Toxicity of size separated chrysotile fibres: The relevance of the macrophage-endothelial axis crosstalk.

Asbestos minerals have been widely exploited due to their physical-chemical properties, and chrysotile asbestos has accounted for about 95% of all asbestos commercially employed worldwide. The exposure to chrysotile, classified like other five amphibole asbestos species as carcinogenic to humans, represents a serious occupational and environmental hazard. Nevertheless, this mineral is still largely employed in about 65% of the countries worldwide, which still allow its "safe use". The complex mechanisms through which the mineral fibres induce toxicity are not yet completely understood. In this regard, the morphometric parameters of asbestos fibres (e.g., length, width, aspect ratio) are known for their fundamental role in determining the degree of pathogenicity. In this context, the potential toxicity of short chrysotile fibres remains widely debated due to the contradictory results from countless studies. Thus, the present study investigated the different toxicity mechanisms of two representative batches of short (length ≤5 µm) and long (length >5 µm) chrysotile fibres obtained by cryogenic milling. The fibre doses were based upon equal mass and size, since due to chrysotile ability to form bundles, it was not possible to calculate the number of fibers applied per cell. The cytotoxic, genotoxic, and pro-inflammatory potential of the two size-separated chrysotile fractions was investigated on human THP-1-derived macrophages and HECV endothelial cells, both separately and in a co-culture setup, mimicking the alveolar pro-inflammatory microenvironment, in time course experiments up to 1 week. Both chrysotile fractions displayed cytotoxic, genotoxic, and pro-inflammatory effects, with results comparable to the well-known damaging effects of crocidolite asbestos, or higher, as in the case of the longer chrysotile fraction. Furthermore, in presence of HECV, fibre-treated macrophages showed prolonged inflammation, indicating an interesting crosstalk between these cells able to sustain a low-grade chronic inflammation in the lung. In conclusion, these results help to shed light on some important open questions on the mechanisms of toxicity of chrysotile asbestos fibres.