EPR imaging of magnetic field effects on radiation dose distributions around millimeter-size air cavities

• Published in: Physics in medicine & biology Vol. 64; no. 17; p. 175013
• Main Authors: Höfel, Sebastian, Fix, Michael K, Zwicker, Felix, Sterpin, Edmond, Drescher, Malte
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 04.09.2019
• Subjects: Air; dosimetry; EPR imaging; Feasibility Studies; Humans; irradiated quartz; Magnetic Fields; Magnetic Resonance Imaging - methods; Microscopy, Energy-Filtering Transmission Electron; Monte Carlo Method; MR-linac; MRgRT; Phantoms, Imaging; Radiation Dosage; Radiation Dosimeters; radiotherapy; Radiotherapy Planning, Computer-Assisted
• ISSN: 0031-9155; 1361-6560; 1361-6560
• DOI: 10.1088/1361-6560/ab325b

New hybrid radiotherapy treatment systems combining an MRI scanner with a source of ionizing radiation are being introduced in the clinic. The strong magnetic fields of MRI considerably affect radiation dose distributions, especially at tissue-air interfaces due to the electron return effect (ERE). Experimental investigation of the ERE within a sub-millimeter thick surface layer is still highly challenging. In the present work, we examine and quantify the magnetic field induced perturbations of dose distributions within a 0.5 mm layer surrounding millimeter-size air cavities by applying electron paramagnetic resonance imaging (EPRI). Air-filled fused quartz tubes (inner diameter 3 or 4 mm) mimic small air cavities and serve as model systems. The tubes were irradiated inside a PMMA phantom by a 6 MV photon beam. The irradiations were performed in the presence or absence of a transverse, magnetic field providing a magnetic field strength of 1.0 Tesla. The spatial distributions of radiation induced paramagnetic defects in the quartz tubes were subsequently determined by applying field-swept echo-detected EPRI and were then converted to relative dose distributions. The transverse magnetic field leads to considerable local dose enhancements and reductions (up to 35%) with respect to the mean dose within the quartz tubes. The experimentally determined dose distributions are in good quantitative agreement with Monte Carlo radiation transport simulations. The results of this work demonstrate the feasibility of field-swept echo-detected EPRI to measure magnetic field induced perturbations of dose distributions within a sub-millimeter thick surface layer at the dosimeter-air interface.