New methodologies have been developed for the determination of arsenic and selenium species in a
variety of environmentally important matrices. A simple liquid chromatographic separation technique
based upon mini-column technology was developed to obtain a simultaneous, fast, efficient and
reliable separation of relatively toxic from relatively non-toxic arsenic and selenium species. The
relatively toxic arsenic and selenium species studied were inorganic Asv, AsIII,
SeVI and SeIV. The
relatively non-toxic species of arsenic and selenium studied were AsBet, DMA and Se Met. Optimum
conditions were found to be the use of a Hamilton PRP X100 12-20 µm anion-exchange resin with
column dimensions of 100 x 3 mm. The mobile phase utilized a 10 mM K2S04 solution at pH 10.2
with a flow rate of 1 ml minˉ¹ and a sample injection loop of 100 µ1. Total analysis time was under 7
minutes with limits of detection in the range of 2.0 - 10 µg kgˉ¹ for arsenic and selenium species,
respectively.
Work was undertaken, using HPLC-ICP-MS instrumentation, as part of a feasibility study, into the
production and certification of six new reference materials; these being analyzed for the species of
arsenic, in chicken, fish, rice and soil samples, and selenium, in wheat and yeast samples. Enzyme
extraction techniques were used throughout, except for soil where a microwave H3P04 extraction was
used. Efficiencies were in the range 90-100%. The results obtained provided speciation information as
well as total elemental concentrations with no operationally defined limits.
Speciation analysis requires that the endogenous species are extracted without modification of their
chemical form or disturbance to the equilibrium existing between the various species present. Work
was undertaken to identify and quantify the selenium species present in two samples of novel,
previously unstudied, bio-natured nutrients, these nutrients being: i) a selenized yeast from a new
process and: ii) a probiotic bacteria-based dried milk sample (Biogurt®). Specific interest was
directed towards enzyme, MeOH and KOH and TMAH extraction efficiencies together with retention
of species information. Selenium speciation was performed using ion-exchange HPLC-ICP-MS. It
was found that the selenium content, in the form of SeMet, was adequately extracted from the yeast
(Pharma Nord) that was used for method validation using protease, which yielding 90% of the total
selenium. However, the determination of selenium and selenium species in the bionatured nutrients
proved to be quite problematic. Methods that avoided species conversion with the highest extraction
efficiencies were found to be: i) the use of protease for the yeast sample (19%) and; ii) the use of 0.01
M HCl for the Biogurt® (71%). Information obtained from speciation of these samples by anion and
cation-exchange HPLC-ICP-MS was limited due to the low extraction efficiencies of any procedure
undertaken for the samples, by the retention of the analyte on-column and by the lack of standards
available for matching of retention times.
HPLC-ICP-MS has proved an efficient tool for the identification and determination of arsenic and
selenium species providing detection limits at µg kgˉ¹ levels. However, a major concern with this
instrumentation is the unambiguous assignment of peaks which relies on the chromatographic purity
of the signal and the availability of standards. Anion-exchange chromatography employing Hamilton
PRP X100 resin with NH4HC03 (10 mM, pH 10.2 for arsenic and 10-50 mM, pH 5 for selenium
species) with methanol (10 %, v/v) as the mobile phase allowed separation of the arsenic and
selenium species investigated under conditions that were compatible for both HPLC-ICP-MS and
HPLC-ESMS. Molecular ions and structural fragmentation patterns of these by tandem MS have
facilitated the identification of chromatographic peaks obtained using HPLC-ICP-MS. In the analysis
of marine algae, arsenosugars were the major species found, and in yeast the dominant species was
found to be selenomethionine.
Date of Award | 2003 |
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Original language | English |
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Awarding Institution | |
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Speciation Analysis of Arsenic and Selenium by HPLC and Mass Spectrometry
Fitzpatrick, S. (Author). 2003
Student thesis: PhD