Characterization of minerals in pleural plaques from lung tissue of nonhuman primates

Authors

  • Anne E. Taunton
  • Mickey E. Gunter
  • Robert P. Nolan
  • James I. Phillips

DOI:

https://doi.org/10.2451/2011PM0014

Keywords:

asbestos, in vivo, SEM, powder X-ray diffraction, pleural plaques

Abstract

Periodico di Mineralogia (2011), 80, 1 (Special Issue), 167-179 - DOI: 10.2451/2011PM0014
Special Issue in memory of Sergio Lucchesi

Characterization of minerals in pleural plaques from lung tissue of non-human primates

Anne E. Taunton1, Mickey E. Gunter1, 2,*, Robert P. Nolan3 and James I. Phillips4

1Department of Geological Sciences, University of Idaho, Moscow, Idaho, USA
2Marsh Professor-at-Large, University of Vermont, Burlington, Vermont, USA
3Earth and Environmental Sciences of the Graduate School and University Center
of The City University of New York, New York, USA
4Pathology Division, National Institute for Occupational Health, National Health Laboratory Service and School of Pathology, Faculty of Health Sciences,University of Witwatersrand, Johannesburg, South Africa
*Corresponding author: mailto:mgunter@uidaho.edu

Abstract

To examine the hypothesis that secondary minerals precipitate in the lung after the inhalation of fibrous minerals, pleural plaques from 11 non-human primates (NHP) were examined using scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDS), and powder X-ray diffraction (XRD). Two NHPs served as controls, and nine were exposed to either low (1 f/cc) or high (1000 f/cc) levels of chrysotile, asbestiform grunerite (amosite), asbestiform riebeckite (crocidolite), or glass fibers. XRD analysis revealed apatite in pleural plaques of six NHPs, and SEM-EDS analysis found small quantities of apatite in three additional NHPs. XRD analysis identified calcite in one control NHP and one exposed to chrysotile (with talc present) and in the NHPs exposed to high doses of glass fibers, chrysotile, and grunerite. XRD analysis detected 2:1 expandable clays in NHPs exposed to high levels of glass fibers, chrysotile, grunerite and riebeckite. XRD also detected amphiboles in NHPs exposed to high levels of grunerite and riebeckite. SEM-EDS analysis revealed Mg-rich silicates in a control NHP and one NHP exposed to low doses of chrysotile. Asbestos bodies coating fibers were detected in NHPs exposed to high levels of grunerite and chrysotile. Iron-rich silicate fibers without coatings were identified in the NHP exposed to high levels of riebeckite using SEM-EDS. SEM-EDS also revealed Na-rich silicates in one NHP exposed to low doses of chrysotile. Because minerals other than exposure minerals were detected in many of the NHPs, the hypothesis that secondary minerals may form in the lung after exposure to fibrous minerals should be considered when addressing the health effects of minerals.


Key words: asbestos; in vivo; SEM; powder X-ray diffraction; pleural plaques.

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