Differences among Monte Carlo codes in the calculations of voxel S values for radionuclide targeted therapy and analysis of their impact on absorbed dose evaluations.

Several updated Monte Carlo (MC) codes are available to perform calculations of voxel S values for radionuclide targeted therapy. The aim of this work is to analyze the differences in the calculations obtained by different MC codes and their impact on absorbed dose evaluations performed by voxel dosimetry. Voxel S values for monoenergetic sources (electrons and photons) and different radionuclides (90Y, 131I, and 188Re) were calculated. Simulations were performed in soft tissue. Three general-purpose MC codes were employed for simulating radiation transport: MCNP4C, EGSnrc, and GEANT4. The data published by the MIRD Committee in Pamphlet No. 17, obtained with the EGS4 MC code, were also included in the comparisons. The impact of the differences (in terms of voxel S values) among the MC codes was also studied by convolution calculations of the absorbed dose in a volume of interest. For uniform activity distribution of a given radionuclide, dose calculations were performed on spherical and elliptical volumes, varying the mass from 1 to 500 g. For simulations with monochromatic sources, differences for self-irradiation voxel S values were mostly confined within 10% for both photons and electrons, but with electron energy less than 500 keV, the voxel S values referred to the first neighbor voxels showed large differences (up to 130%, with respect to EGSnrc) among the updated MC codes. For radionuclide simulations, noticeable differences arose in voxel S values, especially in the bremsstrahlung tails, or when a high contribution from electrons with energy of less than 500 keV is involved. In particular, for 90Y the updated codes showed a remarkable divergence in the bremsstrahlung region (up to about 90% in terms of voxel S values) with respect to the EGS4 code. Further, variations were observed up to about 30%, for small source-target voxel distances, when low-energy electrons cover an important part of the emission spectrum of the radionuclide (in our case, for 131I). For 90Y and 188Re, the differences among the various codes have a negligible impact (within few percents) on convolution calculations of the absorbed dose; thus either one of the MC programs is suitable to produce voxel S values for radionuclide targeted therapy dosimetry. However, if a low-energy beta-emitting radionuclide is considered, these differences can affect also dose depositions at small source-target voxel distances, leading to more conspicuous variations (about 9% for 1311) when calculating the absorbed dose in the volume of interest.

[1]  I. Kawrakow Accurate condensed history Monte Carlo simulation of electron transport. I. EGSnrc, the new EGS4 version. , 2000, Medical physics.

[2]  G. Martinelli,et al.  High-Dose Radioimmunotherapy with 90Y-Ibritumomab Tiuxetan: Comparative Dosimetric Study for Tailored Treatment , 2007, Journal of Nuclear Medicine.

[3]  I. Kawrakow,et al.  3D electron dose calculation using a Voxel based Monte Carlo algorithm (VMC). , 1996, Medical physics.

[4]  W E Bolch,et al.  MIRD pamphlet No. 17: the dosimetry of nonuniform activity distributions--radionuclide S values at the voxel level. Medical Internal Radiation Dose Committee. , 1999, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[5]  E. Poon,et al.  Accuracy of the photon and electron physics in GEANT4 for radiotherapy applications. , 2005, Medical physics.

[6]  Carlo Chiesa,et al.  Dosimetry in myeloablative (90)Y-labeled ibritumomab tiuxetan therapy: possibility of increasing administered activity on the base of biological effective dose evaluation. Preliminary results. , 2007, Cancer biotherapy & radiopharmaceuticals.

[7]  R. Taylor,et al.  Benchmarking brachydose: Voxel based EGSnrc Monte Carlo calculations of TG-43 dosimetry parameters. , 2007, Medical physics.

[8]  Wesley E. Bolch,et al.  3D internal dosimetry for radio-immunotherapy using Voxel S-Values approach , 2007 .

[9]  M. D'Andrea,et al.  Monte Carlo dose voxel kernel calculations of beta-emitting and Auger-emitting radionuclides for internal dosimetry: A comparison between EGSnrcMP and EGS4. , 2006, Medical physics.

[10]  G. D. Valdez,et al.  ITS: the integrated TIGER series of electron/photon transport codes-Version 3.0 , 1991, Conference Record of the 1991 IEEE Nuclear Science Symposium and Medical Imaging Conference.

[11]  R Wang,et al.  Monte Carlo dose calculations of beta-emitting sources for intravascular brachytherapy: a comparison between EGS4, EGSnrc, and MCNP. , 2001, Medical physics.

[12]  K. F. Eckerman,et al.  Specific absorbed fractions of energy at various ages from internal photon sources: 6, Newborn , 1987 .

[13]  A. Kazemnejad,et al.  Comparison of MCNP4C and EGSnrc Monte Carlo codes in depth-dose calculation of low energy clinical electron beams , 2007 .

[14]  Michael G Stabin,et al.  Uncertainties in Internal Dose Calculations for Radiopharmaceuticals , 2008, Journal of Nuclear Medicine.

[15]  I. Kawrakow,et al.  Dose calculation validation of Vmc++ for photon beams. , 2007, Medical physics.

[16]  O. Chibani,et al.  Monte Carlo dose calculations in homogeneous media and at interfaces: a comparison between GEPTS, EGSnrc, MCNP, and measurements. , 2002, Medical physics.

[17]  Firas Mourtada,et al.  Dosimetry characterization of a 32P source wire used for intravascular brachytherapy with automated stepping. , 2003, Medical physics.

[18]  B. Wessels,et al.  The MIRD Perspective 1999 , 1999 .

[19]  S Vynckier,et al.  Evaluation of a commercial VMC++ Monte Carlo based treatment planning system for electron beams using EGSnrc/BEAMnrc simulations and measurements. , 2009, Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics.