Abstract
Various cell types are compromised by synthetic amorphous silica (SAS) if they are exposed to SAS under protein-free conditions in vitro. Addition of serum protein can mitigate most SAS effects, but it is not clear whether this is solely caused by protein corona formation and/or altered particle uptake. Because sensitive and reliable mass spectrometric measurements of SiO2 NP are cumbersome, quantitative uptake studies of SAS at the cellular level are largely missing. In this study, we combined the comparison of SAS effects on alveolar macrophages in the presence and absence of foetal calf serum with mass spectrometric measurement of 28Si in alkaline cell lysates. Effects on the release of lactate dehydrogenase, glucuronidase, TNFα and H2O2 of precipitated (SIPERNAT® 50, SIPERNAT® 160) and fumed SAS (AEROSIL® OX50, AEROSIL® 380 F) were lowered close to control level by foetal calf serum (FCS) added to the medium. Using a quantitative high resolution ICP-MS measurement combined with electron microscopy, we found that FCS reduced the uptake of particle mass by 9.9% (SIPERNAT® 50) up to 83.8% (AEROSIL® OX50). Additionally, larger particle agglomerates were less frequent in cells in the presence of FCS. Plotting values for lactate dehydrogenase (LDH), glucuronidase (GLU) or tumour necrosis factor alpha (TNFα) against the mean cellular dose showed the reduction of bioactivity with a particle sedimentation bias. As a whole, the mitigating effects of FCS on precipitated and fumed SAS on alveolar macrophages are caused by a reduction of bioactivity and by a lowered internalization, and both effects occur in a particle specific manner. The method to quantify nanosized SiO2 in cells is a valuable tool for future in vitro studies.
Highlights
Synthetic amorphous silica (SAS) form a major group of industrially relevant nanomaterials (NMs) [1,2,3]
ICP-MS measurement combined with electron microscopy, we found that foetal calf serum (FCS) reduced the uptake of particle mass by 9.9% (SIPERNAT® 50) up to 83.8% (AEROSIL® OX50)
The mitigating effects of FCS on precipitated and fumed SAS on alveolar macrophages are caused by a reduction of bioactivity and by a lowered internalization, and both effects occur in a particle specific manner
Summary
Synthetic amorphous silica (SAS) form a major group of industrially relevant nanomaterials (NMs) [1,2,3]. They are produced either from aqueous solutions of sodium silicate to form colloidal silica, silica gels, and precipitated silica, or may be synthesized from the gaseous phase of SiCl4 to form fumed (pyrogenic) silica [3,4]. Due to the production process, pyrogenic and precipitated silica form indivisible aggregates, which have no physical boundaries among their primary structures. These aggregates have external dimensions that are highly variable in nature with some particles being in the nano-size range [3,5]. Animal studies have shown that SAS can induce transient inflammatory responses in the rat lung [6,7,8,9,10] whereas fibrogenic or genotoxic effects, as induced by crystalline silica, such as quartz or cristobalite, were not induced even at high lung burden [11,12]
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