Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation

Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation

Introduction: Since the heart of the electronic brachytherapy system is a tube of a miniature x-ray and due to the increasing use of electronic brachytherapy, there is an urgent need for acquiring knowledge about the X-ray spectrum produced, and distribution of x-ray dose. This study aimed to asse...

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Main Authors: Barat Barati, Mansour Zabihzadeh, Mohammad Javad Tahmasebi Birgani, Nahid Chegini, Mojtaba Hoseini Ghahfarokhi, Jafar Fatahiasl
Format: Article
Language:English
Published: Electronic Physician 2017-02-01
Series:Electronic Physician
Subjects:
Mont Carlo simulation
Electronic Branchy therapy
Energy Spectrum
Dose calculation
Online Access:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5410916/
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spelling doaj-edfd6a3ceaf74ace81bbd945a1b2d5cd2020-11-24T22:06:43ZengElectronic PhysicianElectronic Physician2008-58422008-58422017-02-01923845385610.19082/3845Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo SimulationBarat BaratiMansour ZabihzadehMohammad Javad Tahmasebi BirganiNahid CheginiMojtaba Hoseini GhahfarokhiJafar FatahiaslIntroduction: Since the heart of the electronic brachytherapy system is a tube of a miniature x-ray and due to the increasing use of electronic brachytherapy, there is an urgent need for acquiring knowledge about the X-ray spectrum produced, and distribution of x-ray dose. This study aimed to assess the optimal target thickness (TT), the X-ray source spectrum, and the absorbed dose of two miniature sources of hemispherical and hemispherical- conical used in electronic brachytherapy systems, through a Monte Carlo simulation. Methods: Considering the advantages of MCNPX Code (2.6.0), two input files corresponding to the characteristics of the investigated miniature sources were prepared for this code and then were used for simulation. The optimal thickness (OT) of gold and tungsten targets was determined for the energy levels of 40, 45, and 50 kilo-electron-volts. Results: In this study, the values of the size of the optimal thickness of 0.92, 1.01 and 1.06 μ for gold target and values of 0.99, 1.08 and 1.34 μ for tungsten target were obtained for energies 40, 45 and 50 keV that using these values, the optimum thickness of 0.92, X-ray spectrum within and outside targets, axial and radial doses for the used energy were calculated for two miniature sources. Conclusion: It was found that the energy of incident electron, target shape, cross-sectional area of the produced bremsstrahlung, atomic number of materials constituting of the target and output window are the factors with the greatest impacts on the produced X-ray spectrum and the absorbed dosehttps://www.ncbi.nlm.nih.gov/pmc/articles/PMC5410916/Mont Carlo simulationElectronic Branchy therapyEnergy SpectrumDose calculation
collection DOAJ
language English
format Article
sources DOAJ
author Barat Barati
Mansour Zabihzadeh
Mohammad Javad Tahmasebi Birgani
Nahid Chegini
Mojtaba Hoseini Ghahfarokhi
Jafar Fatahiasl
spellingShingle Barat Barati
Mansour Zabihzadeh
Mohammad Javad Tahmasebi Birgani
Nahid Chegini
Mojtaba Hoseini Ghahfarokhi
Jafar Fatahiasl
Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation
Electronic Physician
Mont Carlo simulation
Electronic Branchy therapy
Energy Spectrum
Dose calculation
author_facet Barat Barati
Mansour Zabihzadeh
Mohammad Javad Tahmasebi Birgani
Nahid Chegini
Mojtaba Hoseini Ghahfarokhi
Jafar Fatahiasl
author_sort Barat Barati
title Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation
title_short Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation
title_full Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation
title_fullStr Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation
title_full_unstemmed Assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using Monte Carlo Simulation
title_sort assessment of two hemispherical and hemispherical-conical miniature sources used in electronic brachytherapy using monte carlo simulation
publisher Electronic Physician
series Electronic Physician
issn 2008-5842
2008-5842
publishDate 2017-02-01
description Introduction: Since the heart of the electronic brachytherapy system is a tube of a miniature x-ray and due to the increasing use of electronic brachytherapy, there is an urgent need for acquiring knowledge about the X-ray spectrum produced, and distribution of x-ray dose. This study aimed to assess the optimal target thickness (TT), the X-ray source spectrum, and the absorbed dose of two miniature sources of hemispherical and hemispherical- conical used in electronic brachytherapy systems, through a Monte Carlo simulation. Methods: Considering the advantages of MCNPX Code (2.6.0), two input files corresponding to the characteristics of the investigated miniature sources were prepared for this code and then were used for simulation. The optimal thickness (OT) of gold and tungsten targets was determined for the energy levels of 40, 45, and 50 kilo-electron-volts. Results: In this study, the values of the size of the optimal thickness of 0.92, 1.01 and 1.06 μ for gold target and values of 0.99, 1.08 and 1.34 μ for tungsten target were obtained for energies 40, 45 and 50 keV that using these values, the optimum thickness of 0.92, X-ray spectrum within and outside targets, axial and radial doses for the used energy were calculated for two miniature sources. Conclusion: It was found that the energy of incident electron, target shape, cross-sectional area of the produced bremsstrahlung, atomic number of materials constituting of the target and output window are the factors with the greatest impacts on the produced X-ray spectrum and the absorbed dose
topic Mont Carlo simulation
Electronic Branchy therapy
Energy Spectrum
Dose calculation
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5410916/
work_keys_str_mv AT baratbarati assessmentoftwohemisphericalandhemisphericalconicalminiaturesourcesusedinelectronicbrachytherapyusingmontecarlosimulation
AT mansourzabihzadeh assessmentoftwohemisphericalandhemisphericalconicalminiaturesourcesusedinelectronicbrachytherapyusingmontecarlosimulation
AT mohammadjavadtahmasebibirgani assessmentoftwohemisphericalandhemisphericalconicalminiaturesourcesusedinelectronicbrachytherapyusingmontecarlosimulation
AT nahidchegini assessmentoftwohemisphericalandhemisphericalconicalminiaturesourcesusedinelectronicbrachytherapyusingmontecarlosimulation
AT mojtabahoseinighahfarokhi assessmentoftwohemisphericalandhemisphericalconicalminiaturesourcesusedinelectronicbrachytherapyusingmontecarlosimulation
AT jafarfatahiasl assessmentoftwohemisphericalandhemisphericalconicalminiaturesourcesusedinelectronicbrachytherapyusingmontecarlosimulation
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