Assessment Of Physico-Chemical And Biokinetic Properties Of Uranium Peroxide Hydrate UO4

Ansoborlo, É.; Chazel, V.; Houpert, P.; Hengé-Napoli, M. H.; Paquet, Fabien; Hodgson, Alan; Stradling, N.

doi:10.1097/00004032-199810000-00005

Cited by 13 publications

(13 citation statements)

References 22 publications

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“…In our study, the UO 4 biokinetics after single UO 4 inhalation (AcUO4 group) agreed with previous UO 4 instillation studies (Ansoborlo et al, 1998;Houpert et al, 1999;Chazel et al, 2001). A rapid clearance of U from lungs resulted partly from its translocation to the blood, and U was subsequently excreted in the urine.…”

Section: Discussionsupporting

confidence: 91%

“…A rapid clearance of U from lungs resulted partly from its translocation to the blood, and U was subsequently excreted in the urine. Both our inhalation study and a previous instillation study, with comparable lung deposit (around 200µg), showed a UO 4 peak in kidneys of about 15% of the intake, at 3 days postexposure (Ansoborlo et al, 1998). The previous UO 2 exposures apparently modify the early UO 4 biokinetics in kidneys without modifying the day of appearance of the UO 4 peak in kidneys.…”

Section: Discussionsupporting

confidence: 75%

“…UO 2 is a subproduct of the enrichment process of U for radioactive fuel, while UO 4 is a subproduct of the reprocess steps of fuel after its use in nuclear reactor. UO 2 is considered by ICRP to be a very insoluble compound (absorption type S), while UO 4 is much more soluble (Ansoborlo et al, 1998) and considered as absorption type F. Due to this difference in solubility, their behavior and biokinetics in the organism are very different, with a long biological half-time for UO 2 staying in lungs and a rapid elimination of UO 4 from the lungs to the blood. The UO 2 characteristics were: insoluble depleted U; specific alpha activity = 13.10 3 Bq g −1 ; isotopic composition by mass: 238 U = 99.75%, 235 U = 0.24%, 234 U = 0.001%, 236 U < 0.0003%, 232 U < 0.00001%.…”

Section: Uranium Compoundsmentioning

confidence: 99%

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Distribution and Genotoxic Effects After Successive Exposure to Different Uranium Oxide Particles Inhaled by Rats

Monleau

Méo

Frelon

et al. 2006

Inhalation Toxicology

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In nuclear fuel cycle facilities, workers may inhale airborne uranium compounds that lead to internal contamination, with various exposure scenarios depending on the workplace. These exposures can be chronic, repeated, or acute, and can involve many different compounds. The effect of uranium after multiple scenarios of exposure is unknown. The aim of this study, therefore, was to investigate the genotoxic and biokinetics consequences of exposure to depleted insoluble uranium dioxide (UO2) by repeated or acute inhalation on subsequent acute inhalation of moderately soluble uranium peroxide (UO4) in rats. The results show that UO2 repeated preexposure by inhalation increases the genotoxic effects of UO4 inhalation, assessed by comet assay, in different cell types, when UO4 exposure alone has no effect. At the same time, the study of UO4 bioaccumulation showed that the UO4 biokinetics in the kidneys, gastrointestinal tract, and excreta, but not in the lungs, were slightly modified by previous UO2 exposures. All these results show that both genotoxic and biokinetics effects of uranium may depend on preexposure and that repeated exposure induces a potentiation effect compared with acute exposure.

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Section: Discussionsupporting

confidence: 91%

Section: Discussionsupporting

confidence: 75%

Section: Uranium Compoundsmentioning

confidence: 99%

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Distribution and Genotoxic Effects After Successive Exposure to Different Uranium Oxide Particles Inhaled by Rats

Monleau

Méo

Frelon

et al. 2006

Inhalation Toxicology

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“…Ansoborlo et al (1998a) used two different media (Gamble's solution and culture medium) for the solubility tests. The dissolution rate for the slow fraction of the material in Gamble's solution (an alternative to simulated lung fluid) was lower by a factor of 30.…”

Section: Determination Of Parameter Valuesmentioning

confidence: 99%

In vitro dissolution studies of uranium bearing material in simulated lung fluid

Sdraulig¹,

Franich

Tinker³

et al. 2008

Journal of Environmental Radioactivity

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“…1 For pulmonary toxicity studies, specialized equipment that includes aerosol generators, airflow monitoring instruments, exposure chambers, exhaust systems and often analytical chemical support is required in order to deliver known amounts of the test compound into the lungs. Consequently, the need for this equipment increases the cost and technical complexity of such studies.…”

mentioning

confidence: 99%

An automatic video instillator for intratracheal instillation in the rat

Kim

Lee²,

Hwang³

et al. 2010

Lab Anim

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Intratracheal instillation (ITI) of a test compound is an alternative method to inhalation methods that require complex aerosol generation, exposure chambers and airflow monitoring instruments for exposing the lungs of animals to a test compound. For ITI in the rat, a laryngoscope is generally used for endotracheal intubation, and the procedure is difficult to perform. Therefore, we designed and constructed an automatic video instillator (AVI) for the accurate delivery of a dose of a test compound into the trachea of rats. The device has a videocamera probe for image guidance, and a liquid-crystal display for image display. These two items are used to visualize the larynx and trachea for intratracheal insertion of the tubing, and for placing the tip of the instillation tubing beyond the vocal cords for ITI of the test compound. After a 2 h training session on the use of the AVI in an anaesthetized rat, we assessed the utility of the device by ITI of 0.25% (w/v) solution of Evans Blue dye into the lungs of 30 isoflurane-anaesthetized rats. Necropsy examinations were performed on 20 rats immediately after the completion of the procedure, and on 10 rats three days after the procedure. Based on the results of these examinations, we concluded that the device could be used for rapid, reproducible and successful ITI of a test compound into the lungs of a rat by one operator. The pulmonary toxicology of environmental toxins to assess their physicochemical characteristics, such as the effect of particle size and distribution, and the biological response that follows their exposure in humans is studied frequently by either inhalation or intratracheal instillation (ITI) of the toxin in rodents.1 For pulmonary toxicity studies, specialized equipment that includes aerosol generators, airflow monitoring instruments, exposure chambers, exhaust systems and often analytical chemical support is required in order to deliver known amounts of the test compound into the lungs. Consequently, the need for this equipment increases the cost and technical complexity of such studies.2 ITI has become a feasible alternative method for delivering a toxin into the lung of rodents, 3 -6 because the required equipment is less sophisticated than that required for inhalation toxicity studies. 7 -9 This method is also simpler and safer than the inhalation method: many dose levels of compounds with a wide range of physicochemical properties and toxicity can be introduced rapidly into the lungs with minimal risk to the operator. Furthermore, ITI is used often as a screen to determine an appropriate dose range for inhalation toxicity studies. Despite the advantages of ITI over inhalation, the use of ITI for the pulmonary toxicology studies in rodents does have limitations.10 One such limitation is the resultant pulmonary distribution of the toxin. In inhalation studies, the distribution of the test compound in the right and left lungs is uniform, whereas it is non-uniform when using ITI. In addition, Lakatos et al. suggested that oropharynge...

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Assessment Of Physico-Chemical And Biokinetic Properties Of Uranium Peroxide Hydrate UO4

Cited by 13 publications

References 22 publications

Distribution and Genotoxic Effects After Successive Exposure to Different Uranium Oxide Particles Inhaled by Rats

Distribution and Genotoxic Effects After Successive Exposure to Different Uranium Oxide Particles Inhaled by Rats

In vitro dissolution studies of uranium bearing material in simulated lung fluid

An automatic video instillator for intratracheal instillation in the rat

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