Methylmercury is among the most potentially toxic species to which human populations are exposed, both at high levels through poisonings and at lower levels through consumption of fish and other seafood. However, the molecular mechanisms of methylmercury toxicity in humans remain poorly understood. We used synchrotron X-ray absorption spectroscopy (XAS) to study mercury chemical forms in human brain tissue. Individuals poisoned with high levels of methylmercury species showed elevated cortical selenium with significant proportions of nanoparticulate mercuric selenide plus some inorganic mercury and methylmercury bound to organic sulfur. Individuals with a lifetime of high fish consumption showed much lower levels of mercuric selenide and methylmercury cysteineate. Mercury exposure did not perturb organic selenium levels. These results elucidate a key detoxification pathway in the central nervous system and provide new insights into the appropriate methods for biological monitoring.
Industrial
release of mercury into the local Minamata environment
with consequent poisoning of local communities through contaminated
fish and shellfish consumption is considered the classic case of environmental
mercury poisoning. However, the mercury species in the factory effluent
has proved controversial, originally suggested as inorganic, and more
recently as methylmercury species. We used newly available methods
to re-examine the cerebellum of historic Cat 717, which was fed factory
effluent mixed with food to confirm the source. Synchrotron high-energy-resolution
fluorescence detection-X-ray absorption spectroscopy revealed sulfur-bound
organometallic mercury with a minor β-HgS phase. Density functional
theory indicated energetic preference for α-mercuri-acetaldehyde
as a waste product of aldehyde production. The consequences of this
alternative species in the “classic” mercury poisoning
should be re-evaluated.
Hydroquinone (HQ) has been used since the 1950s in commercially available over-the-counter skin lightener products and since the 1960s as a commercially available medical product. It is also used in cosmetic products such as hair dyes and products for coating finger nails. Beginning in 2001, HQ is no longer authorized for use in cosmetic skin lightening formulations in European Union countries, although products containing arbutin, an analogue of HQ, and botanicals, including plants that naturally contain HQ and arbutin, continue to remain available in European countries. The potential toxicity of HQ is dependent on the route of exposure, and toxicity in rodents is highly sex-, species-, and strain-specific. Subchronic and chronic toxicity in experimental animals is primarily limited to nephrotoxicity in male F-344 rats. Dermal toxicity studies, even those conducted in the sensitive male F-344 rat, are essentially devoid of systemic toxicity. Developmental and reproductive toxicity studies with HQ in rats and rabbits have not demonstrated significant effects. Cancer bioassay data for HQ demonstrate limited effects and are not sufficient to classify HQ for human carcinogenicity. Epidemiology and occupational studies of workers with extensive exposure to HQ have not reported any evidence of adverse systemic health effects or carcinogenicity. A risk-benefit approach is recommended for assessing the available data for HQ, arbutin, and other materials in use as, or proposed for use as, skin lighteners to provide optimal therapeutic benefits to patients with pigmentary changes of the skin.
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