Eva Kasanda scite author profile

In this work, we propose a novel technique for in-vivo proton therapy range verification. This technique makes use of a molybdenum hadron tumour marker, implanted at a short distance from the clinical treatment volume. Signals emitted from the marker during treatment can provide a direct measurement of the proton beam energy at the marker’s position. Fusion-evaporation reactions between the proton beam and marker nucleus result in the emission of delayed characteristic γ rays, which are detected off-beam for an improved signal-to-noise ratio. In order to determine the viability of this technique and to establish an experimental setup for future work, the Monte Carlo package GEANT4 was used in combination with ROOT to simulate a treatment scenario with the new method outlined in this work. These simulations show that the intensity of delayed γ rays produced from competing reactions yields a precise measurement of the range of the proton beam relative to the marker, with sub-millimetre uncertainty.

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Proton therapy range verification method via delayed γ-ray spectroscopy of a molybdenum tumour marker

Burbadge

Kasanda²,

Bildstein³

et al. 2021

Phys. Med. Biol.

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In this work, a new method of range verification for proton therapy (PT) is experimentally demonstrated for the first time. If a metal marker is implanted near the tumour site, its response to proton activation will result in the emission of characteristic γ rays. The relative intensity of γ rays originating from competing fusion-evaporation reaction channels provides a unique signature of the average proton energy at the marker, and by extension the beam’s range, in vivo and in real time. The clinical feasibility of this method was investigated at the PT facility at TRIUMF with a proof-of-principle experiment which irradiated a naturally-abundant molybdenum foil at various proton beam energies. Delayed characteristic γ rays were measured with two Compton-shielded LaBr3 scintillators. The technique was successfully demonstrated by relating the relative intensity of two γ-ray peaks to the energy of the beam at the Mo target, opening the door to future clinical applications where the range of the beam can be verified in real time.

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First Direct Measurement of an Astrophysical p -Process Reaction Cross Section Using a Radioactive Ion Beam

Lotay¹,

Gillespie²,

Williams³

et al. 2021

Phys. Rev. Lett.

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We have performed the first direct measurement of the 83 Rbðp; γÞ radiative capture reaction cross section in inverse kinematics using a radioactive beam of 83 Rb at incident energies of 2.4 and 2.7A MeV. The measured cross section at an effective relative kinetic energy of E cm ¼ 2.393 MeV, which lies within the relevant energy window for core collapse supernovae, is smaller than the prediction of statistical model calculations. This leads to the abundance of 84 Sr produced in the astrophysical p process being higher than previously calculated. Moreover, the discrepancy of the present data with theoretical predictions indicates that further experimental investigation of p-process reactions involving unstable projectiles is clearly warranted.

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Intra- and inter-fraction relative range verification in heavy-ion therapy using filtered interaction vertex imaging

Hymers¹,

Kasanda²,

Bildstein³

et al. 2021

Phys. Med. Biol.

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Heavy-ion therapy, particularly using scanned (active) beam delivery, provides a precise and highly conformal dose distribution, with maximum dose deposition for each pencil beam at its endpoint (Bragg peak), and low entrance and exit dose. To take full advantage of this precision, robust range verification methods are required; these methods ensure that the Bragg peak is positioned correctly in the patient and the dose is delivered as prescribed. Relative range verification allows intra-fraction monitoring of Bragg peak spacing to ensure full coverage with each fraction, as well as inter-fraction monitoring to ensure all fractions are delivered consistently. To validate the proposed filtered Interaction Vertex Imaging method for relative range verification, a 16O beam was used to deliver 12 Bragg peak positions in a 40 mm poly-(methyl methacrylate) phantom. Secondary particles produced in the phantom were monitored using position-sensitive silicon detectors. Events recorded on these detectors, along with a measurement of the treatment beam axis, were used to reconstruct the sites of origin of these secondary particles in the phantom. The distal edge of the depth distribution of these reconstructed points was determined with logistic fits, and the translation in depth required to minimize the χ2 statistic between these fits was used to compute the range shift between any two Bragg peak positions. In all cases, the range shift was determined with sub-millimeter precision, to a standard deviation of the mean of 220(10) μm. This result validates filtered Interaction Vertex Imaging as a reliable relative range verification method, which should be capable of monitoring each energy step in each fraction of a scanned heavy-ion treatment plan.

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Single neutron transfer on 23Ne and its relevance for the pathway of nucleosynthesis in astrophysical X-ray bursts

et al. 2022

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Eva Kasanda

GEANT4 simulation of a range verification method using delayed γ spectroscopy of a ⁹²Mo marker

Proton therapy range verification method via delayed γ-ray spectroscopy of a molybdenum tumour marker

First Direct Measurement of an Astrophysical p -Process Reaction Cross Section Using a Radioactive Ion Beam

Intra- and inter-fraction relative range verification in heavy-ion therapy using filtered interaction vertex imaging

Single neutron transfer on 23Ne and its relevance for the pathway of nucleosynthesis in astrophysical X-ray bursts

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Eva Kasanda

GEANT4 simulation of a range verification method using delayed γ spectroscopy of a 92Mo marker

Proton therapy range verification method via delayed γ-ray spectroscopy of a molybdenum tumour marker

First Direct Measurement of an Astrophysical p -Process Reaction Cross Section Using a Radioactive Ion Beam

Intra- and inter-fraction relative range verification in heavy-ion therapy using filtered interaction vertex imaging

Single neutron transfer on 23Ne and its relevance for the pathway of nucleosynthesis in astrophysical X-ray bursts

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Product

Resources

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GEANT4 simulation of a range verification method using delayed γ spectroscopy of a ⁹²Mo marker