Nuclear Technology & Radiation Protection Journal


NT & RP Journal	MONTE CARLO MODELING OF THE YTTRIUM-90 NANOSPHERES APPLICATION IN THE LIVER RADIONUCLIDE THERAPY AND ORGANS DOSES CALCULATION
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Vol. XXXI, No. 1, Pp. 1-109 March 2016 UDC 621.039+614.876:504.06 ISSN 1451-3994 Back to Contents	Pages: 89-96 Authors: Seyed Mostafa Ghavami, Hosein Ghiasi, and Asghar Mesbahi Abstract Using the nano-scaled radionuclides in the radionuclide therapy significantly reduces the particles trapping in the organs vessels and avoids thrombosis formations. Additionally, uniform distribution in the target organ may be another benefit of the nanoradionuclides in the radionuclide therapy. Monte Carlo simulation was conducted to model a mathematical humanoid phantom and the liver cells of the simulated phantom were filled with the ⁹⁰Y nanospheres. Healthy organs doses, fatal and nonfatal risks of the surrounding organs were estimated. The estimations and calculations were made in four different distribution patterns of the radionuclide seeds. Maximum doses and risks estimated for the surrounding organs were obtained in the high edge concentrated distribution model of the liver including the nanoradionuclides. For the dose equivalent, effective dose, fatal and non-fatal risks, the values obtained as 7.51E-03 Sv/Bq, 3.01E-01 Sv/Bq, and 9.16E-01 cases/10⁴ persons for the bladder, colon, and kidney of the modeled phantom, respectively. The mentioned values were the maximum values among the studied modeled distributions. Maximum values of Normal Tissue Complication Probability for the healthy organs calculated as 5.9-8.9 %. Result of using nanoparticles of the ⁹⁰Y provides promising dosimetric properties in MC simulation results considering non-toxicity reports for the radionuclide. Key words: nanoscaled ⁹⁰Y, internal dosimetry, organs absorbed dose, risk estimation, radionuclide therapy FULL PAPER IN PDF FORMAT (1.29 MB)
Vinča Institute of Nuclear Sciences :: Designed by milas :: July 2007 Operated by acapanic :: Last updated on April, 2016

Pages: 89-96

Authors: Seyed Mostafa Ghavami, Hosein Ghiasi, and Asghar Mesbahi

Abstract

Using the nano-scaled radionuclides in the radionuclide therapy significantly reduces the particles trapping in the organs vessels and avoids thrombosis formations. Additionally, uniform distribution in the target organ may be another benefit of the nanoradionuclides in the radionuclide therapy. Monte Carlo simulation was conducted to model a mathematical humanoid phantom and the liver cells of the simulated phantom were filled with the ⁹⁰Y nanospheres. Healthy organs doses, fatal and nonfatal risks of the surrounding organs were estimated. The estimations and calculations were made in four different distribution patterns of the radionuclide seeds. Maximum doses and risks estimated for the surrounding organs were obtained in the high edge concentrated distribution model of the liver including the nanoradionuclides. For the dose equivalent, effective dose, fatal and non-fatal risks, the values obtained as 7.51E-03 Sv/Bq, 3.01E-01 Sv/Bq, and 9.16E-01 cases/10⁴ persons for the bladder, colon, and kidney of the modeled phantom, respectively. The mentioned values were the maximum values among the studied modeled distributions. Maximum values of Normal Tissue Complication Probability for the healthy organs calculated as 5.9-8.9 %. Result of using nanoparticles of the ⁹⁰Y provides promising dosimetric properties in MC simulation results considering non-toxicity reports for the radionuclide.

Key words: nanoscaled ⁹⁰Y, internal dosimetry, organs absorbed dose, risk estimation, radionuclide therapy

FULL PAPER IN PDF FORMAT (1.29 MB)