Abstract
Oxygen distribution is a major determinant of treatment success in radiotherapy, with well-oxygenated tumour regions responding by up to a factor of three relative to anoxic volumes. Conversely, tumour hypoxia is associated with treatment resistance and negative prognosis. Tumour oxygenation is highly heterogeneous and difficult to measure directly. The recent advent of functional hypoxia imaging modalities such as fluorine-18 fluoromisonidazole positron emission tomography have shown promise in non-invasively determining regions of low oxygen tension. This raises the prospect of selectively increasing dose to hypoxic subvolumes, a concept known as dose painting. Yet while this is a promising approach, oxygen-mediated radioresistance is inherently a multiscale problem, and there are still a number of substantial challenges that must be overcome if hypoxia dose painting is to be successfully implemented. Current imaging modalities are limited by the physics of such systems to have resolutions in the millimetre regime, whereas oxygen distribution varies over a micron scale, and treatment delivery is typically modulated on a centimetre scale. In this review, we examine the mechanistic basis and implications of the radiobiological oxygen effect, the factors influencing microscopic heterogeneity in tumour oxygenation and the consequent challenges in the interpretation of clinical hypoxia imaging (in particular fluorine-18 fluoromisonidazole positron emission tomography). We also discuss dose-painting approaches and outline challenges that must be addressed to improve this treatment paradigm.
Highlights
In 1953, Gray et al[1] had observed that the concentration of oxygen in tissues markedly affects the response of animal tumours to radiotherapy
A low oxygen microenvironment is highly correlated with the development of metastatic phenotypes and poor prognosis
Functional imaging using hypoxia tracers such as FMISO positron emission tomography (PET) may be suitable for determining regions of Grimes et al substantial hypoxia
Summary
In 1953, Gray et al[1] had observed that the concentration of oxygen in tissues markedly affects the response of animal tumours to radiotherapy. One alluring experimental model for investigating the relationship between OCR and diffusion limited hypoxia is to instead use tumour spheroids Simulations have shown that the ratio of the “late” 18F-FMISO activity (mostly bound tracer, acquired 4 h post injection) to “early” activity (mostly perfusion, acquired during the first 15 min) result in a much better correlation between image signal and average tissue oxygenation.[64] It is possible to identify characteristic time activity curves for vasculature, hypoxia and necrosis,[70] but (as with a static analysis) all these features may be present in varying proportions within a voxel. The largest planning studies[76,96] (involving 21 and 20 patients, respectively) have used 18F-FDG as a tracer
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call