Functional Imaging for Dose Painting in Radiotherapy

TL;DR

This paper reviews how functional imaging techniques like PET-CT and MRI enable personalized dose painting in radiotherapy, aiming to escalate doses in resistant tumor regions while sparing healthy tissue.

Contribution

It provides a comprehensive overview of quantitative functional imaging methods and compares dose painting techniques, highlighting challenges and future research directions.

Findings

Functional imaging enables biological dose escalation in resistant tumor areas.

Comparison of dose painting by contours and dose painting by numbers methods.

Discussion of clinical outcomes and future challenges in dose painting.

Abstract

Dose painting has been developed to modulate the required dose in the target area without increasing the toxicity in healthy areas. Apart from determining the accurate location and size of tumors, quantitative functional imaging can be used to implement the dose painting. Functional imaging, such as multi-parameter MRI and PET CT, allows us to achieve biological dose escalation by increasing the dose in certain areas or voxels that are therapy-resistant in the gross tumor volume while reducing the dose in the less aggressive area or voxels. Functional imaging can serve as an indicator of therapeutic intervention in radiotherapy due to microscopic tissue properties. With such biological indicators, the personalized radiation dose can be tailored to a specific contour or a voxel using dose painting. In this review, we firstly discuss several quantitative functional imaging techniques including PET-CT and multi-parameter MRI. Furthermore, theoretical and experimental comparisons for dose painting by contours (DPBC) and dose painting by numbers (DPBN), along with outcome analysis after dose painting are provided. Finally, we conclude major challenges and future directions in this field through which we hope to inspire exciting developments and fruitful research avenues.