Mesure de la dose physique par lms radiochromiques et simulation Monte Carlo pour l'hadronthérapie / Dose measurement using radiochromic lms and Monte Carlo simulation for hadrontherapy

Zahra, Nabil

25 June 2010

En raison des forts gradients de dose générés par les interactions des particules avec la matière, les traitements par hadronthérapie nécessitent un contrôle très précis de la dose délivrée au patient. Les codes Monte Carlo représentent des outils indispensables dans la validation des systèmes de planification de traitement utilisé en clinique. Nous nous intéressons dans cette thèse au calcul de la dose physique à l'aide des simulations Monte Carlo Geant4/Gate. Nous étudions l'ajustement de plusieurs paramètres qui peuvent influencer la précision du calcul de dose requise en clinique (2%, 2mm) pour un faisceau d'ions carbone de 300 MeV/u dans l'eau. Ces paramètres sont : le seuil de production des particules secondaires et la taille maximale d'un segment de la trace de particule. Les critères de tolérance sur la valeur et la localisation de la dose sont fixés de manière à avoir le meilleur compromis en termes de distribution spatiale et de temps de calcul. Nous proposons ici des paramètres permettant d'atteindre ces critères de précision. Dans la deuxième partie du travail, nous étudions la réponse des films radiochromiques MDv2-55 pour le contrôle qualité des faisceaux d'ions carbone et protons. Nous avons en particulier observé et étudié l'effet de saturation de ces films dosimétriques pour les irradiations à TEL élevés (≥ 20 KeV/µm) dans des milieux homogènes et hétérogènes. Cet effet est dû à la forte densité d'ionisation autour de la trace de particule. Nous avons proposé et développé un modèle appelé « RADIS RAdiochromic films Dosimetry for Ions using Simulations » qui permet de prédire la réponse de ces films avec la prise en compte de cet effet de saturation. Ce modèle est basé sur la réponse des films en photons et la saturation des films à des dépôts d'énergies linéïques élevés calculée par Monte Carlo. Plusieurs types de faisceaux ont été étudiés : ions carbone, protons et photons à différentes énergies. Ces expérimentations ont été menées au Grand Accélérateur National d'Ions Lourds (GANIL), au Centre de protonthérapie d'Orsay (CPO), au Centre A. Lacassagne (CAL) et au Centre Léon Bérard (CLB). A l'aide du modèle, nous pouvons ainsi reproduire la densité optique des films le long du profil de Bragg pour tous les faisceaux avec une précision meilleure que 2%. / Because of the increase in dose at the end of the range of ions, dose delivery during patient treatment with hadrontherapy should be controlled with high precision. Monte Carlo codes are now considered mandatory for validation of clinical treatment planing and as a new tool for dosimetry of ion beams. In this work, we aimed to calculate the absorbed dose using Monte Carlo simulation Geant4/Gate. The ejffect on the dose calculation accuracy of dierent Geant4 parameters has been studied for mono-energetic carbon ion beams of 300 MeV/u in water. The parameters are : the production threshold of secandary particules and the maximum step limiter of the particle track. Tolerated criterion were choosen to meet the precision required in radiotherapy (2%, 2mm) and to obtain the best compromise on dose distribution and computational time.We propose here the values of parameters in order to satisfy the precision required. In the second part of this work, we will study the response of radiochromic lms MD-v2-55 for quality control in proton and carbon ion beams. We have particularly observed and studie the quenching effect of dosimetric lms for high LET (20 KeV/m) irradiations in homogeneous and heterogeneous medium. This eject is due to the high ionization density around the track of the particule. We have developped a method to predict the response of radiochromic lms taking into account the saturation effect. This model is called the RADIS model forRAdiochromic films. Dosimetry for Ions using Simulations". It is based on the response of lms under photon irradiations and the saturation of lms due to high linear energy deposit calculated by Monte Carlo. Four beams were used in this study and aimed to validate the model for hadrontherapy applications : carbon ions, protons and photons at different energies. Experiments were performed at Grand Accélérateur National d'Ions Lourds (GANIL), Proton therpay center of Orsay (CPO), A. Lacassagne proton center (CAL) and Leon Berard cancer center (CLB). The model showed very good agreement between the measured and calculated optical density with an error less than 2%.

Hadronthérapie

Simulations Monte Carlo

Gate/Geant4

Dosimétrie films radiochromiques

Dépôt d'énergie linéïque

Hadrontherapy

Monte Carlo Gate/Geant4 simulation

Dosimetry

Radiochromic films

Linear Energy Deposit

DEVELOPMENT OF A TRANSPARENT AND DEFORMABLE TWO DIMENSIONAL RADIOCHROMIC GEL DOSIMETER

Ataei, Pouria

04 1900

<p>Radiotherapy is used in many clinics to deliver a sufficient and uniform dose to the cancerous tumours while the dose to normal tissues is minimized. However, there is a possibility of missing the target volume due to patient set up/motion errors, or any fluctuation in treatment delivery. Therefore, accurate dose verification tools are essential to evaluate the delivered dose distribution of the designed treatment plan under realistic treatment conditions.</p> <p>Current research is focused on developing 3D dose verification tools to record the complex dose distributions for quality assurance purposes and the evaluation of new treatment techniques. New and novel materials and read-out techniques suitable for use in hospitals are desirable. The objective of this research is to fabricate a transparent radiochromic gel dosimeter that may be used as quality assurance tool. Also, the fabricated gel must be analyzed using a simple optical read-out technique.</p> <p>Gel dosimeters are gels that undergo some chemical changes upon irradiation as a function of absorbed dose. The absorbed dose may be recorded in three dimensions depending on the type of gel dosimeter. Radiochromic gels are dosimeters that change colour upon irradiation. A radiosensitive dye, leucomalachite green (LMG) is dissolved in a matrix material to record the dose distribution in 3D. LMG changes its colour upon irradiation, and has an absorbance band of 629nm.</p> <p>In this research two different matrix materials were investigated: poly (vinyl alcohol) and gelatin. PVA was studied as the primary agent due to its adjustable mechanical strength and high transparency. PVA has also been studied to have a low diffusion rate when it was used as the matrix material in Fricke gel dosimeters [41]. Even though PVA had all the desired characteristics, fabricating a PVA based radiochromic dosimeter was not successful. Consequently, gelatin was used as the matrix material to fabricate a gelatin-based radiochromic dosimeter.</p> <p>Using gelatin, highly transparent radiosensitive gels were successfully fabricated. The absorbencies of the irradiated gels were measured as a function of absorbed dose, using a 1D set up. After, the gels were formed into 5mm thick films and used as two-dimensional dose verification tools. The relationship between absorbance and absorbed dose for 1D measurement was obtained to be 0.00241± 0.00004 , and 0.0022 ± 0.00007 for 2D gels scaled to a thickness of 1 cm.</p> <p>In all of the experiments the absorbance-dose relationships were similar in slopes, but there was an offset between different batches. The offset was 20% between the different experiments. Moreover, there was less than 5% error associated with the physical set up; the major source of error was due to the production and handling of the mixture, possibly due to the effects of inconsistent heating and UV light exposure.</p> <p>The 2D gels were used to verify the dose distribution for the purpose of quality assurance. Six different complicated beams were delivered to the gels and their dose distributions were compared to their respective Pinnacle Calculated Planar (PCP) dose maps. The difference was found to be about 35% at worst; however, this error may be reduced by utilizing more sophisticated data processing methods. Nevertheless, the images were quite similar above 20Gy. Furthermore, the dose distributions recorded by the gels are qualitatively and quantitatively similar to the (PCP) dose map. Although the fabricated gel dosimeters show some promise as future tools for quality assurance purposes, they must go through many more stages of research to be used clinically.</p> / Master of Science (MSc)

Gel Dosimetry

Radiochromic Dosimeter

Radiotherapy

Poly(vinyl Alcohol) PVA

Gelatin

Micelle

Two dimensional

Medicine and Health Sciences

Physics

Medicine and Health Sciences