Proton microbeam radiotherapy with scanned pencil-beams – Monte Carlo simulations

Abstract Irradiation, delivered by a synchrotron facility, using a set of highly collimated, narrow and parallel photon beams spaced by 1 mm or less, has been termed Microbeam Radiation Therapy (MRT). The tolerance of healthy tissue after MRT was found to be better than after standard broad X-ray be...

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Bibliographic Details
Published in:Physica medica 2015-09, Vol.31 (6), p.621-626
Main Authors: Kłodowska, M, Olko, P, Waligórski, M.P.R
Format: Article
Language:English
Subjects:
Absorption, Radiation
Animals
Brain Neoplasms - radiotherapy
Computer Simulation
Dose Fractionation
Equipment Design
Evidence-Based Medicine
Humans
Microbeam radiation therapy
Models, Biological
Models, Statistical
Monte Carlo Method
Monte Carlo simulations
Organ Sparing Treatments - methods
Proton radiotherapy
Proton Therapy - methods
Radiology
Radiotherapy, High-Energy - adverse effects
Radiotherapy, High-Energy - methods
Technology Assessment, Biomedical
Treatment Outcome
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Summary:Abstract Irradiation, delivered by a synchrotron facility, using a set of highly collimated, narrow and parallel photon beams spaced by 1 mm or less, has been termed Microbeam Radiation Therapy (MRT). The tolerance of healthy tissue after MRT was found to be better than after standard broad X-ray beams, together with a more pronounced response of malignant tissue. The microbeam spacing and transverse peak-to-valley dose ratio (PVDR) are considered to be relevant biological MRT parameters. We investigated the MRT concept for proton microbeams, where we expected different depth-dose profiles and PVDR dependences, resulting in skin sparing and homogeneous dose distributions at larger beam depths, due to differences between interactions of proton and photon beams in tissue. Using the FLUKA Monte Carlo code we simulated PVDR distributions for differently spaced 0.1 mm (sigma) pencil-beams of entrance energies 60, 80, 100 and 120 MeV irradiating a cylindrical water phantom with and without a bone layer, representing human head. We calculated PVDR distributions and evaluated uniformity of target irradiation at distal beam ranges of 60–120 MeV microbeams. We also calculated PVDR distributions for a 60 MeV spread-out Bragg peak microbeam configuration. Application of optimised proton MRT in terms of spot size, pencil-beam distribution, entrance beam energy, multiport irradiation, combined with relevant radiobiological investigations, could pave the way for hypofractionation scenarios where tissue sparing at the entrance, better malignant tissue response and better dose conformity of target volume irradiation could be achieved, compared with present proton beam radiotherapy configurations.
ISSN:1120-1797
1724-191X
DOI:10.1016/j.ejmp.2015.04.006