Accurate Monte Carlo simulations for nozzle design, commissioning and quality assurance for a proton radiation therapy facility. - Wikidata - wikimedia - TriplyDB

Accurate Monte Carlo simulations for nozzle design, commissioning and quality assurance for a proton radiation therapy facility.

Accurate Monte Carlo simulations for nozzle design, commissioning and quality assurance for a proton radiation therapy facility.

http://www.wikidata.org/entity/Q51632872

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A phenomenological relative biological effectiveness (RBE) model for proton therapy based on all published in vitro cell survival data.Variations in linear energy transfer within clinical proton therapy fields and the potential for biological treatment planning Adaptation of GEANT4 to Monte Carlo dose calculations based on CT data.Secondary range shifting with range compensator for reduction of beam data library in heavy-ion radiotherapy.Assessment of out-of-field absorbed dose and equivalent dose in proton fields.Experimental validation of the TOPAS Monte Carlo system for passive scattering proton therapy.Secondary neutron spectrum from 250-MeV passively scattered proton therapy: measurement with an extended-range Bonner sphere system An MCNPX Monte Carlo model of a discrete spot scanning proton beam therapy nozzle Golden beam data for proton pencil-beam scanning Uncertainties and correction methods when modeling passive scattering proton therapy treatment heads with Monte Carlo.First steps towards a fast-neutron therapy planning program.Experimental depth dose curves of a 67.5 MeV proton beam for benchmarking and validation of Monte Carlo simulation.A modular method to handle multiple time-dependent quantities in Monte Carlo simulations.A framework for implementation of organ effect models in TOPAS with benchmarks extended to proton therapy Improved efficiency in Monte Carlo simulation for passive-scattering proton therapy.Extension of TOPAS for the simulation of proton radiation effects considering molecular and cellular endpoints.Proton SBRT for medically inoperable stage I NSCLC.Efficient voxel navigation for proton therapy dose calculation in TOPAS and Geant4.Comparison of out-of-field photon doses in 6 MV IMRT and neutron doses in proton therapy for adult and pediatric patients Dosimetric accuracy of planning and delivering small proton therapy fields.Patient study of in vivo verification of beam delivery and range, using positron emission tomography and computed tomography imaging after proton therapy.TOPAS: an innovative proton Monte Carlo platform for research and clinical applications.Comparison of MCNPX and Geant4 proton energy deposition predictions for clinical use PET/CT imaging for treatment verification after proton therapy: a study with plastic phantoms and metallic implants.Monte Carlo calculations for absolute dosimetry to determine machine outputs for proton therapy fields Effects of Hounsfield number conversion on CT based proton Monte Carlo dose calculations.Geometrical splitting technique to improve the computational efficiency in Monte Carlo calculations for proton therapy.Reduction of the secondary neutron dose in passively scattered proton radiotherapy, using an optimized pre-collimator/collimator.Assessment of organ-specific neutron equivalent doses in proton therapy using computational whole-body age-dependent voxel phantoms.Characterizing the response of miniature scintillation detectors when irradiated with proton beams.Range uncertainties in proton therapy and the role of Monte Carlo simulations.A review of the use and potential of the GATE Monte Carlo simulation code for radiation therapy and dosimetry applications.Automated Monte Carlo Simulation of Proton Therapy Treatment Plans.TOPAS Simulation of the Mevion S250 compact proton therapy unit.Commissioning a passive-scattering proton therapy nozzle for accurate SOBP delivery.An implementation to read and write IAEA phase-space files in GEANT4-based simulations.Phase Space Generation for Proton and Carbon Ion Beams for External Users' Applications at the Heidelberg Ion Therapy Center.Technical Note: On the analytical proton dose evaluation in compounds and mixtures.The energy margin strategy for reducing dose variation due to setup uncertainty in intensity modulated proton therapy (IMPT) delivered with distal edge tracking (DET)The clinical impact of uncertainties in the mean excitation energy of human tissues during proton therapy.

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P2860

Accurate Monte Carlo simulations for nozzle design, commissioning and quality assurance for a proton radiation therapy facility.

http://www.wikidata.org/entity/Q51632872

description

2004 nî lūn-bûn

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2004年学术文章

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2004年學術文章

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2004年學術文章

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Accurate Monte Carlo simulatio ...... on radiation therapy facility.

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P2860

Compensating for heterogeneities in proton radiation therapy.

Nuclear interactions in proton therapy: dose and relative biological effect distributions originating from primary and secondary particles.

Monte Carlo method to study the proton fluence for treatment planning.

Flattening of proton dose distributions for large-field radiotherapy.

Biophysical modelling of proton radiation effects based on amorphous track models.

Test of GEANT3 and GEANT4 nuclear models for 160 MeV protons stopping in CH2.

Monte Carlo and analytical calculation of proton pencil beams for computerized treatment plan optimization.

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radiation therapy