of response. Finally, some of the major challenges in this field and potential avenues for future improvements are also discussed.

KW - DNA repair

KW - Monte Carlo

KW - cell death

KW - modelling

KW - radiobiology

U2 - 10.1088/1361-6560/ad70f0

DO - 10.1088/1361-6560/ad70f0

M3 - Review article

C2 - 39159658

SN - 1361-6560

VL - 69

JO - Physics in Medicine & Biology

JF - Physics in Medicine & Biology

IS - 18

M1 - 18TR01

ER -

Modelling radiobiology

Abstract

UN SDGs

Keywords

Access to Document

Fingerprint

Student theses

Quantifying the impact of DNA repair dysregulation on intrinsic radiation sensitivity

Cite this