Current and future radionuclide speciation studies in biological media

Radionuclides may be released into the environment accidentally or incidentally, which could raise health risks when ingested or inhaled by humans. In order to study the behaviour of radionuclides in the human organism (metabolism, retention, excretion), knowledge of radionuclide speciation is indis...

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Published inRadiation protection dosimetry Vol. 127; no. 1-4; p. 97
Main Authors Ansoborlo, E, Bion, L, Doizi, D, Moulin, C, Lourenco, V, Madic, C, Cote, G, Van der Lee, J, Moulin, V
Format Journal Article
LanguageEnglish
Published England 01.01.2007
Subjects
Body Burden
Computer Simulation
Forecasting
Foreign Bodies - complications
Foreign Bodies - physiopathology
Humans
Injections - adverse effects
Kinetics
Metabolic Clearance Rate
Models, Biological
Plutonium - pharmacokinetics
Plutonium - toxicity
Radiation Injuries - etiology
Radiation Injuries - physiopathology
Radiometry - methods
Radiometry - trends
Relative Biological Effectiveness
Wounds, Penetrating - etiology
Wounds, Penetrating - physiopathology
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Summary:Radionuclides may be released into the environment accidentally or incidentally, which could raise health risks when ingested or inhaled by humans. In order to study the behaviour of radionuclides in the human organism (metabolism, retention, excretion), knowledge of radionuclide speciation is indispensable: speciation governs the transfer, bioavailability and toxicity of elements and is also of considerable interest for decorporation. In this context, the Commissariat à l'Energie Atomique has created a working group on speciation to share data both on thermodynamic constants and on speciation analysis methods of interest to chemists, environmentalists and biologists. The initial focus was on the 31 radionuclides described in different International Commission on Radiological Protection models (HRTM, HAT) and the National Council on Radiation Protection model (wound). Particular attention was devoted to selecting the inorganic and organic ligands, most representative of biological media. The base applied to speciation in solution and at interfaces and solubility (BASSIST) thermodynamic database was developed for this purpose. The aim of this paper is to present the state of the art on radionuclide speciation tools within biological media and to emphasise some missing data in order to orient future research.
ISSN:0144-8420
DOI:10.1093/rpd/ncm258