Mineralogical Characterization and Dissolution Experiments in Gamble's Solution of Tremolitic Amphibole from Passo di Caldenno (Sondrio, Italy).

Jessica Choi,Alessandra Marengo,Federico Lucci,Ruggero Vigliaturo,Giancarlo Della Ventura,Michael O'Shea,Reto Gieré,Ileana Pérez-Rodríguez

doi:10.3390/min8120557

Abstract

In nature, asbestos is often associated with minerals and other non-asbestiform morphologies thought to be harmless, but not much is known about the potential toxic effects of these phases. Therefore, the characterization of natural assemblages should not be limited to asbestos fibers only. This paper combines a multi-analytical characterization of asbestos from Valmalenco (Italy) with data from dissolution experiments conducted in a simulated interstitial lung fluid (Gamble’s solution), and a detailed dimensional study that compares the particle population before and after this interaction. The sample is identified as a tremolitic amphibole, exhibiting a predominance of fiber and prismatic habits at lower magnification, but a bladed habit at higher magnification. The results show that at different magnification, the dimensional and habit distributions are notably different. After the dissolution experiments, the sample showed rounded edges and pyramid-shaped dissolution pits. Chemical analyses suggested that a nearly stoichiometric logarithmic loss of Si and Mg occurred associated with a relatively intense release of Ca in the first 24 h, whereas Fe was probably redeposited on the fiber surfaces. A rearrangement of the more frequent habits and dimensions was recorded after the dissolution experiment, with a peculiar increase of the proportion of elongated mineral particles.

Highlights

Exposure to asbestiform amphiboles can trigger several diseases, including asbestosis, squamous, small, and large-cell carcinoma, adenocarcinoma, and mesothelioma
Dimensional Results Obtained by Field Emission Environmental Scanning Electron Microscopy (FE-ESEM) for the Powdered Starting Material
After interaction with Gamble’s solution, the percentage of Elongated mineral particles (EMPs) in the sample is different compared to the sample before the dissolution experiment at each magnification: the proportion of

Summary

Introduction

Exposure to asbestiform amphiboles can trigger several diseases, including asbestosis, squamous-, small-, and large-cell carcinoma, adenocarcinoma, and mesothelioma. Minerals 2018, 8, 557 including their shapes and dimensional parameters, present in complex amphibole-bearing rocks or powders in order to assess their potential effect in disrupting normal physiological functions and homeostasis (e.g., iron homeostasis in cells). This approach is even more important after evidence has become available that asbestiform minerals may induce fibrosis and malignancies, and other diseases. While asbestosis and mesothelioma all over the world are immediately related to asbestos, the recognized cases of autoimmune disease are much rarer because of a lack of systematic investigation and sufficient available cohorts of study [4]. Only tremolite is regulated as asbestos, and the exact identification of the different fiber compositions can be dependent on the data reduction method used or can vary among different laboratories [5]

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Conclusion