Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries

<p>Abstract</p> <p>The abundant iron sulfide mineral pyrite has been shown to catalytically produce hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>) and hydroxyl radical (<b><sup>.</sup></b>OH) in slurries of oxygenated water. Understan...

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Main Authors: Fisher Shawn C, Schoonen Martin AA, Brownawell Bruce J
Format: Article
Language:English
Published: BMC 2012-02-01
Series:Geochemical Transactions
Online Access:http://www.geochemicaltransactions.com/content/13/1/3
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spelling doaj-f58ef0915c604e4cabcb1f2dee50d64c2020-11-25T01:01:15ZengBMCGeochemical Transactions1467-48662012-02-01131310.1186/1467-4866-13-3Phenylalanine as a hydroxyl radical-specific probe in pyrite slurriesFisher Shawn CSchoonen Martin AABrownawell Bruce J<p>Abstract</p> <p>The abundant iron sulfide mineral pyrite has been shown to catalytically produce hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>) and hydroxyl radical (<b><sup>.</sup></b>OH) in slurries of oxygenated water. Understanding the formation and fate of these reactive oxygen species is important to biological and ecological systems as exposure can lead to deleterious health effects, but also environmental engineering during the optimization of remediation approaches for possible treatment of contaminated waste streams. This study presents the use of the amino acid phenylalanine (Phe) to monitor the kinetics of pyrite-induced <b><sup>.</sup></b>OH formation through rates of hydroxylation forming three isomers of tyrosine (Tyr) - <it>ortho</it>-, <it>meta</it>-, and <it>para</it>-Tyr. Results indicate that about 50% of the Phe loss results in Tyr formation, and that these products further react with <b><sup>.</sup></b>OH at rates comparable to Phe. The overall loss of Phe appeared to be pseudo first-order in [Phe] as a function of time, but for the first time it is shown that initial rates were much less than first-order as a function of initial substrate concentration, [Phe]<sub>o</sub>. These results can be rationalized by considering that the effective concentration of <b><sup>.</sup></b>OH in solution is lower at a higher level of reactant and that an increasing fraction of <b><sup>.</sup></b>OH is consumed by Phe-degradation products as a function of time. A simplified first-order model was created to describe Phe loss in pyrite slurries which incorporates the [Phe]<sub>o</sub>, a first-order dependence on pyrite surface area, the assumption that all Phe degradation products compete equally for the limited supply of highly reactive <b><sup>.</sup></b>OH, and a flux that is related to the release of H<sub>2</sub>O<sub>2 </sub>from the pyrite surface (a result of the incomplete reduction of oxygen at the pyrite surface). An empirically derived rate constant, <b>K<sub>pyr</sub></b>, was introduced to describe a variable <b><sup>.</sup></b>OH-reactivity for different batches of pyrite. Both the simplified first-order kinetic model, and a more detailed numerical simulation, yielded results that compare well to the observed kinetic data describing the effects of variations in concentrations of both initial Phe and pyrite. This work supports the use of Phe as a useful probe to assess the formation of <b><sup>.</sup></b>OH in the presence of pyrite, and its possible utility for similar applications with other minerals.</p> http://www.geochemicaltransactions.com/content/13/1/3
collection DOAJ
language English
format Article
sources DOAJ
author Fisher Shawn C
Schoonen Martin AA
Brownawell Bruce J
spellingShingle Fisher Shawn C
Schoonen Martin AA
Brownawell Bruce J
Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
Geochemical Transactions
author_facet Fisher Shawn C
Schoonen Martin AA
Brownawell Bruce J
author_sort Fisher Shawn C
title Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
title_short Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
title_full Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
title_fullStr Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
title_full_unstemmed Phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
title_sort phenylalanine as a hydroxyl radical-specific probe in pyrite slurries
publisher BMC
series Geochemical Transactions
issn 1467-4866
publishDate 2012-02-01
description <p>Abstract</p> <p>The abundant iron sulfide mineral pyrite has been shown to catalytically produce hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>) and hydroxyl radical (<b><sup>.</sup></b>OH) in slurries of oxygenated water. Understanding the formation and fate of these reactive oxygen species is important to biological and ecological systems as exposure can lead to deleterious health effects, but also environmental engineering during the optimization of remediation approaches for possible treatment of contaminated waste streams. This study presents the use of the amino acid phenylalanine (Phe) to monitor the kinetics of pyrite-induced <b><sup>.</sup></b>OH formation through rates of hydroxylation forming three isomers of tyrosine (Tyr) - <it>ortho</it>-, <it>meta</it>-, and <it>para</it>-Tyr. Results indicate that about 50% of the Phe loss results in Tyr formation, and that these products further react with <b><sup>.</sup></b>OH at rates comparable to Phe. The overall loss of Phe appeared to be pseudo first-order in [Phe] as a function of time, but for the first time it is shown that initial rates were much less than first-order as a function of initial substrate concentration, [Phe]<sub>o</sub>. These results can be rationalized by considering that the effective concentration of <b><sup>.</sup></b>OH in solution is lower at a higher level of reactant and that an increasing fraction of <b><sup>.</sup></b>OH is consumed by Phe-degradation products as a function of time. A simplified first-order model was created to describe Phe loss in pyrite slurries which incorporates the [Phe]<sub>o</sub>, a first-order dependence on pyrite surface area, the assumption that all Phe degradation products compete equally for the limited supply of highly reactive <b><sup>.</sup></b>OH, and a flux that is related to the release of H<sub>2</sub>O<sub>2 </sub>from the pyrite surface (a result of the incomplete reduction of oxygen at the pyrite surface). An empirically derived rate constant, <b>K<sub>pyr</sub></b>, was introduced to describe a variable <b><sup>.</sup></b>OH-reactivity for different batches of pyrite. Both the simplified first-order kinetic model, and a more detailed numerical simulation, yielded results that compare well to the observed kinetic data describing the effects of variations in concentrations of both initial Phe and pyrite. This work supports the use of Phe as a useful probe to assess the formation of <b><sup>.</sup></b>OH in the presence of pyrite, and its possible utility for similar applications with other minerals.</p>
url http://www.geochemicaltransactions.com/content/13/1/3
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