Bioaccessibility, release kinetics, and molecular speciation of arsenic and lead in geo-dusts from the Iron King Mine Federal Superfund site in Humboldt, Arizona

Nazune Menka; Rob Root; Jon Chorover

doi:10.1515/reveh-2014-0009

Bioaccessibility, release kinetics, and molecular speciation of arsenic and lead in geo-dusts from the Iron King Mine Federal Superfund site in Humboldt, Arizona

Nazune Menka, Rob Root, Jon Chorover

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

Mine tailings contain multiple toxic metal(loid)s that pose a threat to human health via inhalation and ingestion. The goals of this research include understanding the speciation and molecular environment of these toxic metal(loid)s (arsenic and lead) as well as the impacts particle size and residence time have on their bioaccessibilty in simulated gastric and lung fluid. Additionally, future work will include smaller size fractions (PM10 and PM2.5) of surface mine tailings, with the goal of increasing our understanding of multi-metal release from contaminated geo-dusts in simulated bio-fluids. This research is important to environmental human health risk assessment as it increases the accuracy of exposure estimations to toxic metal(loid)s.

Original language	English (US)
Pages (from-to)	23-27
Number of pages	5
Journal	Reviews on Environmental Health
Volume	29
Issue number	1-2
DOIs	https://doi.org/10.1515/reveh-2014-0009
State	Published - Apr 2014

Keywords

Arsenic
Geo-dust
Human health
Lead
Mine tailings
Simulated gastric fluid (SGF)
Simulated lung fluid (SLF)

ASJC Scopus subject areas

Health(social science)
Pollution
Public Health, Environmental and Occupational Health

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10.1515/reveh-2014-0009

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title = "Bioaccessibility, release kinetics, and molecular speciation of arsenic and lead in geo-dusts from the Iron King Mine Federal Superfund site in Humboldt, Arizona",

abstract = "Mine tailings contain multiple toxic metal(loid)s that pose a threat to human health via inhalation and ingestion. The goals of this research include understanding the speciation and molecular environment of these toxic metal(loid)s (arsenic and lead) as well as the impacts particle size and residence time have on their bioaccessibilty in simulated gastric and lung fluid. Additionally, future work will include smaller size fractions (PM10 and PM2.5) of surface mine tailings, with the goal of increasing our understanding of multi-metal release from contaminated geo-dusts in simulated bio-fluids. This research is important to environmental human health risk assessment as it increases the accuracy of exposure estimations to toxic metal(loid)s.",

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AU - Root, Rob

AU - Chorover, Jon

PY - 2014/4

Y1 - 2014/4

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AB - Mine tailings contain multiple toxic metal(loid)s that pose a threat to human health via inhalation and ingestion. The goals of this research include understanding the speciation and molecular environment of these toxic metal(loid)s (arsenic and lead) as well as the impacts particle size and residence time have on their bioaccessibilty in simulated gastric and lung fluid. Additionally, future work will include smaller size fractions (PM10 and PM2.5) of surface mine tailings, with the goal of increasing our understanding of multi-metal release from contaminated geo-dusts in simulated bio-fluids. This research is important to environmental human health risk assessment as it increases the accuracy of exposure estimations to toxic metal(loid)s.

KW - Arsenic

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KW - Simulated lung fluid (SLF)

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Bioaccessibility, release kinetics, and molecular speciation of arsenic and lead in geo-dusts from the Iron King Mine Federal Superfund site in Humboldt, Arizona

Abstract

Keywords

ASJC Scopus subject areas

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