G. Etherington scite author profile

This report is the first in a series of reports replacing Publications 30 and 68 to provide revised dose coefficients for occupational intakes of radionuclides by inhalation and ingestion. The revised dose coefficients have been calculated using the Human Alimentary Tract Model (Publication 100) and a revision of the Human Respiratory Tract Model (Publication 66) that takes account of more recent data. In addition, information is provided on absorption into blood following inhalation and ingestion of different chemical forms of elements and their radioisotopes. In selected cases, it is judged that the data are sufficient to make material-specific recommendations. Revisions have been made to many of the models that describe the systemic biokinetics of radionuclides absorbed into blood, making them more physiologically realistic representations of uptake and retention in organs and tissues, and excretion. The reports in this series provide data for the interpretation of bioassay measurements as well as dose coefficients, replacing Publications 54 and 78. In assessing bioassay data such as measurements of whole-body or organ content, or urinary excretion, assumptions have to be made about the exposure scenario, including the pattern and mode of radionuclide intake, physical and chemical characteristics of the material involved, and the elapsed time between the exposure(s) and measurement. This report provides some guidance on monitoring programmes and data interpretation.

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A neutron diffraction study of the structure of evaporated amorphous germanium

Etherington

Wright

Wenzel

et al. 1982

Journal of Non-Crystalline Solids

239

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The influence of breathing patterns on particle deposition in a nasal replicate cast

Häußermann

Bailey

Bailey³

et al. 2002

Journal of Aerosol Science

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Neutron amorphography

Wright

Etherington

Desa

et al. 1982

Journal of Non-Crystalline Solids

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Effect of Particle Size on Slow Particle Clearance From the Bronchial Tree

Smith¹,

Bailey²,

Etherington³

et al. 2008

Experimental Lung Research

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The Human Respiratory Tract Model of the International Commission on Radiological Protection assumes that a fraction of particles deposited in the bronchial tree clears slowly, this fraction decreasing with increasing particle geometric diameter. To test this assumption, volunteers inhaled 5-microm aerodynamic diameter 111In-polystyrene and 198Au-gold particles simultaneously, as a 'bolus' at the end of each breath to minimize alveolar deposition. Because of the different densities (1.05 versus 19.3 g cm3), geometric diameters were about 5 and 1.2 microm, respectively, and corresponding predicted slowly cleared fractions were about 10% and 50%. However, lung retention of the 2 particles was similar in each subject. Retention at 24 hours, as a percentage of initial lung deposit (mean +/- SD) was 34 +/- 12 for polystyrene and 31 +/- 11 for the gold particles.

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G. Etherington

ICRP Publication 130: Occupational Intakes of Radionuclides: Part 1

A neutron diffraction study of the structure of evaporated amorphous germanium

The influence of breathing patterns on particle deposition in a nasal replicate cast

Neutron amorphography

Effect of Particle Size on Slow Particle Clearance From the Bronchial Tree

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