Introduction: The present study was conducted with the aim of designing a liver phantom for dosimetry. To benchmark the results obtained by the developed liver phantom, another method was applied for the dosimetry of a real liver tissue using imaging. Materials and Methods: For the purpose of the study, a real liver tissue was converted into a phantom based on thegram-molecular weight of the components of human liver tissue, mass percentage, and density, and then simulated by MCNPX code for dosimetry. The real liver tissue was contoured using the computed tomography DICOM images of the abdomen region. Subsequently, the accurate geometry of the segmented liver tissue was generated and simulated by MATLAB software and MCNPX code for dosimetric purposes. Then, the obtained data were transferred into the MCNPX code. Results: Equivalent dose was measured in total and for each component of the liver phantom and separated liver tissue. The results obtained from these two simulations were compared with each other to validate the efficiency of the phantom and evaluated the differences. Conclusion: The comparison of the equivalent doses obtained from the prepared equivalent liver phantom and the real liver tissue revealed the applicability of the liver phantom as a virtual liver for dosimetry.
Chakraborty S, Das T, Sarma H, Venkatesh M, Banerjee S. Preparation and preliminary studies on 177Lu-labeled hydroxylapatite particles for possible use in the therapy of liver cancer. Nuclear Medicine and Biology. 2008;35: 589-97.
Reginatto M. What can we learn about the spectrum of high-energy stray neutron fields from Bonner sphere measurements?. Rad Measur. 2009;44:692-99.
Mousavi Shirazi SA, Sardari D. Design and simulation of a new model for treatment by NCT. Sci Technol Nucl Ins. 2012; 2012:1-7. Doi:10.1155/2012/213640.
Kramer R, Cassola VF, Khoury HJ , et al. FASH and MASH: female and male adult human phantoms based on polygon mesh surfaces: II. Dosimetric calculations. Physics in Medicine and Biology. 2010;55:163-89.
Wambaugh J, Shah I. A Model for Micro-Dosimetry in Virtual Liver Tissues. The 10th International Conference on Systems Biology Stanford. 2009 August 31-September 4; California (USA).
Stenvall A, Larsson E, Strand SE, Jönsson BA. A small-scale anatomical dosimetry model of the liver. Phys Med Biol. 2014; 59:3353-71. Doi: 10.1088/0031-9155/59/13/3353.
Postuma I, Bortolussi S, Protti N, Ballarini F, Bruschi P and et al. An improved neutron autoradiography set-up for 10B concentration measurements in biological samples. Reports of Practical Oncology and Radiotherapy. 2016;21:123-8.
Koivunoro H, Bleuel D, Nastasi U, Lou T, Reijonen J and et al. BNEUTRON THERAPY dose distribution in liver with epithermal D–D and D–T fusion-based neutron beams. Applied Radiation and Isotopes. 2004;61:853-9.
McBride J, Mason M, Scott E. The Storage of the Major Liver Components. Biol Chem. 1941;1:943-52.
Clark H. The Cure for All Diseases (FE). New Century Press, 1995.
Högberg J, Rizell M, Hultborn R, Svensson J, Henrikson O, Mölne J , et al. Increased absorbed liver dose in Selective Internal Radiation Therapy (SIRT) correlates with increased sphere-cluster frequency and absorbed dose inhomogeneity. European Journal of Nuclear Medicine and Molecular Imaging. 2015; 2(1):10. Doi: 10.1186/s40658-015-0113-4.
Lorette WT. The Chemical Composition of Adipose Tissue of Man and Mice. Exp Physiol.1962; 47:179-88.
Martin AD, Daniel MZ, Drinkwater DT, Clarys JP. Adipose tissue density, estimated adipose lipid fraction and whole body adiposity in male cadavers. Int J Obes Relat Metab Disord. 1994;18:79-83.
Otte JW, Merrick MA, Ingersoll CD, Cordova ML. Subcutaneous adipose tissue thickness alters cooling time during cryotherapy. Arch Phys Med Rehabil. 2002;83:1501-5.
Broder V. Observations on skin thickness and subcutaneous tissue in man. Z Morph Anthrop. 1960;50:386-95.
Smith JT, Hawkins RM, Guthrie JA and et al. Effect of slice thickness on liver lesion detection and characterisation by multidetector CT. J Med Imaging Radiat Oncol. 2010; 54:188-93. Doi: 10.1111/j.1754-9485.2010.02157.x.
Hounsfield GN. Computed medical imaging. J RADIOL. 1980;61(6-7):459-68.
Reeves TE, Mah P, McDavid WD. Deriving Hounsfield units using grey levels in cone beam CT: a clinical application. Dentomaxillofac Radiol. 2012;41:500-8. Doi: 10.1259/dmfr/31640433.
Mousavi Shirazi, S. A. (2018). Development of a Liver Phantom Based on Computed Tomography Images for Dosimetric Purpose. Iranian Journal of Medical Physics, 15(3), 183-191. doi: 10.22038/ijmp.2018.27035.1277
MLA
Seyed Alireza Mousavi Shirazi. "Development of a Liver Phantom Based on Computed Tomography Images for Dosimetric Purpose". Iranian Journal of Medical Physics, 15, 3, 2018, 183-191. doi: 10.22038/ijmp.2018.27035.1277
HARVARD
Mousavi Shirazi, S. A. (2018). 'Development of a Liver Phantom Based on Computed Tomography Images for Dosimetric Purpose', Iranian Journal of Medical Physics, 15(3), pp. 183-191. doi: 10.22038/ijmp.2018.27035.1277
VANCOUVER
Mousavi Shirazi, S. A. Development of a Liver Phantom Based on Computed Tomography Images for Dosimetric Purpose. Iranian Journal of Medical Physics, 2018; 15(3): 183-191. doi: 10.22038/ijmp.2018.27035.1277
)