4.5 Article

Chemo-physical properties of asbestos bodies in human lung tissues studied at the nano-scale by non-invasive, label free x-ray imaging and spectroscopic techniques

Journal

TOXICOLOGY LETTERS
Volume 348, Issue -, Pages 18-27

Publisher

ELSEVIER IRELAND LTD
DOI: 10.1016/j.toxlet.2021.05.002

Keywords

Asbestos; Lungs; Imaging; Tomography; Spectroscopy; Synchrotron radiation; X-ray fluorescence

Categories

Funding

  1. Marie SkodowskaCurie Individual Fellowship action BiominAB3D [GA707905H2020]

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In the lungs, asbestos forms Asbestos Bodies (AB) with a Fe-rich coating, serving as the interface between foreign fibers and the host organism. A novel combination of x-ray tomography and spectroscopy allowed the study of unaltered lung tissue samples containing chrysotile and crocidolite asbestos. The composition of all ABs analyzed was similar, indicating possible sources of Fe from the fibers or the host organism, with a decrease in silicon concentration from core to rim.
In the lungs, asbestos develops an Fe-rich coating (Asbestos Body, AB) that becomes the actual interface between the foreign fibers and the host organism. Conventional approaches to study ABs require an invasive sample preparation that can alter them. In this work, a novel combination of x-ray tomography and spectroscopy allowed studying unaltered lung tissue samples with chrysotile and crocidolite asbestos. The thickness and mass density maps of the ABs obtained by x-ray tomography were used to derive a truly quantitative elemental analysis from scanning x-ray fluorescence spectroscopy data. The average mass density of the ABs is compatible with that of highly loaded ferritin, or hemosiderin. The composition of all ABs analyzed was similar, with only minor differences in the relative elemental fractions. Silicon concentration decreased in the core-to-rim direction, indicating a possible partial dissolution of the inner fiber. The Fe content in the ABs was higher than that possibly contained in chrysotile and crocidolite. This finding opens two opposite scenarios, the first with Fe coming from the fiber bulk and concentrating on the surface as long as the fiber dissolves, the second where the Fe that takes part to the formation of the AB originates from the host organism Fe-pool. (c) 2021 Elsevier B.V. All rights reserved.

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