Your search keyword '"Xu, X. G."' showing total 4 results

1. Conversion coefficients based on the VIP-Man anatomical model and EGS4.

Author

Chao TC, Bozkurt A, and Xu XG

Subjects

Female, Health Physics instrumentation, Health Physics methods, Humans, Image Processing, Computer-Assisted, Male, Monte Carlo Method, National Library of Medicine (U.S.), Organ Specificity, Radiometry methods, United States, Air Pollutants, Radioactive, Environmental Exposure, Models, Anatomic, Phantoms, Imaging, Photons

Abstract

A new set of conversion coefficients from kerma free-in-air to absorbed dose and kerma free-in-air to "effective VIP-Man dose" has been calculated for external monoenergetic photon beams from 10 keV to 10 MeV using an image-based whole-body anatomical model. This model, called VIP-Man, was recently developed at Rensselaer from the high-resolution color images of the National Library of Medicine's Visible Human Project. An EGS4-based Monte Carlo user code, named EGS4-VLSI, was developed to efficiently process the extremely large image data in VIP-Man. Irradiation conditions include anterior-posterior, posterior-anterior, right lateral, left lateral, rotational, and isotropic geometries. Conversion coefficients from this study are compared with those obtained from two mathematical models, ADAM and EVA. "Effective VIP-Man doses" differ from the previously reported effective dose results by 10%-50% for photons between 100 keV and 10 MeV. Discrepancies are more significant at lower energies and for individual organ doses. Since VIP-Man is a realistic model that contains several tissues that were not previously defined well (or not available) in other models, the reported results offer an opportunity to improve the existing dosimetric data and the mathematical models.

Published

2001

2. Organ dose conversion coefficients for 0.1-10 MeV electrons calculated for the VIP-Man tomographic model.

Author

Chao TC, Bozkurt A, and Xu XG

Subjects

Humans, Male, Monte Carlo Method, National Library of Medicine (U.S.), Neurons, Organ Specificity, Photons, Radiometry instrumentation, Radiometry methods, United States, Electrons, Models, Anatomic, Radiation Dosage

Abstract

A whole-body tomographic model, called VIP-Man, was recently developed at Rensselaer Polytechnic Institute from the high-resolution color photographic images of the National Library of Medicine's Visible Human Project. An EGS4-based Monte Carlo user code, named EGS4-VLSI, was developed to efficiently transport electrons using the large image data set for VIP-Man. VIP-Man has been used to calculate doses for neutrons and photons. This paper presents a new set of fluence-to-absorbed-dose conversion coefficients for monoenergetic electron beams between 100 keV and 10 MeV for VIP-Man. Irradiation conditions include anterior-posterior, posterior-anterior, right lateral, left lateral, rotational, and isotropic source geometries. Comparisons between organ doses from VIP-Man, which is taller and heavier than the Reference Man, and existing data from mathematical models show significant discrepancies. It appears that even slight differences between body models can cause dramatic dosimetric deviations for low penetrating electron irradiation. This suggests that a single standard body model may poorly represent a large population and may not be acceptable for electron dosimetry.

Published

2001

3. Fluence-to-dose conversion coefficients based on the VIP-Man anatomical model and MCNPX code for monoenergetic neutrons above 20 MeV.

Author

Bozkurt A, Chao TC, and Xu XG

Subjects

Humans, Male, Models, Theoretical, Monte Carlo Method, National Library of Medicine (U.S.), Organ Specificity, Phantoms, Imaging, Photography, Radiation Monitoring methods, United States, Models, Anatomic, Neutrons, Radiation Dosage, Radiation Protection

Abstract

A new set of fluence-to-absorbed dose and fluence-to-effective dose conversion coefficients has been calculated for high-energy neutrons using a whole-body anatomical model, VIP-Man, developed from the high-resolution transversal color photographic images of the National Library of Medicine's Visible Human Project. Organ dose calculations were performed using the Monte Carlo code MCNPX for 20 monoenergetic neutron beams between 20 MeV and 10,000 MeV under 6 different irradiation geometries: anterior-posterior, posterior-anterior, left lateral, right lateral, isotropic, and rotational. For neutron Monte Carlo calculations, results based on an image-based whole-body model were not available in the literature. The absorbed dose results for 24 major organs of VIP-Man are presented in the form of tables and selected figures that compare with those based on simplified mathematical phantoms reported in the literature. VIP-Man yields up to 40% larger values of effective dose and many organ doses, thus suggesting that the results reported in the past may not be conservative.

Published

2001

4. Specific absorbed fractions from the image-based VIP-Man body model and EGS4-VLSI Monte Carlo code: internal electron emitters.

Author

Chao TC and Xu XG

Subjects

Bone Marrow radiation effects, Dose-Response Relationship, Radiation, Electron Transport, Environmental Exposure, Humans, National Library of Medicine (U.S.), Organ Specificity, Phantoms, Imaging, Tissue Distribution, United States, Electrons, Health Physics methods, Image Processing, Computer-Assisted methods, Models, Anatomic, Monte Carlo Method, Radiometry methods

Abstract

VIP-Man is a whole-body anatomical model newly developed at Rensselaer from the high-resolution colour images of the National Library of Medicine's Visible Human Project. This paper summarizes the use of VIP-Man and the Monte Carlo method to calculate specific absorbed fractions from internal electron emitters. A specially designed EGS4 user code, named EGS4-VLSI, was developed to use the extremely large number of image data contained in the VIP-Man. Monoenergetic and isotropic electron emitters with energies from 100 keV to 4 MeV are considered to be uniformly distributed in 26 organs. This paper presents, for the first time, results of internal electron exposures based on a realistic whole-body tomographic model. Because VIP-Man has many organs and tissues that were previously not well defined (or not available) in other models, the efforts at Rensselaer and elsewhere bring an unprecedented opportunity to significantly improve the internal dosimetry.

Published

2001