Patient positioning verification for proton therapy using proton radiography.

We present a proof of principle, experimental validation of the potential of proton 'Range Probes' (RP) for patient positioning verification in proton therapy. In this work, we have evaluated experimentally the accuracy of RP by using tissue-like samples and an in-house developed multilayer ionization chamber (MLIC). In addition we build on our previous, simulation based work to present first experimental measurements of RP through anthropomorphic phantoms to detect either rotational or translational positioning errors. For this, a technique has been proposed to characterize the residual integral depth dose curve (RIDDC) after range mixing. This parametrization has been used to evaluate the similarity between Monte Carlo calculated error scenarios of the database and the measured RIDDC, while considering the intrinsic uncertainties of both modalities in order to deduce the positioning error. Finally, the additional dose applied to the patient when using clinical RP with known fluence has been estimated by measuring the local dose of a single RP. In tissue phantoms, the prediction accuracy of the water equivalent path length was 0.70%, with the highest deviations being found in low density samples (up to 5.67%). In addition, the results of the patient positioning verification measurements demonstrated that using carefully selected RPs, 1D translational or rotational errors could be detected with an accuracy of 1 mm and 2°, respectively, and that these would be associated with a low additional dose burden to the patient. In summary, these promising results suggest that the RP method could be a simple, fast and low-dose tool for verifying patient set-up during proton therapy treatment.