Search results for "Radiotherapy Planning"

showing 10 items of 47 documents

Response charactterization of ammonium tartrate solid state pellets for ESR dosimetry with radiotherapeutic photon and electron beams.

2001

Solid state pellets (1 mm thick) for electron spin resonance (ESR) dosimetry were made using ammonium tartrate as the radiation-sensitive substance. Their behaviour was experimentally investigated as a function of dose with 60Co gamma rays. The calibration function obtained permits measurements of absorbed dose in the 2-50 Gy range, with a combined uncertainty of +/-4%. The lowest detectable dose was about 0.5 Gy. These properties are comparable with or even better than those of ESR dosimeters made from other materials. The time stability of the ESR signal of ammonium tartrate dosimeters at different storage conditions after irradiation was studied. A rather complex behaviour was observed, …

Materials scienceFree RadicalsBiophysicsElectronsRadiationTartrateBiophysical Phenomenalaw.inventionchemistry.chemical_compoundlawDosimetryHumansRadiology Nuclear Medicine and imagingIrradiationParticle SizeElectron paramagnetic resonanceRadiometryTartratesPhotonsDosimeterRadiological and Ultrasound Technologybusiness.industryRadiotherapy Planning Computer-AssistedRadiochemistryGamma rayElectron Spin Resonance SpectroscopyMicrosphereschemistryAbsorbed doseNuclear medicinebusinessPhysics in medicine and biology
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A Monte Carlo study of intersource effects in dome-type applicators loaded with LDR Cs-137 sources

2005

In this study, the dose rate distributions produced by low dose rate Cs-137 sources loaded in afterloadable dome applicators are studied using the Monte Carlo method. Dose differences between Monte Carlo results and calculations done using the superposition principle are within 1-3% in front of the applicator and between 3 and 10% near and along the longitudinal source axis. Consequently, the real doses to lateral vaginal wall, rectum and bladder are very close to the doses estimated applying the superposition principle, while the dose to the vaginal cuff has been overestimated by up to 10%.

Materials scienceMaximum Tolerated DoseBrachytherapyMonte Carlo methodRadiationSensitivity and SpecificityVaginal wallDome (geology)Superposition principleOpticsHumansDosimetryRadiology Nuclear Medicine and imagingLow dose rateEquipment Safetybusiness.industryRadiotherapy Planning Computer-AssistedDose-Response Relationship RadiationRadiotherapy DosageEquipment DesignHematologyOncologyDose rateNuclear medicinebusinessMonte Carlo MethodRadiotherapy and Oncology
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A monte carlo study of dose rate distribution around the specially asymmetric CSM3-a 137Cs source.

2001

The CSM3 137Cs type stainless-steel encapsulated source is widely used in manually afterloaded low dose rate brachytherapy. A specially asymmetric source, CSM3-a, has been designed by CIS Bio International (France) substituting the eyelet side seed with an inactive material in the CSM3 source. This modification has been done in order to allow a uniform dose level over the upper vaginal surface when this `linear' source is inserted at the top of the dome vaginal applicators. In this study the Monte Carlo GEANT3 simulation code, incorporating the source geometry in detail, was used to investigate the dosimetric characteristics of this special CSM3-a 137Cs brachytherapy source. The absolute do…

Materials scienceRadiological and Ultrasound Technologybusiness.industryRadioactive sourceRadiotherapy Planning Computer-AssistedMonte Carlo methodBrachytherapyDose levelSievert integralLow-Dose Rate BrachytherapyComputational physicsDistribution (mathematics)Cesium RadioisotopesNeoplasmsVaginaDosimetryHumansRadiology Nuclear Medicine and imagingFemaleDose rateNuclear medicinebusinessRadiometryMonte Carlo MethodAlgorithmsPhysics in medicine and biology
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Investigation of correction factors for non-reference conditions in ion chamber photon dosimetry with Monte-Carlo simulations.

2009

Current dosimetry protocols require geometrical reference conditions for the determination of absorbed dose in external radiotherapy. Whenever these geometrical conditions cannot be maintained the application of additional corrections becomes necessary, in principle. The current DIN6800-2 protocol includes a corresponding factor k(NR), but numerical values are lacking and no definite information about the magnitude of this correction is available yet. This study presents Monte-Carlo based calculations within the 6 MV-X photon field of a linear accelerator for a common used ion chamber (PTW31010) employing the EGSnrc code system. The linear accelerator model was matched to measurements, show…

PhotonMonte Carlo methodBiophysicsRadiation DosageLinear particle acceleratorlaw.inventionIonlawDosimetryHumansScattering RadiationRadiology Nuclear Medicine and imagingPhysicsIonsPhotonsRadiological and Ultrasound TechnologyPhantoms ImagingRadiotherapy Planning Computer-AssistedReproducibility of ResultsWaterParticle acceleratorCharged particleIonization chamberRadiotherapy Intensity-ModulatedAtomic physicsParticle AcceleratorsMonte Carlo MethodAlgorithmsZeitschrift fur medizinische Physik
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The FiR 1 photon beam model adjustment according to in-air spectrum measurements with the Mg(Ar) ionization chamber.

2014

Abstract The mixed neutron–photon beam of FiR 1 reactor is used for boron–neutron capture therapy (BNCT) in Finland. A beam model has been defined for patient treatment planning and dosimetric calculations. The neutron beam model has been validated with an activation foil measurements. The photon beam model has not been thoroughly validated against measurements, due to the fact that the beam photon dose rate is low, at most only 2% of the total weighted patient dose at FiR 1. However, improvement of the photon dose detection accuracy is worthwhile, since the beam photon dose is of concern in the beam dosimetry. In this study, we have performed ionization chamber measurements with multiple b…

PhotonQuantitative Biology::Tissues and OrgansPhysics::Medical PhysicsMonte Carlo methodAnalytical chemistryBoron Neutron Capture TherapySensitivity and SpecificityOpticsNuclear ReactorsDosimetryPenelopeIonization ChamberDosimetryComputer SimulationPhoton beamRadiometryMonte CarloPhysicsPhotonsRadiationModels Statisticalbusiness.industryAirRadiotherapy Planning Computer-AssistedReproducibility of ResultsEquipment DesignNeutron radiationEquipment Failure AnalysisIonization chamberBNCTPhysics::Accelerator PhysicsComputer-Aided DesignDose ratebusinessMCNP5Beam (structure)Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine
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Phantom size in brachytherapy source dosimetric studies

2004

An important point to consider in a brachytherapy dosimetry study is the phantom size involved in calculations or experimental measurements. As pointed out by Williamson [Med. Phys. 18, 776-786 (1991)] this topic has a relevant influence on final dosimetric results. Presently, one-dimensional (1-D) algorithms and newly-developed 3-D correction algorithms are based on physics data that are obtained under full scatter conditions, i.e., assumed infinite phantom size. One can then assume that reference dose distributions in source dosimetry for photon brachytherapy should use an unbounded phantom size rather than phantom-like dimensions. Our aim in this paper is to study the effect of phantom s…

Photonmedicine.medical_treatmentBrachytherapyMonte Carlo methodBrachytherapyModels BiologicalSensitivity and SpecificityImaging phantomRelative biological effectivenessmedicineHumansScattering RadiationDosimetryComputer SimulationPoint (geometry)RadiometryRadioisotopesPhysicsPhantoms Imagingbusiness.industryRadiotherapy Planning Computer-AssistedReproducibility of ResultsRadiotherapy DosageGeneral MedicineRadiusComputational physicsOrgan SpecificityBody BurdenRadiopharmaceuticalsNuclear medicinebusinessMonte Carlo MethodAlgorithmsRelative Biological EffectivenessMedical Physics
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Monte Carlo calculation of dose rate distributions around 192Ir wires.

1997

Monte Carlo calculations of absolute dose rate in liquid water are presented in the form of away-along tables for 1 and 5 cm 192 Ir wires of 0.3 mm diameter. Simulated absolute dose rate values can be used as benchmark data to verify the calculation results of treatment planning systems or directly as input data for treatment planning. Best fit value of attenuation coefficient suitable for use in Sievert-integrals-type calculations has been derived based on Monte Carlo calculation results. For the treatment planning systems that are based on TG43 formalism we have also calculated the required dosimetry parameters.

PhysicsLiquid waterRadiotherapy Planning Computer-AssistedMonte Carlo methodBrachytherapyBiophysicsRadiotherapy DosageGeneral MedicineReference StandardsIridium RadioisotopesBiophysical PhenomenaComputational physicsEvaluation Studies as TopicAttenuation coefficientNeoplasmsDynamic Monte Carlo methodDosimetryHumansComputer SimulationStatistical physicsBenchmark dataDose rateMonte Carlo MethodMedical physics
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Irradiation facility at the TRIGA Mainz for treatment of liver metastases

2009

Abstract The TRIGA Mark II reactor at the University of Mainz provides ideal conditions for duplicating BNCT treatment as performed in Pavia, Italy, in 2001 and 2003 [Pinelli, T., Zonta, A., Altieri, S., Barni, S., Braghieri, A., Pedroni, P., Bruschi, P., Chiari, P., Ferrari, C., Fossati, F., Nano, R., Ngnitejeu Tata, S., Prati, U., Ricevuti, G., Roveda, L., Zonta, C., 2002. TAOrMINA: from the first idea to the application to the human liver. In: Sauerwein et al. (Eds.), Research and Development in Neutron Capture Therapy. Proceedings of the 10th International Congress on Neutron Capture Therapy, Monduzzi editore, Bologna, pp. 1065–1072]. In order to determine the optimal parameters for the…

PhysicsModels StatisticalRadiationHuman liverbusiness.industryRadiotherapy Planning Computer-AssistedLiver NeoplasmsBoron Neutron Capture TherapyIn Vitro TechniquesTRIGAFast NeutronsNuclear ReactorsGermanyInternational congressHumansNuclear medicinebusinessMonte Carlo MethodApplied Radiation and Isotopes
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Brachytherapy structural shielding calculations using Monte Carlo generated, monoenergetic data

2014

Purpose: To provide a method for calculating the transmission of any broad photon beam with a known energy spectrum in the range of 20–1090 keV, through concrete and lead, based on the superposition of corresponding monoenergetic data obtained from Monte Carlo simulation. Methods: MCNP5 was used to calculate broad photon beam transmission data through varying thickness of lead and concrete, for monoenergetic point sources of energy in the range pertinent to brachytherapy (20–1090 keV, in 10 keV intervals). The three parameter empirical model introduced byArcher et al. [“Diagnostic x-ray shielding design based on an empirical model of photon attenuation,” Health Phys. 44, 507–517 (1983)] was…

PhysicsPhotonsPhotonbusiness.industryRadiotherapy Planning Computer-AssistedBrachytherapyMonte Carlo methodMonte Carlo method for photon transportGeneral MedicineSuperposition principleRadiation ProtectionOpticsTransmission curveElectromagnetic shieldingEmission spectrumbusinessMonte Carlo MethodBeam (structure)Medical Physics
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Monte Carlo calculation of dose rate distributions around the Walstam CDC.K-type137Cs sources

2001

Basic dosimetric data for the Walstam CDC.K-type low dose rate 137Cs sources in water have been calculated using Monte Carlo techniques. These sources, CDC.K1 -K3 and CDC.K4, are widely used in a range of applicators and moulds for the treatment of intracavitary and superficial cancers. Our purpose is to improve existing data about these sources using the Monte Carlo simulation code GEANT3. Absolute dose rate distributions in water have been calculated around these sources and are presented as conventional 2D Cartesian look-up tables. Also the AAPM Task Group 43 formalism for dose calculation has been applied. The calculated dose rate constant for the CDC.K1-K3 source is A = 1.106 +/- 0.001…

PhysicsPolynomial regressionModels StatisticalRadiological and Ultrasound TechnologyRadiotherapy Planning Computer-AssistedMonte Carlo methodSievert integrallaw.inventionComputational physicsCesium RadioisotopeslawAnisotropyHumansDosimetryRadiology Nuclear Medicine and imagingCartesian coordinate systemStatistical physicsLow dose rateRadiometryDose rateAnisotropyMonte Carlo MethodAlgorithmsSoftwarePhysics in Medicine and Biology
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