Literature DB >> 35669292

Consistency checks of results from a Monte Carlo code intercomparison for emitted electron spectra and energy deposition around a single gold nanoparticle irradiated by X-rays.

H Rabus1,2, W B Li3,2, H Nettelbeck1,2, J Schuemann4,2, C Villagrasa5,2, M Beuve6,2, S Di Maria7,2, B Heide8,2, A P Klapproth3,9, F Poignant6,10, R Qiu11,2, B Rudek4,12.   

Abstract

Organized by the European Radiation Dosimetry Group (EURADOS), a Monte Carlo code intercomparison exercise was conducted where participants simulated the emitted electron spectra and energy deposition around a single gold nanoparticle (GNP) irradiated by X-rays. In the exercise, the participants scored energy imparted in concentric spherical shells around a spherical volume filled with gold or water as well as the spectral distribution of electrons leaving the GNP. Initially, only the ratio of energy deposition with and without GNP was to be reported. During the evaluation of the exercise, however, the data for energy deposition in the presence and absence of the GNP were also requested. A GNP size of 50 nm and 100 nm diameter was considered as well as two different X-ray spectra (50 kVp and 100kVp). This introduced a redundancy that can be used to cross-validate the internal consistency of the simulation results. In this work, evaluation of the reported results is presented in terms of integral quantities that can be benchmarked against values obtained from physical properties of the radiation spectra and materials involved. The impact of different interaction cross-section datasets and their implementation in the different Monte Carlo codes is also discussed.

Entities:  

Year:  2021        PMID: 35669292      PMCID: PMC9165644          DOI: 10.1016/j.radmeas.2021.106637

Source DB:  PubMed          Journal:  Radiat Meas        ISSN: 1350-4487            Impact factor:   1.743


  20 in total

Review 1.  Physical basis and biological mechanisms of gold nanoparticle radiosensitization.

Authors:  Karl T Butterworth; Stephen J McMahon; Fred J Currell; Kevin M Prise
Journal:  Nanoscale       Date:  2012-07-06       Impact factor: 7.790

Review 2.  Track structure modeling in liquid water: A review of the Geant4-DNA very low energy extension of the Geant4 Monte Carlo simulation toolkit.

Authors:  M A Bernal; M C Bordage; J M C Brown; M Davídková; E Delage; Z El Bitar; S A Enger; Z Francis; S Guatelli; V N Ivanchenko; M Karamitros; I Kyriakou; L Maigne; S Meylan; K Murakami; S Okada; H Payno; Y Perrot; I Petrovic; Q T Pham; A Ristic-Fira; T Sasaki; V Štěpán; H N Tran; C Villagrasa; S Incerti
Journal:  Phys Med       Date:  2015-12-01       Impact factor: 2.685

Review 3.  Track structures, DNA targets and radiation effects in the biophysical Monte Carlo simulation code PARTRAC.

Authors:  Werner Friedland; Michael Dingfelder; Pavel Kundrát; Peter Jacob
Journal:  Mutat Res       Date:  2011-01-31       Impact factor: 2.433

4.  Determining dose enhancement factors of high-Z nanoparticles from simulations where lateral secondary particle disequilibrium exists.

Authors:  Hans Rabus; Elisabetta Gargioni; Wei Bo Li; Heidi Nettelbeck; Carmen Villagrasa
Journal:  Phys Med Biol       Date:  2019-08-07       Impact factor: 3.609

5.  Geant4-DNA example applications for track structure simulations in liquid water: A report from the Geant4-DNA Project.

Authors:  S Incerti; I Kyriakou; M A Bernal; M C Bordage; Z Francis; S Guatelli; V Ivanchenko; M Karamitros; N Lampe; S B Lee; S Meylan; C H Min; W G Shin; P Nieminen; D Sakata; N Tang; C Villagrasa; H N Tran; J M C Brown
Journal:  Med Phys       Date:  2018-06-14       Impact factor: 4.071

6.  A method for converting dose-to-medium to dose-to-tissue in Monte Carlo studies of gold nanoparticle-enhanced radiotherapy.

Authors:  B Koger; C Kirkby
Journal:  Phys Med Biol       Date:  2016-02-19       Impact factor: 3.609

7.  Corrigendum to "Intercomparison of dose enhancement ratio and secondary electron spectra for gold nanoparticles irradiated by X-rays calculated using multiple Monte Carlo simulation codes" [Phys. Med. 69 (2020) 147-163].

Authors:  W B Li; M Beuve; S Di Maria; W Friedland; B Heide; A P Klapproth; C Y Li; F Poignant; H Rabus; B Rudek; J Schuemann; C Villagrasa
Journal:  Phys Med       Date:  2020-11-14       Impact factor: 2.685

8.  The use of gold nanoparticles to enhance radiotherapy in mice.

Authors:  James F Hainfeld; Daniel N Slatkin; Henry M Smilowitz
Journal:  Phys Med Biol       Date:  2004-09-21       Impact factor: 3.609

9.  Nanodosimetric effects of gold nanoparticles in megavoltage radiation therapy.

Authors:  Stephen J McMahon; Wendy B Hyland; Mark F Muir; Jonathan A Coulter; Suneil Jain; Karl T Butterworth; Giuseppe Schettino; Glenn R Dickson; Alan R Hounsell; Joe M O'Sullivan; Kevin M Prise; David G Hirst; Fred J Currell
Journal:  Radiother Oncol       Date:  2011-09-15       Impact factor: 6.280

10.  TOPAS-nBio: An Extension to the TOPAS Simulation Toolkit for Cellular and Sub-cellular Radiobiology.

Authors:  J Schuemann; A L McNamara; J Ramos-Méndez; J Perl; K D Held; H Paganetti; S Incerti; B Faddegon
Journal:  Radiat Res       Date:  2019-01-04       Impact factor: 2.841
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