Could 18O-enriched water increase signal for PET proton range verification? A study using a chicken embryo model

TL;DR

This study explores using O-18-enriched water in a chicken embryo model to enhance PET signal for proton therapy range verification, showing promising retention of F-18 signals with minimal washout.

Contribution

It demonstrates that O-18-enriched water can be incorporated into live tissues to produce detectable F-18 signals post-irradiation, potentially improving PET-based proton range verification.

Findings

F-18 activity detected up to 9 hours post-irradiation

Minimal biological washout observed, with 68% retained activity at 8 hours

O-18-enriched water can be incorporated into tissues for PET signal enhancement

Abstract

Range verification of clinical protontherapy systems via positron-emission tomography (PET) still suffers from insufficient signal from low-energy protons around the Bragg peak and biological washout of PET emitters. Here we investigate the possibilities of O-18-enriched water (18-W), a potential contrast agent that could be incorporated in live tissues by replacing regular water, leading to the production of the F-18 PET emitters in the last millimeters of the proton path. We hypothesize that 18-W could also mitigate the problem of washout, as PET (F-18) isotopes created inside live cells would remain trapped in the form of fluoride anions. To test our hypothesis, we designed an experiment to prove that 18-W can incorporate enough O-18 into a living organism to produce a detectable signal from F-18 after proton irradiation, and to determine the amount of activity that remains trapped inside the cells. The experiment was performed on a chicken embryo chorioallantoic membrane tumor model of head and neck cancer. Seven eggs with visible tumors were infused with 18-W and irradiated with 8-MeV protons, equivalent to clinical protons at the end of particle range. The activity produced after irradiation was detected and quantified in a small-animal PET-CT scanner. The specific F-18 activity was detected in the tumor area of the alive chicken embryo up to 9 h after irradiation. Dynamic PET studies evidenced a minimal effect of biological washout, with 68% retained specific 18F activity at 8 hours after irradiation. Therefore, an infusion of 18-W can incorporate O-18 in animal tissues by replacing regular water inside cells, producing a PET signal when irradiated with low-energy protons that could be used for range verification in protontherapy. F-18 produced inside cells suffers from minimal biological washout, allowing for a sharper localization with longer PET acquisitions.