Skin penetration and decontamination of actinides

Les actinides sont des radioéléments couramment manipulés par les travailleurs de l'industrie nucléaire et font partie de la menace NRBC (nucléaire, radiologique, biologique, chimique). La contamination cutanée représente une voie d'exposition majeure de ces agents radiologiques. La décontamination de la peau est donc cruciale pour empêcher une dispersion de la contamination et l'absorption systémique du contaminant par la peau. Ce travail s'est attaché à évaluer les profils de pénétration cutanée de deux actinides : l'américium et le plutonium, sous différentes formes, dans un modèle d'étude ex vivo, la peau d'oreille de porc. L'efficacité de décontamination de différents produits usuels a également été testée sur ce modèle, mais aussi sur un modèle in vitro de poudre de couche cornée bovine. Pour compléter l'étude de la décontamination, l'efficacité d'une formulation d'hydrogel de DTPA a également été testée. La détermination de la distribution de la contamination dans la peau a été réalisée à l'aide de différentes techniques d'imagerie : l'autoradiographie par émulsion, le TASTRAK ou encore l'iQID camera. Les résultats ont montré une grande différence dans les profils de pénétration et de rétention des actinides lorsqu'ils sont en solution aqueuse modérément soluble ou en solution organique dans un mélange de solvant. De plus, cette dernière forme modifie fortement la structure cutanée, menant à une forte augmentation de la pénétration cutanée. Les résultats des protocoles de décontamination montrent une efficacité égale du savon (Trait rouge®) comparé au DTPA, qui est le traitement décorporant utilisé également en décontamination. La formulation en hydrogel présente une efficacité supérieure pour le traitement de solutions organiques et met en évidence l'intérêt de développer d'autres formulations galéniquesActinides are alpha-emitting radioactive elements handled by nuclear industry workers and are part of the NRBC threat (nuclear, radiological, biological, and chemical). Skin contamination represents a major exposure route for these radioelements. Skin decontamination is therefore essential to prevent any dispersion of contamination and systemic absorption through the skin. This work focused the evaluation of skin penetration behavior of two actinides: americium and plutonium, in different forms, in an ex vivo model, pig ear skin. The decontamination efficacy of various products was tested on this model as well as an in vitro model of bovine hide powder. The efficacy of a new DTPA hydrogel formulation was also tested. The localization of in different skin layers was carried out using various imaging techniques: emulsion autoradiography, solid track autoradiography, TASTRAK or iQID camera. Data showed differences in penetration, retention and localization profiles of the different actinides used in moderately soluble aqueous solution or in a solvent mixture. In addition, the latter modifies skin structure that is associated with an increase in skin penetration. Radioactivity activity measurements in skin layers agreed well with distribution as shown by the different autoradiography techniques. The results of decontamination protocols showed an equal efficacy of the soap (Trait rouge®) as compared to DTPA, that is used for decorporation therapy and also for decontamination. The hydrogel formulation showed a superior efficacy for the treatment of organic solutions and demonstrates the interest for development of other pharmaceutical formulation

Pénétration et décontamination cutanée des actinides

Actinides are alpha-emitting radioactive elements handled by nuclear industry workers and are part of the NRBC threat (nuclear, radiological, biological, and chemical). Skin contamination represents a major exposure route for these radioelements. Skin decontamination is therefore essential to prevent any dispersion of contamination and systemic absorption through the skin. This work focused the evaluation of skin penetration behavior of two actinides: americium and plutonium, in different forms, in an ex vivo model, pig ear skin. The decontamination efficacy of various products was tested on this model as well as an in vitro model of bovine hide powder. The efficacy of a new DTPA hydrogel formulation was also tested. The localization of in different skin layers was carried out using various imaging techniques: emulsion autoradiography, solid track autoradiography, TASTRAK or iQID camera. Data showed differences in penetration, retention and localization profiles of the different actinides used in moderately soluble aqueous solution or in a solvent mixture. In addition, the latter modifies skin structure that is associated with an increase in skin penetration. Radioactivity activity measurements in skin layers agreed well with distribution as shown by the different autoradiography techniques. The results of decontamination protocols showed an equal efficacy of the soap (Trait rouge®) as compared to DTPA, that is used for decorporation therapy and also for decontamination. The hydrogel formulation showed a superior efficacy for the treatment of organic solutions and demonstrates the interest for development of other pharmaceutical formulationsLes actinides sont des radioéléments couramment manipulés par les travailleurs de l'industrie nucléaire et font partie de la menace NRBC (nucléaire, radiologique, biologique, chimique). La contamination cutanée représente une voie d'exposition majeure de ces agents radiologiques. La décontamination de la peau est donc cruciale pour empêcher une dispersion de la contamination et l'absorption systémique du contaminant par la peau. Ce travail s'est attaché à évaluer les profils de pénétration cutanée de deux actinides : l'américium et le plutonium, sous différentes formes, dans un modèle d'étude ex vivo, la peau d'oreille de porc. L'efficacité de décontamination de différents produits usuels a également été testée sur ce modèle, mais aussi sur un modèle in vitro de poudre de couche cornée bovine. Pour compléter l'étude de la décontamination, l'efficacité d'une formulation d'hydrogel de DTPA a également été testée. La détermination de la distribution de la contamination dans la peau a été réalisée à l'aide de différentes techniques d'imagerie : l'autoradiographie par émulsion, le TASTRAK ou encore l'iQID camera. Les résultats ont montré une grande différence dans les profils de pénétration et de rétention des actinides lorsqu'ils sont en solution aqueuse modérément soluble ou en solution organique dans un mélange de solvant. De plus, cette dernière forme modifie fortement la structure cutanée, menant à une forte augmentation de la pénétration cutanée. Les résultats des protocoles de décontamination montrent une efficacité égale du savon (Trait rouge®) comparé au DTPA, qui est le traitement décorporant utilisé également en décontamination. La formulation en hydrogel présente une efficacité supérieure pour le traitement de solutions organiques et met en évidence l'intérêt de développer d'autres formulations galénique

Skin absorption of actinides: influence of solvents or chelates on skin penetration ex vivo

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Actinide bioimaging in tissues: Comparison of emulsion and solid track autoradiography techniques with the iQID camera

<div><p>This work presents a comparison of three autoradiography techniques for imaging biological samples contaminated with actinides: emulsion-based, plastic-based autoradiography and a quantitative digital technique, the iQID camera, based on the numerical analysis of light from a scintillator screen. In radiation toxicology it has been important to develop means of imaging actinide distribution in tissues as these radionuclides may be heterogeneously distributed within and between tissues after internal contamination. Actinide distribution determines which cells are exposed to alpha radiation and is thus potentially critical for assessing absorbed dose. The comparison was carried out by generating autoradiographs of the same biological samples contaminated with actinides with the three autoradiography techniques. These samples were cell preparations or tissue sections collected from animals contaminated with different physico-chemical forms of actinides. The autoradiograph characteristics and the performances of the techniques were evaluated and discussed mainly in terms of acquisition process, activity distribution patterns, spatial resolution and feasibility of activity quantification. The obtained autoradiographs presented similar actinide distribution at low magnification. Out of the three techniques, emulsion autoradiography is the only one to provide a highly-resolved image of the actinide distribution inherently superimposed on the biological sample. Emulsion autoradiography is hence best interpreted at higher magnifications. However, this technique is destructive for the biological sample. Both emulsion- and plastic-based autoradiography record alpha tracks and thus enabled the differentiation between ionized forms of actinides and oxide particles. This feature can help in the evaluation of decorporation therapy efficacy. The most recent technique, the iQID camera, presents several additional features: real-time imaging, separate imaging of alpha particles and gamma rays, and alpha activity quantification. The comparison of these three autoradiography techniques showed that they are complementary and the choice of the technique depends on the purpose of the imaging experiment.</p></div

Top-view of microscope slides set-up on the two configurations of the iQID camera.

<p>(a) Camera with sensitive diameter of 40 mm and (b) with a fiber-optic tape that increased the sensitive diameter to 115 mm.</p

Actinide distribution in different animal tissue samples imaged by three autoradiography techniques.

<p>Nuclear track emulsion (a-f), plastic detector TASTRAK^™ (g-i) and digital autoradiography with the iQID camera (j-l). MOX: mixed oxide of uranium, plutonium and americium. Exposure time is displayed on the lower left corner of each image. Emulsion- and plastic-based autoradiographs were observed with objective x2 (d-i). Blue ellipses were represented to facilitate the visualization of similar areas between plastic-based and iQID images for the lung section; the co-localization with the corresponding histological image remained difficult.</p

Alpha tracks from oxide particle in the plastic detector TASTRAK^™ at two magnifications: objectives 20 (a) and 60 (b).

<p>Sample is from lung macrophages contaminated with PuO₂. 1: orthogonal pit; 2: non-orthogonal pit.</p

Examples of selected biological samples contaminated with actinides.

<p>Examples of selected biological samples contaminated with actinides.</p

Autoradiographs from the same sample of rat lung macrophages after inhalation of PuO₂.

<p>Nuclear track emulsion (a), plastic detector TASTRAK^™ (b) and iQID autoradiographs (c). Exposure time is displayed on the lower left corner of each image. w: week; h: hours. Nuclear track emulsion technique was done last as it is a destructive endpoint. Three points of origin for appreciation of the spatial relationships and resolution of the tracks via each system are circled together in each frame. Emulsion- and plastic-based autoradiographs were observed with objective 2. The total alpha activity detected in the sample is displayed at the bottom of the iQID autoradiograph as estimated from this imaging technique.</p