Y. Karakaya scite author profile

Ion beam therapy enables a highly accurate dose conformation delivery to the tumor due to the finite range of charged ions in matter (i.e. Bragg peak (BP)). Consequently, the dose profile is very sensitive to patients anatomical changes as well as minor mispositioning, and so it requires improved dose control techniques. Proton interaction vertex imaging (IVI) could offer an online range control in carbon ion therapy. In this paper, a statistical method was used to study the sensitivity of the IVI technique on experimental data obtained from the Heidelberg Ion-Beam Therapy Center. The vertices of secondary protons were reconstructed with pixelized silicon detectors. The statistical study used the [Formula: see text] test of the reconstructed vertex distributions for a given displacement of the BP position as a function of the impinging carbon ions. Different phantom configurations were used with or without bone equivalent tissue and air inserts. The inflection points in the fall-off region of the longitudinal vertex distribution were computed using different methods, while the relation with the BP position was established. In the present setup, the resolution of the BP position was about 4-5 mm in the homogeneous phantom under clinical conditions (10 incident carbon ions). Our results show that the IVI method could therefore monitor the BP position with a promising resolution in clinical conditions.

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Analytical dose modeling for preclinical proton irradiation of millimetric targets

Vanstalle

Constanzo

Karakaya

et al. 2017

Medical Physics

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Purpose: Due to the considerable development of proton radiotherapy, several proton platforms have emerged to irradiate small animals in order to study the biological effectiveness of proton radiation. A dedicated analytical treatment planning tool was developed in this study to accurately calculate the delivered dose given the specific constraints imposed by the small dimensions of the irradiated areas. Methods: The treatment planning system (TPS) developed in this study is based on an analytical formulation of the Bragg peak and uses experimental range values of protons. The method was validated after comparison with experimental data from the literature and then compared to Monte Carlo simulations conducted using GEANT4. Three examples of treatment planning, performed with phantoms made of water targets and bone-slab insert, were generated with the analytical formulation and GEANT4. Each treatment planning was evaluated using dose-volume histograms and gamma index maps. Results: We demonstrate the value of the analytical function for mouse irradiation, which requires a targeting accuracy of 0.1 mm. Using the appropriate database, the analytical modeling limits the errors caused by misestimating the stopping power. For example, 99% of a 1-mm tumor irradiated with a 24-MeV beam receives the prescribed dose. The analytical dose deviations from the prescribed dose remain within the dose tolerances stated by report 62 of the International Commission on Radiation Units and Measurements for all tested configurations. In addition, the gamma index maps show that the highly constrained targeting accuracy of 0.1 mm for mouse irradiation leads to a significant disagreement between GEANT4 and the reference. This simulated treatment planning is nevertheless compatible with a targeting accuracy exceeding 0.2 mm, corresponding to rat and rabbit irradiations. Conclusion: Good dose accuracy for millimetric tumors is achieved with the analytical calculation used in this work. These volume sizes are typical in mouse models for radiation studies. Our results demonstrate that the choice of analytical rather than simulated treatment planning depends on the animal model under consideration.

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Differential cross section measurements for hadron therapy: 50 MeV/nucleon C12 reactions on H, C, O, Al, and Tinat targets

et al. 2017

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et al.. Differential cross section measurements for hadron therapy: 50 MeV/nucleon 12 C reactions on H, C, O, Al, and nat Ti targets. Phys.Rev.C, 2017, 95 (4), pp.During a carbon therapy treatment, the beam undergoes inelastic nuclear reactions leading to the production of secondary fragments. These nuclear interactions tend to delocate a part of the dose into healthy tissues and create a mixed radiation field. In order to accurately estimate the dose deposited into the tissues, the production rate of these fragments all along the beam path have to be taken into account. But the double differential carbon fragmentation cross sections are not well known in the energy range needed for a treatment (up to 400 MeV/nucleon). Therefore, a series of experiments aiming to measure the double differential fragmentation cross sections of carbon on thin targets of medical interest has been started by our collaboration. In March 2015 we performed an experiment to study the fragmentation of a 50 MeV/nucleon 12 C beam on thin targets at GANIL. During this experiment, energy and angular cross-section distributions on H, C, O, Al, and nat Ti have been measured. The experimental set-up will be detailed as well as the systematic error study and all the experimental results will be presented.

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Differential cross-sections measurements for hadrontherapy: 50 MeV/A¹²C reactions on H, C, O, Al and^natTi targets

et al. 2017

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Abstract. In order to keep the benefits of a carbon treatment, the dose and biological effects induced by secondary fragments must be taken into account when simulating the treatment plan. These Monte-Carlo simulations codes are done using nuclear models that are constrained by experimental data. It is hence necessary to have precise measurements of the production rates of these fragments all along the beam path and for its whole energy range. In this context, a series of experiments aiming to measure the double differential fragmentation cross-sections of carbon on thin targets of medical interest has been started by our collaboration. In March 2015, an experiment was performed with a 50 MeV/nucleon 12 C beam at GANIL. During this experiment, energy and angular differential cross-section distributions on H, C, O, Al and nat Ti have been measured. In the following, the experimental set-up and analysis process are briefly described and some experimental results are presented. Comparisons between several exit channel models from PHITS and GEANT4 show great discrepancies with the experimental data. Finally, the homemade SLIIPIE model is briefly presented and preliminary results are compared to the data with a promising outcome.

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Differential cross sections measurements for hadrontherapy: 50 MeV/n 12C reactions on H, C, Al, O and natTi targets.

Divay¹,

Cussol²,

Labalme³

et al. 2016

Radiotherapy and Oncology

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Y. Karakaya

Study for online range monitoring with the interaction vertex imaging method

Analytical dose modeling for preclinical proton irradiation of millimetric targets

Differential cross section measurements for hadron therapy: 50 MeV/nucleon C12 reactions on H, C, O, Al, and Tinat targets

Differential cross-sections measurements for hadrontherapy: 50 MeV/A¹²C reactions on H, C, O, Al and^natTi targets

Differential cross sections measurements for hadrontherapy: 50 MeV/n 12C reactions on H, C, Al, O and natTi targets.

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Y. Karakaya

Study for online range monitoring with the interaction vertex imaging method

Analytical dose modeling for preclinical proton irradiation of millimetric targets

Differential cross section measurements for hadron therapy: 50 MeV/nucleon C12 reactions on H, C, O, Al, and Tinat targets

Differential cross-sections measurements for hadrontherapy: 50 MeV/A12C reactions on H, C, O, Al andnatTi targets

Differential cross sections measurements for hadrontherapy: 50 MeV/n 12C reactions on H, C, Al, O and natTi targets.

Contact Info

Product

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Differential cross-sections measurements for hadrontherapy: 50 MeV/A¹²C reactions on H, C, O, Al and^natTi targets