The rise in breast cancer diagnoses among Chinese women has necessitated the use of X-ray breast screening,which carries a radiation risk.This study aimed to provide a dosimetry protocol for the Chinese female populat...The rise in breast cancer diagnoses among Chinese women has necessitated the use of X-ray breast screening,which carries a radiation risk.This study aimed to provide a dosimetry protocol for the Chinese female population to replace the traditional standard that utilizes simplified breast models,for the accurate estimation of the mean glandular dose of a patient undergoing digital breast tomosynthesis(DBT).The first set of detailed Chinese female breast models and representative breast parameters was constructed.Considering backscatter radiation and computational efficiency,we improved the combination of these models and the Chinese reference adult female whole-body voxel phantom.Image acquisition for four commercial DBT systems that are widely employed in China was simulated using the Monte Carlo method to obtain the normalized glandular dose coefficients of DBT(D_(gN)^(DBT))and the glandular depth dose(D_(g)^(dep)(z))for different breast characteristics and X-ray spectra.We calculated a series of D_(gN)^(DBT) values for breasts with different percentage mass glandularities(5%,25%,50%,75%,and 100%)and compressed breast thicknesses(2,3,4,5,6,and 7 cm)at various tube potentials(25,28,30,32,35,and 49 kV)and target/filter combinations(W/Rh,W/Al,Mo/Mo,Rh/Rh,and Rh/Ag).The parameter dependence of the breast characteristics and beam conditions on D_(gN)^(DBT) in detailed breast models was investigated.The D_(gN)^(DBT) results were 14.6-51.0%lower than those of the traditional dosimetry standard in China.The difference in D_(gN)^(DBT) was mainly due to a decrease in the depth of the main energy deposition area caused by the glandular distribution along the depth direction.The results obtained in this study may be used to improve breast dosimetry in China and provide more detailed information on risk assessment during DBT.展开更多
INTERNAL DOSE RESEARCH PAPERS INTDOSKIT:An R-Code for Calculation of Dose Coefficients and Studying Their Uncertainties Bastian Breustedt 1,Niranjan Chavan 2,Thomas Makumbi 2(1.Karlsruhe Institute of Technology,Instit...INTERNAL DOSE RESEARCH PAPERS INTDOSKIT:An R-Code for Calculation of Dose Coefficients and Studying Their Uncertainties Bastian Breustedt 1,Niranjan Chavan 2,Thomas Makumbi 2(1.Karlsruhe Institute of Technology,Institute of Biomedical Engineering(IBT),Fritz-Haber-Weg 1,D-76131 Karlsruhe,Germany;2.Karlsruhe Institute of Technology,Institute for Thermal Energy Technology and Safety(ITES),Hermann-von-Helmholtz-Platz 1,76344 EggensteinLeopoldshafen,Germany)Abstract:An R-code,which allows the calculation of the time dependent activity distribution based on ICRP reference models,the number of decays in a commitment period,and the dose coefficients for tissues and organs of the human body,has been developed.R Language was chosen due to its powerful mathematical and statistical modeling features,as well as its graphical capabilities.展开更多
基金supported by the National Natural Science Foundation of China(Nos.U2167209 and 12175114)the National Key R&D Program of China(No.2021YFF0603600).
文摘The rise in breast cancer diagnoses among Chinese women has necessitated the use of X-ray breast screening,which carries a radiation risk.This study aimed to provide a dosimetry protocol for the Chinese female population to replace the traditional standard that utilizes simplified breast models,for the accurate estimation of the mean glandular dose of a patient undergoing digital breast tomosynthesis(DBT).The first set of detailed Chinese female breast models and representative breast parameters was constructed.Considering backscatter radiation and computational efficiency,we improved the combination of these models and the Chinese reference adult female whole-body voxel phantom.Image acquisition for four commercial DBT systems that are widely employed in China was simulated using the Monte Carlo method to obtain the normalized glandular dose coefficients of DBT(D_(gN)^(DBT))and the glandular depth dose(D_(g)^(dep)(z))for different breast characteristics and X-ray spectra.We calculated a series of D_(gN)^(DBT) values for breasts with different percentage mass glandularities(5%,25%,50%,75%,and 100%)and compressed breast thicknesses(2,3,4,5,6,and 7 cm)at various tube potentials(25,28,30,32,35,and 49 kV)and target/filter combinations(W/Rh,W/Al,Mo/Mo,Rh/Rh,and Rh/Ag).The parameter dependence of the breast characteristics and beam conditions on D_(gN)^(DBT) in detailed breast models was investigated.The D_(gN)^(DBT) results were 14.6-51.0%lower than those of the traditional dosimetry standard in China.The difference in D_(gN)^(DBT) was mainly due to a decrease in the depth of the main energy deposition area caused by the glandular distribution along the depth direction.The results obtained in this study may be used to improve breast dosimetry in China and provide more detailed information on risk assessment during DBT.
文摘INTERNAL DOSE RESEARCH PAPERS INTDOSKIT:An R-Code for Calculation of Dose Coefficients and Studying Their Uncertainties Bastian Breustedt 1,Niranjan Chavan 2,Thomas Makumbi 2(1.Karlsruhe Institute of Technology,Institute of Biomedical Engineering(IBT),Fritz-Haber-Weg 1,D-76131 Karlsruhe,Germany;2.Karlsruhe Institute of Technology,Institute for Thermal Energy Technology and Safety(ITES),Hermann-von-Helmholtz-Platz 1,76344 EggensteinLeopoldshafen,Germany)Abstract:An R-code,which allows the calculation of the time dependent activity distribution based on ICRP reference models,the number of decays in a commitment period,and the dose coefficients for tissues and organs of the human body,has been developed.R Language was chosen due to its powerful mathematical and statistical modeling features,as well as its graphical capabilities.
