Computational phantoms are commonly used in internal radiation dosimetry to assess the amount and distribution pattern of energy deposited in various parts of the human body from different internal radiation sources. Radiation dose assessments are commonly performed on predetermined reference computational phantoms while the argument for individualized patientspecific radiation dosimetry exists. This study aims to evaluate the influence of body habitus on internal dosimetry and to quantify the uncertainties in dose estimation correlated with the use of fixed reference models. The 5-year-old IT'IS male phantom was modified to match target anthropometric parameters, including body weight, body height and sitting height/stature ratio (SSR), de...
Purpose: Positron emission tomography (PET) plays an important role in the diagnosis, staging, treat...
In the internal dose evaluation, the specific absorbed fraction (SAF) and S-value are calculated fro...
The emission of radiation from a contaminated body region is connected with the dose received by rad...
Computational phantoms are commonly used in internal radiation dosimetry to assess the amount and di...
The phantoms used in standardized dose assessment are based on amedian (i.e., 50th percentile) indiv...
Radionuclide therapy requires patient-specific planning of the absorbed dose to target volumes, in m...
Purpose: Estimation of the radiation dose to internal organs is essential for the assessment of radi...
The objective of radiation dosimetry both at organ and cellular levels, as applied to radiation prot...
Computational phantom libraries have been developed over the years to enhance the accuracy of Monte ...
International audienceIn diagnostic nuclear medicine, mean absorbed doses to patients' organs and ef...
The aim of this study was to use a new system of realistic voxel phantoms, based on computed tomogra...
In the internal dose evaluation, the specific absorbed fraction (SAF) and S-value are calculated fro...
Computational models of the human body - together with radiation transport codes - have been used fo...
PET uses specific molecules labelled with positron-emitting radionuclides to provide valuable bioche...
Purpose: Positron emission tomography (PET) plays an important role in the diagnosis, staging, treat...
In the internal dose evaluation, the specific absorbed fraction (SAF) and S-value are calculated fro...
The emission of radiation from a contaminated body region is connected with the dose received by rad...
Computational phantoms are commonly used in internal radiation dosimetry to assess the amount and di...
The phantoms used in standardized dose assessment are based on amedian (i.e., 50th percentile) indiv...
Radionuclide therapy requires patient-specific planning of the absorbed dose to target volumes, in m...
Purpose: Estimation of the radiation dose to internal organs is essential for the assessment of radi...
The objective of radiation dosimetry both at organ and cellular levels, as applied to radiation prot...
Computational phantom libraries have been developed over the years to enhance the accuracy of Monte ...
International audienceIn diagnostic nuclear medicine, mean absorbed doses to patients' organs and ef...
The aim of this study was to use a new system of realistic voxel phantoms, based on computed tomogra...
In the internal dose evaluation, the specific absorbed fraction (SAF) and S-value are calculated fro...
Computational models of the human body - together with radiation transport codes - have been used fo...
PET uses specific molecules labelled with positron-emitting radionuclides to provide valuable bioche...
Purpose: Positron emission tomography (PET) plays an important role in the diagnosis, staging, treat...
In the internal dose evaluation, the specific absorbed fraction (SAF) and S-value are calculated fro...
The emission of radiation from a contaminated body region is connected with the dose received by rad...