en Radiation Biology Radiation Biology تحقيق بديع Original Research <div style="text-align: justify;"><span style="font-size:10pt"><span style="text-justify:newspaper"><span style="text-kashida-space:50%"><span style="line-height:119%"><span style="font-family:Calibri"><span style="color:black"><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-style:italic"><span style="font-weight:bold"><span style="language:en-US">Background</span></span></span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-weight:bold"><span style="language:en-US">:</span></span></span></span></span> <span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:black"><span style="language:en-US">Dosimetry calculations in radioembolization therapy are known to include some uncertainties due to working assumptions. First, the microspheres used in the procedure are homogeneously distributed within the tumor volume. Second, Medical Internal Radiation Dosimetry (MIRD) method of dose calculation involves a mono-compartmental model only. To minimize the impact of these uncertainties, this study proposes Monte Carlo (MC) simulations as an alternative to MIRD method to verify the absorbed doses in the volumes of interest (tumor and its surroundings).&nbsp; </span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-style:italic"><span style="font-weight:bold"><span style="language:en-US">Material and Methods</span></span></span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-weight:bold"><span style="language:en-US">:</span></span></span></span></span> <span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:black"><span style="language:en-US">Lung, liver, and tumor volumes of 30 radioembolization patients were defined in a mathematical whole-body phantom and MC simulations were performed using Monte Carlo N-Particle code. Absorbed doses were calculated for these tissues both in addition to stomach wall, pancreas, spleen, and kidneys which are close to the tumor volume being treated with microspheres of radioembolization therapy containing the beta-emitting </span></span></span></span><span lang="en-US" style="font-size:5.9939pt"><span style="font-family:Calibri"><span style="color:black"><span style="language:en-US">⁹⁰</span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:black"><span style="language:en-US">Y radioisotope. </span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-style:italic"><span style="font-weight:bold"><span style="language:en-US">Results</span></span></span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-weight:bold"><span style="language:en-US">:</span></span></span></span></span> <span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:black"><span style="language:en-US">The doses absorbed by tumor, lung, and liver volumes of each patient were calculated by both MIRD methodology and MC simulations. The differences between the two methods were evaluated for normal lung tissue and tumor tissues in the liver where maximum differences were observed for tumor tissues (16.18%) and lungs (11.69%). Furthermore, it was observed through MC simulations; the organs that are close to the liver being treated were also exposed to the radiation for which absorbed doses could not be calculated by MIRD method. </span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="font-style:italic"><span style="font-weight:bold"><span style="language:en-US">Conclusion</span></span></span></span></span></span><span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:#1f497d"><span style="language:en-US">:</span></span></span></span> <span lang="en-US" style="font-size:9.0pt"><span style="font-family:Calibri"><span style="color:black"><span style="language:en-US">MC simulations may offer significant advantages for dose verification in radioembolization therapy.</span></span></span></span></span></span></span></span></span></span></div> Radioembolization, 90-Y, critical organ doses, MIRD, Monte Carlo simulations. 353 360 http://ijrr.com/browse.php?a_code=A-10-1-1052&slc_lang=en&sid=1 O.M. Yildirim 7900319475328460024002 7900319475328460024002 No Department of Bioengineering, Yildiz Technical University, 34220 Istanbul, Turkey A. Bingolbali ab1353@gmail.com 7900319475328460024003 7900319475328460024003 Yes Department of Bioengineering, Yildiz Technical University, 34220 Istanbul, Turkey A. Bozkurt 7900319475328460024004 7900319475328460024004 No Department of Biomedical Engineering, Akdeniz University, 07058 Antalya, Turkey C. Cafaro 7900319475328460024005 7900319475328460024005 No O.M. Yildirim1, A. Bingolbali1,2*, A. Bozkurt3, C. Cafaro4, M.O. Demirkol5 1Department of Bioengineering, Yildiz Technical University, 34220 Istanbul, Turkey 2Department of Physics, University at Albany-SUNY, 12222 Albany, NY, USA 3Department of Biomedical Engineering, Akdeniz University, 07058 Antalya, Turkey 4Department of Mathematics & Physics, SUNY Polytechnic Institute, 12222 Albany, NY, USA 5Department of Nuclear Medicine & Molecular Imaging, Koç University, 34450 Istanbul, Turkey M.O. Demirkol 7900319475328460024006 7900319475328460024006 No Department of Nuclear Medicine & Molecular Imaging, Koç University, 34450 Istanbul, Turkey