Metal Ion Release from Engineered Stone Dust in Artificial Lysosomal Fluid-Variation with Time and Stone Type.

Inhalational exposure to dust from engineered stone (ES), also known as artificial or composite stone, is associated with a specific disease profile, namely accelerated silicosis, and scleroderma. The pathogenic mechanisms are poorly understood, particularly the role of resin and metal ions. Metal ions are present in pigments and constituent minerals and may be considered potential contributors to toxicity. The aim of this preliminary study was to understand the solubility of ES-containing metals in artificial lysosomal fluid (ALF) simulating the acidic intracellular environment of the lung macrophage lysosome. Differences with respect to ES types and temporal release were explored. Ten ES products of variable colour and company origin were comminuted and assessed for four different metals, solubilized into ALF solutions at 1,2,4 and 8 weeks at 37 °C. There was significant variability in metal release, particularly with regard to iron and manganese, which could be correlated with the reflected brightness of the stone. A majority of the available Mn, Fe, Al and Ti was solubilized. Time trends for metal release varied with ES type but also with metal ion. The data suggest a high metal ion bioavailability once engulfed by lung macrophages. There is a need to investigate a wider range of ES dust and relate metal content to markers of ES toxicity.

Skin Absorption of Ethylene Oxide Gas Following Exposures Relevant to HAZMAT Incidents.

Ethylene oxide (EO) is a reactive gas used by numerous industries and medical facilities as a sterilant, a fumigant, and as a chemical intermediate in chemical manufacturing. Due to its common use, EO has been involved in a number of leaks and explosive incidents/accidents requiring HAZMAT response. However, the extent of skin absorption under short-term HAZMAT conditions has not been directly assessed. Such data would assist decision making by first responders regarding skin decontamination in EO HAZMAT incidents. An in vitro test protocol with human skin was used for EO exposures at 800 ppm and 3000 ppm. No evidence of dermal penetration was seen for 800 ppm EO during a 30-min challenge. For 3000 ppm, EO penetration was observed after 20 min and was greater under higher temperature/humidity conditions. Fabric (heavy cotton) on skin enhanced penetration 5-fold compared with naked skin. Off gassing from exposed fabric was rapid. The results show dermal uptake of EO vapour from exposure at 3000 ppm is small but clothing may contribute to further dermal absorption/penetration over time. For exposed, but asymptomatic, persons in EO HAZMAT incidents first responders should remove bulky clothing to prevent potential skin damage and further uptake.