TY - JOUR
T1 - Quantifying tumor-selective radiation dose enhancements using gold nanoparticles
T2 - A monte carlo simulation study
AU - Zhang, Sean X.
AU - Gao, Junfang
AU - Buchholz, Thomas A.
AU - Wang, Zhonglu
AU - Salehpour, Mohammad R.
AU - Drezek, Rebekah A.
AU - Yu, Tse Kuan
N1 - Funding Information:
This study was partially funded by a grant from the U. S. Department of Defense Breast Cancer Research Program (W81XWH-06-1-0672) and by the institutional core grant (CA 16672). The authors also wish to acknowledge the Department of Scientific Publications at The University of Texas M. D. Anderson Cancer Center for its editorial assistance during the preparation of this article. S.X.Zhang(*).J.Gao.Z.Wang.M.R.Salehpour Department of Radiation Physics, The University of Texas M. D. Anderson Cancer Center, 1515 Holcombe Blvd., Unit 1210, Houston, TX 77030, USA e-mail: [email protected]
PY - 2009
Y1 - 2009
N2 - Gold nanoparticles can enhance the biological effective dose of radiation delivered to tumors, but few data exist to quantify this effect. The purpose of this project was to build a Monte Carlo simulation model to study the degree of dose enhancement achievable with gold nanoparticles. A Monte Carlo simulation model was first built using Geant4 code. An Ir-192 brachytherapy source in a water phantom was simulated and the calculation model was first validated against previously published data. We then introduced up to 1013 gold nanospheres per cm3 into the water phantom and examined their dose enhancement effect. We compared this enhancement against a gold-water mixture model that has been previously used to attempt to quantify nanoparticle dose enhancement. In our benchmark test, dose-rate constant, radial dose function, and two-dimensional anisotropy function calculated with our model were within 2% of those reported previously. Using our simulation model we found that the radiation dose was enhanced up to 60% with 1013 gold nanospheres per cm3 (9.6% by weight) in a water phantom selectively around the nanospheres. The comparison study indicated that our model more accurately calculated the dose enhancement effect and that previous methodologies overestimated the dose enhancement up to 16%. Monte Carlo calculations demonstrate that biologically-relevant radiation dose enhancement can be achieved with the use of gold nanospheres. Selective tumor labeling with gold nanospheres may be a strategy for clinically enhancing radiation effects.
AB - Gold nanoparticles can enhance the biological effective dose of radiation delivered to tumors, but few data exist to quantify this effect. The purpose of this project was to build a Monte Carlo simulation model to study the degree of dose enhancement achievable with gold nanoparticles. A Monte Carlo simulation model was first built using Geant4 code. An Ir-192 brachytherapy source in a water phantom was simulated and the calculation model was first validated against previously published data. We then introduced up to 1013 gold nanospheres per cm3 into the water phantom and examined their dose enhancement effect. We compared this enhancement against a gold-water mixture model that has been previously used to attempt to quantify nanoparticle dose enhancement. In our benchmark test, dose-rate constant, radial dose function, and two-dimensional anisotropy function calculated with our model were within 2% of those reported previously. Using our simulation model we found that the radiation dose was enhanced up to 60% with 1013 gold nanospheres per cm3 (9.6% by weight) in a water phantom selectively around the nanospheres. The comparison study indicated that our model more accurately calculated the dose enhancement effect and that previous methodologies overestimated the dose enhancement up to 16%. Monte Carlo calculations demonstrate that biologically-relevant radiation dose enhancement can be achieved with the use of gold nanospheres. Selective tumor labeling with gold nanospheres may be a strategy for clinically enhancing radiation effects.
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U2 - 10.1007/s10544-009-9309-5
DO - 10.1007/s10544-009-9309-5
M3 - Article
C2 - 19381816
AN - SCOPUS:68149154889
SN - 1387-2176
VL - 11
SP - 925
EP - 933
JO - Biomedical Microdevices
JF - Biomedical Microdevices
IS - 4
ER -