SAS induced pulmonary injury in animals via an inflammatory process following high exposure concentrations. Due to fast and complete elimination of SAS from pulmonary tissues and the body,
no SAS accumulation occurs. The observed changes in animal experiments are reversible up to very high exposures, which can practically not be obtained under normal conditions of handling and use of these materials by workers and consumers. As non-threshold effects (mutagenicity) are not involved in the cascade of key events, there is no human health risk associated with SAS if current occupational hygiene standards are met. The biological activity and toxicity of silica is related to its physical and chemical properties (such as crystallinity, shape, composition www.selleckchem.com/products/Vorinostat-saha.html and surface reactivity). The specific physical and chemical properties need to be considered in the ecotoxicological or toxicological testing.
In particular, SAS materials usually do not exist as single particles (primary particles, nodules) but in the form of micro-metre-sized, firmly bound aggregated and loosely connected agglomerates. However, authors of studies on SAS or “nanosilica” often BYL719 manufacturer only report the primary particle size and insufficiently characterise their test material, which makes interpretation and comparison with other test materials and studies difficult. Stabilised colloidal silica with isolated particles in the nano-size range is commercially available, however it usually also quickly polymerizes to bigger aggregates under physiological testing conditions. Aggregation and agglomeration of SAS particles grossly reduces their bioavailability. In contrast to crystalline silica, SAS slowly dissolves in aqueous environments and body fluids. None of the SAS types Ceramide glucosyltransferase was shown to bioaccumulate and all disappear within a few weeks from living organisms by physiological excretion mechanisms. The tendency to supersaturate increases the elimination from body tissues. Any silica
absorbed (either as particle or in dissolved form) is excreted by the kidneys without evidence of accumulation in the body. This is very different from crystalline silica forms which exhibit a marked tendency to accumulate and persist in the lung and lymph nodes. SAS adsorbs to cellular surfaces and can affect membrane structures and integrity. The biological activity and in vitro cytotoxicity can be related to the particle surface characteristics interfacing with the biological milieu rather than to particle size. The physical properties and the results from mechanistic studies with other particles suggest that smaller particles, due to their greater surface area per unit of mass, may be more effective in inducing toxic effects.