Accumulation of plutonium in mammalian wildlife tissues following dispersal by accidental-release tests

Accumulation of plutonium in mammalian wildlife tissues following dispersal by accidental-release tests

We examined the distribution of plutonium (Pu) in the tissues of mammalian wildlife inhabiting the relatively undisturbed, semi-arid former Taranaki weapons test site, Maralinga, Australia. The accumulation of absorbed Pu was highest in the skeleton (83% ± 6%), followed by muscle (10% ± 9%), liver (...

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Veröffentlicht in:Journal of environmental radioactivity 2016-01, Vol.151, p.387-394
Hauptverfasser: Johansen, M.P., Child, D.P., Caffrey, E.A., Davis, E., Harrison, J.J., Hotchkis, M.A.C., Payne, T.E., Ikeda-Ohno, A., Thiruvoth, S., Twining, J.R., Beresford, N.A.
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Sprache:eng
Schlagworte:
Animals
Bone
Liver
Mammals - metabolism
Particle
Partitioning
Plutonium
Plutonium - metabolism
Radiation Exposure
Radiation Monitoring
Radioactive Fallout
South Australia
Wildlife
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container_end_page 394
container_issue
container_start_page 387
container_title Journal of environmental radioactivity
container_volume 151
creator Johansen, M.P.
Child, D.P.
Caffrey, E.A.
Davis, E.
Harrison, J.J.
Hotchkis, M.A.C.
Payne, T.E.
Ikeda-Ohno, A.
Thiruvoth, S.
Twining, J.R.
Beresford, N.A.
description We examined the distribution of plutonium (Pu) in the tissues of mammalian wildlife inhabiting the relatively undisturbed, semi-arid former Taranaki weapons test site, Maralinga, Australia. The accumulation of absorbed Pu was highest in the skeleton (83% ± 6%), followed by muscle (10% ± 9%), liver (6% ± 6%), kidneys (0.6% ± 0.4%), and blood (0.2%). Pu activity concentrations in lung tissues were elevated relative to the body average. Foetal transfer was higher in the wildlife data than in previous laboratory studies. The amount of Pu in the gastrointestinal tract was highly elevated relative to that absorbed within the body, potentially increasing transfer of Pu to wildlife and human consumers that may ingest gastrointestinal tract organs. The Pu distribution in the Maralinga mammalian wildlife generally aligns with previous studies related to environmental exposure (e.g. Pu in humans from worldwide fallout), but contrasts with the partitioning models that have traditionally been used for human worker-protection purposes (approximately equal deposition in bone and liver) which appear to under-predict the skeletal accumulation in environmental exposure conditions. •Accumulation of absorbed Pu in the skeleton was highest among wildlife mammalian tissues.•The lungs and the gastrointestinal tract had relatively high Pu activity concentrations.•Results differ from traditional Pu partitioning models used for humans.
doi_str_mv 10.1016/j.jenvrad.2015.03.031
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subjects Animals
Bone
Liver
Mammals - metabolism
Particle
Partitioning
Plutonium
Plutonium - metabolism
Radiation Exposure
Radiation Monitoring
Radioactive Fallout
South Australia
Wildlife
title Accumulation of plutonium in mammalian wildlife tissues following dispersal by accidental-release tests
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