Radiogenomics: the search for genetic predictors of radiotherapy response

Sarah L. Kerns; Catharine M. L. West; C. Nicolaj Andreassen; Gillian C. Barnett; Soren M. Bentzen; Neil G. Burnet; Andre Dekker; Dirk De Ruysscher; Alison Dunning; Matthew Parliament; Chris Talbot; Ana Vega; Barry S. Rosenstein

doi:10.2217/fon.14.173

Radiogenomics: the search for genetic predictors of radiotherapy response

Sarah L. Kerns, Catharine M. L. West, C. Nicolaj Andreassen, Gillian C. Barnett, Soren M. Bentzen, Neil G. Burnet, Andre Dekker, Dirk De Ruysscher, Alison Dunning, Matthew Parliament, Chris Talbot, Ana Vega, Barry S. Rosenstein^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Radiogenomics' is the study of genetic variation associated with response to radiotherapy. Radiogenomics aims to uncover the genes and biologic pathways responsible for radiotherapy toxicity that could be targeted with radioprotective agents and; identify genetic markers that can be used in risk prediction models in the clinic. The long-term goal of the field is to develop single nucleotide polymorphism-based risk models that can be used to stratify patients to more precisely tailored radiotherapy protocols. The field has evolved over the last two decades in parallel with advances in genomics, moving from narrowly focused candidate gene studies to large, collaborative genome-wide association studies. Several confirmed genetic variants have been identified and the field is making progress toward clinical translation.

Original language	English
Pages (from-to)	2391-2406
Journal	Future Oncology
Volume	10
Issue number	15
DOIs	https://doi.org/10.2217/fon.14.173
Publication status	Published - 2014

Keywords

genome-wide association study
normal tissue toxicity
radiogenomics
radiotherapy
single nucleotide polymorphisms

Access to Document

10.2217/fon.14.173

Cite this

@article{a57a865b21964554bb2653f8fdcba8e9,

title = "Radiogenomics: the search for genetic predictors of radiotherapy response",

abstract = "Radiogenomics' is the study of genetic variation associated with response to radiotherapy. Radiogenomics aims to uncover the genes and biologic pathways responsible for radiotherapy toxicity that could be targeted with radioprotective agents and; identify genetic markers that can be used in risk prediction models in the clinic. The long-term goal of the field is to develop single nucleotide polymorphism-based risk models that can be used to stratify patients to more precisely tailored radiotherapy protocols. The field has evolved over the last two decades in parallel with advances in genomics, moving from narrowly focused candidate gene studies to large, collaborative genome-wide association studies. Several confirmed genetic variants have been identified and the field is making progress toward clinical translation.",

keywords = "genome-wide association study, normal tissue toxicity, radiogenomics, radiotherapy, single nucleotide polymorphisms",

author = "Kerns, {Sarah L.} and West, {Catharine M. L.} and Andreassen, {C. Nicolaj} and Barnett, {Gillian C.} and Bentzen, {Soren M.} and Burnet, {Neil G.} and Andre Dekker and {De Ruysscher}, Dirk and Alison Dunning and Matthew Parliament and Chris Talbot and Ana Vega and Rosenstein, {Barry S.}",

year = "2014",

doi = "10.2217/fon.14.173",

language = "English",

volume = "10",

pages = "2391--2406",

journal = "Future Oncology",

issn = "1479-6694",

publisher = "Future Medicine Ltd.",

number = "15",

}

TY - JOUR

T1 - Radiogenomics: the search for genetic predictors of radiotherapy response

AU - Kerns, Sarah L.

AU - West, Catharine M. L.

AU - Andreassen, C. Nicolaj

AU - Barnett, Gillian C.

AU - Bentzen, Soren M.

AU - Burnet, Neil G.

AU - Dekker, Andre

AU - De Ruysscher, Dirk

AU - Dunning, Alison

AU - Parliament, Matthew

AU - Talbot, Chris

AU - Vega, Ana

AU - Rosenstein, Barry S.

PY - 2014

Y1 - 2014

N2 - Radiogenomics' is the study of genetic variation associated with response to radiotherapy. Radiogenomics aims to uncover the genes and biologic pathways responsible for radiotherapy toxicity that could be targeted with radioprotective agents and; identify genetic markers that can be used in risk prediction models in the clinic. The long-term goal of the field is to develop single nucleotide polymorphism-based risk models that can be used to stratify patients to more precisely tailored radiotherapy protocols. The field has evolved over the last two decades in parallel with advances in genomics, moving from narrowly focused candidate gene studies to large, collaborative genome-wide association studies. Several confirmed genetic variants have been identified and the field is making progress toward clinical translation.

AB - Radiogenomics' is the study of genetic variation associated with response to radiotherapy. Radiogenomics aims to uncover the genes and biologic pathways responsible for radiotherapy toxicity that could be targeted with radioprotective agents and; identify genetic markers that can be used in risk prediction models in the clinic. The long-term goal of the field is to develop single nucleotide polymorphism-based risk models that can be used to stratify patients to more precisely tailored radiotherapy protocols. The field has evolved over the last two decades in parallel with advances in genomics, moving from narrowly focused candidate gene studies to large, collaborative genome-wide association studies. Several confirmed genetic variants have been identified and the field is making progress toward clinical translation.

KW - genome-wide association study

KW - normal tissue toxicity

KW - radiogenomics

KW - radiotherapy

KW - single nucleotide polymorphisms

U2 - 10.2217/fon.14.173

DO - 10.2217/fon.14.173

M3 - Article

C2 - 25525847

SN - 1479-6694

VL - 10

SP - 2391

EP - 2406

JO - Future Oncology

JF - Future Oncology

IS - 15

ER -