Moving the Needle Forward in Genomically-Guided Precision Radiation Treatment

Overview

Journal Cancers (Basel)

Publisher MDPI

Specialty Oncology

Date 2023 Nov 25

PMID 38001574

Authors

Andrew Tam

Benjamin D Mercier

Reeny M Thomas

Eemon Tizpa

Irene G Wong

Juncong Shi

Rishabh Garg

Heather Hampel

Stacy W Gray

Terence Williams

Jose G Bazan

Yun R Li

Affiliations

Soon will be listed here.

Abstract

Radiation treatment (RT) is a mainstay treatment for many types of cancer. Recommendations for RT and the radiation plan are individualized to each patient, taking into consideration the patient's tumor pathology, staging, anatomy, and other clinical characteristics. Information on germline mutations and somatic tumor mutations is at present rarely used to guide specific clinical decisions in RT. Many genes, such as and /, have been identified in the laboratory to confer radiation sensitivity. However, our understanding of the clinical significance of mutations in these genes remains limited and, as individual mutations in such genes can be rare, their impact on tumor response and toxicity remains unclear. Current guidelines, including those from the National Comprehensive Cancer Network (NCCN), provide limited guidance on how genetic results should be integrated into RT recommendations. With an increasing understanding of the molecular underpinning of radiation response, genomically-guided RT can inform decisions surrounding RT dose, volume, concurrent therapies, and even omission to further improve oncologic outcomes and reduce risks of toxicities. Here, we review existing evidence from laboratory, pre-clinical, and clinical studies with regard to how genetic alterations may affect radiosensitivity. We also summarize recent data from clinical trials and explore potential future directions to utilize genetic data to support clinical decision-making in developing a pathway toward personalized RT.

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