Introduction:Traditional methods for determining radiation dose in nuclear medicine include the Monte Carlo method,the discrete ordinate method,and the point kernel integration method.This study presents a new mathema...Introduction:Traditional methods for determining radiation dose in nuclear medicine include the Monte Carlo method,the discrete ordinate method,and the point kernel integration method.This study presents a new mathematical model for predicting the radiation dose rate in the vicinity of nuclear medicine patients.Methods:A new algorithm was created by combining the physical model of“cylinder superposition”of the human body with integral analysis to assess the radiation dose rate in the vicinity of nuclear medicine patients.Results:The model accurately predicted radiation dose rates within distances of 0.1–3.0 m,with a deviation of less than 11%compared to observed rates.The model demonstrated greater accuracy at shorter distances from the radiation source,with a deviation of only 1.55%from observed values at 0.1 m.Discussion:The model proposed in this study effectively represents the spatial and temporal distribution of the radiation field around nuclear medicine patients and demonstrates good agreement with actual measurements.This model has the potential to serve as a radiation dose rate alert system in hospital environments.展开更多
基金Supported by the National Natural Science Foundation of China(grant nos.31770907,31640022 and 31170806)the Beijing Natural Science Foundation(grant no.7172146).
文摘Introduction:Traditional methods for determining radiation dose in nuclear medicine include the Monte Carlo method,the discrete ordinate method,and the point kernel integration method.This study presents a new mathematical model for predicting the radiation dose rate in the vicinity of nuclear medicine patients.Methods:A new algorithm was created by combining the physical model of“cylinder superposition”of the human body with integral analysis to assess the radiation dose rate in the vicinity of nuclear medicine patients.Results:The model accurately predicted radiation dose rates within distances of 0.1–3.0 m,with a deviation of less than 11%compared to observed rates.The model demonstrated greater accuracy at shorter distances from the radiation source,with a deviation of only 1.55%from observed values at 0.1 m.Discussion:The model proposed in this study effectively represents the spatial and temporal distribution of the radiation field around nuclear medicine patients and demonstrates good agreement with actual measurements.This model has the potential to serve as a radiation dose rate alert system in hospital environments.