Your search keyword '"Eric Blanchardon"' showing total 106 results

101. Long term retention and excretion of 201Tl in a patient after myocardial perfusion imaging

Author

C. Challeton-de Vathaire, D. Celier, S. Cassot, Eric Blanchardon, G. Herbelet, D. Franck, Jean-René Jourdain, J.-C. Martin, A. Biau, P. Boisson, Laboratoire d'évaluation de la dose interne (DRPH/SDI/LEDI), and Institut de Radioprotection et de Sûreté Nucléaire (IRSN)

Subjects

radiation detector, Male, urinalysis, [SDV]Life Sciences [q-bio], tissue distribution, Myocardial Ischemia, Urine, radiation detection, Effective dose (radiation), 030218 nuclear medicine & medical imaging, 0302 clinical medicine, Urinary excretion, heart function, dose response, Medicine, Thallium, gamma spectrometry, Radiation, Radiological and Ultrasound Technology, medicine.diagnostic_test, article, General Medicine, 3. Good health, bioassay, drug excretion, 030220 oncology & carcinogenesis, radioactivity, radiation measurement, Biological half-life, radiation dose, whole body counter, thallium 201, heart muscle perfusion, Urinalysis, Metabolic Clearance Rate, chemistry.chemical_element, urinary excretion, Excretion, 03 medical and health sciences, Myocardial perfusion imaging, radioisotope distribution, coronary artery bypass graft, half life time, Coronary Circulation, case report, follow up, Humans, Radiology, Nuclear Medicine and imaging, human, Radionuclide Imaging, Aged, business.industry, Public Health, Environmental and Occupational Health, Biological Transport, Thallium Radioisotopes, chemistry, sodium iodide, functional assessment, heart scintiscanning, Radiopharmaceuticals, business, Nuclear medicine

Abstract

201Tl is widely used in nuclear medicine to carry out myocardial perfusion imaging (MPI). However, very limited data is available on long-term distribution in the body, excretion and corresponding dose. In this study we performed a 2 month follow-up of a patient who underwent MPI, by urine analysis and in vivo measurements. The biological half-life of thallium was consequently estimated to be 11.6-27 d, which is in partial agreement with previous studies. We also estimated excretion and retention of 200Tl, 201Tl and 202Tl isotopes using the biokinetic parameters from ICRP publication 53 and compared the forecast result with actual measurements. The latter demonstrated a higher urinary excretion and a higher body retention than what was expected. Our results therefore suggest that the long-term retention and consequently the effective dose coefficient for 201Tl considered in ICRP publications 53 and 80 may be slightly underestimated. © The Author 2005. Published by Oxford University Press. All rights reserved.

Published

2005

102. Lung doses due to multiple radiation exposures and risk of lung cancer death among French uranium miners

Author

Estelle Rage, Rodrigue S. Allodji, Alain Acker, Sylvaine Caër-Lorho, Eric Blanchardon, J. W. Marsh, H. Baysson, Dominique Laurier, and Blandine Vacquier

Subjects

Oncology, medicine.medical_specialty, Lung, business.industry, Public Health, Environmental and Occupational Health, respiratory system, medicine.disease, respiratory tract diseases, symbols.namesake, medicine.anatomical_structure, Absorbed dose, Internal medicine, Relative risk, Cohort, symbols, Relative biological effectiveness, Medicine, Poisson regression, business, Nuclear medicine, Lung cancer, Respiratory tract

Abstract

Objectives The study aims to assess the risk of lung cancer death associated with lung doses due to radon gas and its short-lived progeny (RnP), long-lived radionucleides (LLR) and external γ rays in the French cohort of uranium miners. Methods The cohort included 3271 exposed miners followed from 1956 through 1999. Annual exposures were assessed individually and lung doses were calculated according to the Human Respiratory Tract Model (Publication 66 of the International Commission on Radiological Protection). Poisson regression was used to fit linear excess relative risk (ERR) models to estimate dose-risk relationships. Results The mean absorbed lung dose due to α emitters was 78 milliGray (mGy), and to non-α emitters, 56 mGy. RnP accounted for 97% of the α absorbed dose. A significant ERR of lung cancer death was associated with the total absorbed lung dose (ERR/Gy (95% CI) = 2.9 (0.8–7.5)), the α absorbed dose (4.58 (1.3–10.9)) and RnP (4.6 (1.3–11.2)). Assuming a value of 20 for the relative biological effectiveness of α particles in lung cancer induction, the ERR/Gy-equivalent for the total-weighted lung dose was 0.2 (0.1–0.5), similar to that for the α-weighted and RnP-weighted lung dose. Conclusions These first results about lung doses from the European Alpha-Risk project, with regard to the lung dose distribution, support the major role of RnP in the risk of lung cancer death.

Published

2011

103. Updated biokinetic model for systemic americium.

Author

Rich Leggett and Eric Blanchardon

Subjects

*AMERICIUM, *RADIOISOTOPES

Abstract

The biokinetic model for systemic americium (Am) currently recommended by the International Commission on Radiological Protection (ICRP) for application to occupational intake of Am is based on information available through the early 1990s. Much additional information on Am biokinetics has been developed in the past 25 y, including measurements of retention and excretion of 241Am in many workers with 241Am burdens and post mortem measurements of 241Am in tissues of some of those workers. The ICRP’s current Am model is reasonably consistent with the updated information, with the main exception that the current model apparently overestimates 24-hour urinary Am as a fraction of skeletal or systemic Am at late times after intake. This paper provides an overview of current information on the systemic kinetics of Am in adult human subjects and laboratory animals and presents an updated biokinetic model for systemic Am that addresses the discrepancies between the current database and current ICRP systemic model for Am. This model is applied in Part 4 (to appear) of an ICRP series of reports on intake of radionuclides by workers called the OIR (Occupational Intake of Radionuclides) series. [ABSTRACT FROM AUTHOR]

Published

2019

104. Biokinetics and dose assessment after iodine intake in a thyroidectomised rat model.

Author

Meriem Mezaguer-Lekouaghet, Maamar Souidi, Abdewahab Badreddine, Eric Blanchardon, Jean-Marc Bertho, Mohamed Amine Benadjaoud, Ahcène Baz, and Zohra Lounis-Mokrani

Subjects

IODINE, NUCLEAR medicine, RADIATION protection, RATS

Abstract

Procedures using iodine-131 represent more than 90% of all therapies in nuclear medicine in Algeria. It is important to evaluate the long-term biological effects of iodine treatment on non-target organs to improve patient radiation protection. This experimental radiotoxicology study aims to determine the biokinetic models of iodine contamination. For this purpose, two Wistar rat models, with and without a thyroid, have been used to evaluate the biological half-life of iodine and then to perform a biodistribution study of iodine activity in 15 organs and tissues. For the most relevant organs, the respective absorbed doses have been calculated using RODES software. [ABSTRACT FROM AUTHOR]

Published

2019

105. RODES software for dose assessment of rats and mice contaminated with radionuclides.

Author

Maxime Locatelli, Hanane Miloudi, Gwennhael Autret, Daniel Balvay, Aurélie Desbrée, Eric Blanchardon, and Jean-Marc Bertho

Subjects

RADIOISOTOPES, RADIATION dosimetry, COMPUTER simulation, LABORATORY rats, MAGNETIC resonance imaging

Abstract

In order to support animal experiments of chronic radionuclides intake with realistic dosimetry, voxel-based three-dimensional computer models of mice and rats of both sexes and three ages were built from magnetic resonance imaging. Radiation transport of mono-energetic photons of 11 energies and electrons of 7 energies was simulated with MCNPX 2.6c to assess specific absorbed fractions (SAFs) of energy emitted from 13 source regions and absorbed in 28 target regions. RODES software was developed to combine SAF with radiation emission spectra and user-supplied biokinetic data to calculate organ absorbed doses per nuclear transformation of radionuclides in source regions (S-factors) and for specific animal experiments with radionuclides. This article presents the design of RODES software including the simulation of the particles in the created rodent voxel phantoms. SAF and S-factor values were compared favourably with published results from similar studies. The results are discussed for rodents of different ages and sexes. [ABSTRACT FROM AUTHOR]

Published

2017

106. Concerted Uranium Research in Europe (CURE): toward a collaborative project integrating dosimetry, epidemiology and radiobiology to study the effects of occupational uranium exposure.

Author

Olivier Laurent, Maria Gomolka, Richard Haylock, Eric Blanchardon, Augusto Giussani, Will Atkinson, Sarah Baatout, Derek Bingham, Elisabeth Cardis, Janet Hall, Ladislav Tomasek, Sophie Ancelet, Christophe Badie, Gary Bethel, Jean-Marc Bertho, Ségolène Bouet, Richard Bull, Cécile Challeton-de Vathaire, Rupert Cockerill, and Estelle Davesne

Subjects

URANIUM industry, IONIZING radiation dosage, RADIOISOTOPES, BIOMARKERS, MOLECULAR epidemiology, RADIATION dosimetry, SAFETY

Abstract

The potential health impacts of chronic exposures to uranium, as they occur in occupational settings, are not well characterized. Most epidemiological studies have been limited by small sample sizes, and a lack of harmonization of methods used to quantify radiation doses resulting from uranium exposure. Experimental studies have shown that uranium has biological effects, but their implications for human health are not clear. New studies that would combine the strengths of large, well-designed epidemiological datasets with those of state-of-the-art biological methods would help improve the characterization of the biological and health effects of occupational uranium exposure. The aim of the European Commission concerted action CURE (Concerted Uranium Research in Europe) was to develop protocols for such a future collaborative research project, in which dosimetry, epidemiology and biology would be integrated to better characterize the effects of occupational uranium exposure. These protocols were developed from existing European cohorts of workers exposed to uranium together with expertise in epidemiology, biology and dosimetry of CURE partner institutions. The preparatory work of CURE should allow a large scale collaborative project to be launched, in order to better characterize the effects of uranium exposure and more generally of alpha particles and low doses of ionizing radiation. [ABSTRACT FROM AUTHOR]

Published

2016