Your search keyword '"Bernar K"' showing total 2 results

1. The 15-Country Collaborative Study of Cancer Risk among Radiation Workers in the Nuclear Industry: study of errors in dosimetry.

Author

Thierry-Chef I, Marshall M, Fix JJ, Bermann F, Gilbert ES, Hacker C, Heinmiller B, Murray W, Pearce MS, Utterback D, Bernar K, Deboodt P, Eklof M, Griciene B, Holan K, Hyvonen H, Kerekes A, Lee MC, Moser M, Pernicka F, and Cardis E

Subjects

Adult, Body Burden, Cohort Studies, Employment statistics & numerical data, Female, Humans, Industry statistics & numerical data, International Cooperation, Male, Occupational Exposure analysis, Radiation Dosage, Reproducibility of Results, Risk Factors, Sensitivity and Specificity, Survival Analysis, Survival Rate, Neoplasms, Radiation-Induced mortality, Nuclear Reactors statistics & numerical data, Occupational Diseases mortality, Occupational Exposure statistics & numerical data, Radiation Monitoring statistics & numerical data, Risk Assessment methods, Whole-Body Counting statistics & numerical data

Abstract

To provide direct estimates of cancer risk after low-dose protracted exposure to ionizing radiation, a large-scale epidemiological study of nuclear industry workers was conducted in 15 countries. As part of this study, identification and quantification of errors in historical recorded doses was conducted based on a review of dosimetric practices and technologies in participating facilities. The main sources of errors on doses from "high-energy" photons (100-3000 keV) were identified as the response of dosimeters in workplace exposure conditions and historical calibration practices. Errors related to dosimetry technology and radiation fields were quantified to derive period- and facility-specific estimates of bias and uncertainties in recorded doses. This was based on (1) an evaluation of predominant workplace radiation from measurement studies and dosimetry expert assessment and (2) an estimation of the energy and geometry response of dosimeters used historically in study facilities. Coefficients were derived to convert recorded doses to H(p) (10) and organ dose, taking into account different aspects of the calibration procedures. A parametric, lognormal error structure model was developed to describe errors in doses as a function of facility and time period. Doses from other radiation types, particularly neutrons and radionuclide intake, could not be adequately reconstructed in the framework of the 15-Country Study. Workers with substantial doses from these radiation types were therefore identified and excluded from analyses. Doses from "lower-energy" photons (<100 keV) and from "higher-energy" photons (>3 MeV) were estimated to be small.

Published

2007

2. The 15-Country Collaborative Study of Cancer Risk among Radiation Workers in the Nuclear Industry: Study of Errors in Dosimetry

Author

Griciene B, M. Marshall, Fix Jj, A. Kerekes, H. Hyvonen, F. Pernicka, Ethel S. Gilbert, M. Moser, C. Hacker, P. Deboodt, Isabelle Thierry-Chef, M. Eklof, B. Heinmiller, K. Holan, F. Bermann, Lee Mc, Mark S. Pearce, D. Utterback, Murray W, Bernar K, and Elisabeth Cardis

Subjects

Adult, Employment, Male, medicine.medical_specialty, Neoplasms, Radiation-Induced, International Cooperation, Biophysics, Radiation Dosage, Risk Assessment, Sensitivity and Specificity, Whole-Body Counting, Ionizing radiation, Cohort Studies, Nuclear Reactors, Radiation Monitoring, Risk Factors, Nuclear industry, Occupational Exposure, medicine, Humans, Industry, Dosimetry, Radiology, Nuclear Medicine and imaging, Medical physics, Hacker, Radiation, Dosimeter, business.industry, Reproducibility of Results, Survival Analysis, Occupational Diseases, Survival Rate, Body Burden, Female, Cancer risk, Nuclear medicine, business

Abstract

To provide direct estimates of cancer risk after low-dose protracted exposure to ionizing radiation, a large-scale epidemiological study of nuclear industry workers was conducted in 15 countries. As part of this study, identification and quantification of errors in historical recorded doses was conducted based on a review of dosimetric practices and technologies in participating facilities. The main sources of errors on doses from "high-energy" photons (100-3000 keV) were identified as the response of dosimeters in workplace exposure conditions and historical calibration practices. Errors related to dosimetry technology and radiation fields were quantified to derive period- and facility-specific estimates of bias and uncertainties in recorded doses. This was based on (1) an evaluation of predominant workplace radiation from measurement studies and dosimetry expert assessment and (2) an estimation of the energy and geometry response of dosimeters used historically in study facilities. Coefficients were derived to convert recorded doses to H(p) (10) and organ dose, taking into account different aspects of the calibration procedures. A parametric, lognormal error structure model was developed to describe errors in doses as a function of facility and time period. Doses from other radiation types, particularly neutrons and radionuclide intake, could not be adequately reconstructed in the framework of the 15-Country Study. Workers with substantial doses from these radiation types were therefore identified and excluded from analyses. Doses from "lower-energy" photons (100 keV) and from "higher-energy" photons (3 MeV) were estimated to be small.

Published

2007