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A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge
Author’s Accepted Manuscript A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge Rujira Tisarum, Jing–Hua Ren, Xiaoling Dong, Hao Chen, Jason T. Lessl, Lena Q. Ma www.elsevier.com/locate/talanta
PII: DOI: Reference:
S0039-9140(15)30198-3 http://dx.doi.org/10.1016/j.talanta.2015.07.073 TAL15838
To appear in: Talanta Received date: 14 April 2015 Revised date: 22 July 2015 Accepted date: 28 July 2015 Cite this article as: Rujira Tisarum, Jing–Hua Ren, Xiaoling Dong, Hao Chen, Jason T. Lessl and Lena Q. Ma, A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge, Talanta, http://dx.doi.org/10.1016/j.talanta.2015.07.073 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting galley proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge
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Rujira Tisaruma,b, Jing–Hua Rena, Xiaoling Dongb, Hao Chenb, Jason T. Lessla,b and Lena Q.
9
Maa,b*
10 11 12
a
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University, Jiangsu 210046, China
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b
State Key Lab of Pollution Control and Resource Reuse, School of the Environment, Nanjing
Soil and Water Science Department, University of Florida, Gainesville, FL 32611 USA
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________________________
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*
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Environment, Nanjing University, Jiangsu 210046, China; Tel./fax: +86 025 8969 0631,
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[email protected]
24
Corresponding author. State Key Lab of Pollution Control and Resource Reuse, School of the
1
25
Abstract
26
A selective separation method based on anion exchange cartridge was developed to determine
27
antimony (Sb) speciation in biological matrices by graphite furnace atomic absorption
28
spectrophotometry (GFAAS). The selectivity of the cartridge towards antimonite [SbIII] and
29
antimonate [SbV] reversed in the presence of deionized (DI) water and 2 mM citric acid. While
30
SbV was retained by the cartridge in DI water, SbIII was retained in citric acid media. At pH 6,
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SbIII and SbV formed SbIII- and SbV-citrate complexes, but the cartridge had higher affinity
32
towards the SbIII-citrate complex. Separation of SbIII was tested at various concentrations in fresh
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and spent growth media and plant tissues. Our results showed that cartridge-based Sb speciation
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was successful in plant tissues, which was confirmed by HPLC–ICP–MS. The cartridge retained
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SbIII and showed 92–104% SbV recovery from arsenic hyperaccumulator Pteris vittata roots
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treated with SbIII and SbV. The cartridge procedure is an effective alternative for Sb speciation,
37
offering low cost, reproducible results, and simple Sb analysis using GFAAS.
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Keywords: antimony; speciation; antimonite; antimonate; solid phase extraction
40 41
2
42 43
Introduction Antimony (Sb) is a toxic element and is commonly associated with sulfur minerals [1].
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Total Sb concentrations in the earth’s crust are 0.2–0.3 mg/kg whereas the background
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concentrations in surface soil are 0.02–7.01 mg/kg [2]. Sb has been used in batteries, car brake
46
linings and in fire retardants and it is released to the environment at 38,000 tons per year from
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both natural and anthropogenic sources [3]. A steady increase of Sb levels in snow and ice in the
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Arctic and in the aerosol samples from Tokyo indicate that Sb contamination is a worldwide
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environmental problem [4].
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Sb is a possible carcinogen, with no known biological function [5]. It induces keratitis,
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dermatitis, conjunctivitis and gastritis and has been shown to cause lung cancer in rats [6]. In
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plants, Sb inhibits photosynthesis and decreases utilization of essential elements [7]. The toxicity
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of Sb largely depends on its chemical species, with inorganic species being more toxic than
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organic [8] and the reduced inorganic species SbIII being 10 times more toxic than the oxidized
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SbV species [6].
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The amount and type of Sb taken up by plants vary with species. For example, rye takes
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up more SbV than SbIII whereas wheat and rice take up more SbIII than SbV [9, 10]. Sb in plant
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tissues exists as both inorganic and organic forms, with inorganic Sb being the dominant species
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[11, 12]. Thus, information on Sb speciation is important to understand Sb behavior in the
60
environment as well as Sb translocation and transformation in plants.
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There are several analytical techniques to analyze total Sb, such as low cost equipment
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graphite furnace atomic absorption spectrophotometry (GFAAS) and high cost equipment
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inductively coupled plasma mass spectrometry (ICP–MS). In term of Sb speciation, the
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commonly used analytical method couples HPLC with ICP–MS [13]. Other Sb speciation 3
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methods focus on Sb separation based on the affinity of SbIII for sulfur group (–S). For example,
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pyrrolidine dithiocarbamate (PDC) containing –S group has been used for SbIII separation with
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non-polar organic solvents such as methyl isobuthyl ketone [14] or xylene [15]. However, this
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technique has the disadvantage of requiring manual injection of the organic media into the
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graphite furnace [15]. Using a column to separate SbIII–PDC complexes has been developed to
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overcome liquid–liquid extraction methods. Separating SbIII–PDC complexes requires a solid
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phase extraction (SPE) based on Chromosorb®self-packed resin column [16], which might cause
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inaccurate results. The non-polar SPE Isolute® silica-based octyl cartridge retains SbIII–PDC
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complex [17], but the cartridge is not globally available.
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In addition to PDC chelating agent, there are several SPE techniques for Sb speciation.
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For example, an ionic Amberlite® IRA 910 resin for adsorbing SbV[18], Dowex® 1x4 resin for
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retaining SbIII–Cl complex [19], and modified columns with dimercaptosuccinic acid or
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tetraethylenepentamine for retaining SbIII [20, 21]. However, those techniques have not been
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successful for Sb speciation as they are limited by graphite furnace analysis, procedure
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complication and commercial availability. For example, an ionic Amberlite® IRA 910 column
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requires self-packing and the Dowex® 1x4 column requires HCl elution, which is impractical for
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analysis by GFAAS. Furthermore, dimercaptosuccinic acid to chemically modifying mesoporous
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TiO2 micro-columns or tetraethylenepentamine to bind silica gel columns are not commercially
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available so they need be synthesized in a laboratory. The reproducibility of those results
84
remains uncertain.
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The pre-packed strong anion exchange cartridges proposed in this study have the ability
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to separate SbIII from SbV, which can be detected by GFAAS or ICP. The cartridges are
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reasonably priced and ready for immediate use. In addition, they are reproducible and 4
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commercially available worldwide. This work was the first application of SPE in separating Sb
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speciation in plant biomass and hydroponic nutrient media. It also sheds light on Sb speciation in
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plant tissues and media while offering an alternative method against expensive HPLC technique.
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The aim of this study was to investigate a silica-based anion exchange cartridge for SbIII
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and SbV separation under pH controlled conditions for Sb analysis by GFAAS. Furthermore, the
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results from Sb speciation in the roots of As hyperaccumulator Pteris vittata were confirmed by
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HPLC–ICP–MS.
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Material and methods
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All chemicals were of analytical reagent grade. Standard stock solutions of SbIII and SbV
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(1 g/L) were prepared by dissolving potassium antimonyltartrate (C8H4K2O12Sb2·3H2O, Fisher)
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and potassium hexahydroxyantimonate (KSb(OH)6, Sigma–Aldrich) in DI water and hot DI
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water, respectively. The SbIII and SbV stock solutions were stored in a refrigerator at 4ºC.
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Working solutions were freshly prepared daily by further dilution from these stock solutions to
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the ranges needed. A citric acid solution was prepared by dissolving monohydrate citric acid
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(HOC(COOH)(CH2COOH)2.H2O, J.T. Baker) in DI water. NaOH and HCl were used for pH
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adjustments. All labware used in this study was washed and soaked in 1 M nitric acid for 24 h
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and rinsed several times with tap water followed by DI water before use.
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Instrument for Sb Analysis and Speciation
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An AA240Z Zeeman atomic absorption spectrometer, equipped with a GTA 120 graphite
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furnace was used together with an Agilent Technology Sb hollow cathode lamp as the light
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source at 10 mA. The wavelength for Sb was 217.6 nm, with peak area mode being used. The
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linear range was 10150 μg/L with the slit at 0.2 nm. Partition-coated graphite tubes (Agilent
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Technologies) along with a programmable sample dispenser and background corrector were used. 5
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An ultra-high purity Argon gas was used as the purge gas. A 10 μL of sample and 5 μL of 500
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mg/L palladium nitrate modifier solution containing 0.25% citric acid in 2.5% nitric acid were
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introduced with an auto-sampler. The graphite furnace temperature program for Sb
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determination was given in Table 1.
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In addition to GFAAS, HPLC–ICP–MS was used to verify the accuracy of the cartridge-
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based method in 2 mM citric acid system. A Hamilton PRP–X100 AEC column (250x4.1 mm,
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10 µM; Hamilton, UK) with a guard column combined with a Waters 2695 HPLC system to
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separate Sb species. The mobile phase consisted of 20 mM EDTA–(NH4)2 and 2 mM potassium
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hydrogen phthalate adjusted to pH 4.5 with ammonium hydroxide. The sample was sonicated
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and filtered (0.22 µm), with 50 µL being injected with a flow rate at 1.2 mL/min at 40°C. A
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Nexion 300X inductively coupled plasma–mass spectrometry (ICP–MS) (Perkin–Elmer, USA)
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was connected to HPLC to analyze Sb concentration. SbV and SbIII standard solutions at 10 µg/L
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were run to obtain retention time. Stock solutions of Sb species were prepared from
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C8H4K2O12Sb2·3H2O (Sigma–Aldrich, >99%) and KSb(OH)6 (Fluka, >99%) with DI water. The
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stock solution at 1 g/L was stored in the dark at 3°C until use. All standard solutions were diluted
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from stock solution with 2 mM citric acid on the day of analysis. SbIII and SbV standard solutions
127
were calibrated on ICP–MS using a 100 mg/L multi-element environmental calibration standard
128
(PerkinElmer, in 5% HNO3). The detection limit of the instrument was 0.2 and 0.4 μg/L for SbIII
129
and SbV, respectively.
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Optimization of Cartridge-Based Sb Separation
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SPE is an extraction method common in liquid chromatography where solid and liquid
132
phases are interacted to separate chemical compounds of interest [22]. The sorbents for SPE
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refer to the stationary phase used in the columns [22]. Anion exchange column such as 6
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Hamiltion PRP–X100 and Synchropak Q300 have been used for Sb speciation by HPLC [3, 23].
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However, the affinity of Sb species towards the solid phase depends on SbIII complex [3]. SbIII-
136
citrate complex has a higher affinity towards the solid phase than SbV-citrate complex whereas
137
without citrate complexing agent, the affinity of SbV is greater than SbIII [3].
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The Sep-Pak AccellPlus QMA Plus Short cartridges used in this study was obtained from
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Waters (WAT020545, Milford, MA). The cartridge contains a silica-based, hydrophilic, strong
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anion exchanger with pore size of 300 Å, and sorbent particle size of 37–55 µm. The silica
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backbone in the cartridge contains quaternary ammonium group as anion-charged site and Cl as
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anion exchanger. Anionic compounds from the sample were exchanged to Cl .
143
–
–
To test the efficiency of the cartridge in SbV retention, 45 mL of SbIII or SbV solution was
144
passed through the cartridge at a flow rate of 10 mL/min. SbIII or SbV solution at 200 µg/L was
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prepared in DI water at pH 4, 6, or 8. The filtrate from the cartridge was collected for Sb analysis
146
by GFAAS. The sample without cartridge filtration was used for total Sb concentration. The
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SbIII or SbV concentrations were calculated from a difference between total Sb and Sb passed
148
through the cartridge.
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To ensure better separation of SbV from SbIII, the discarded filtrate volume was
150
determined by applying 250 mL of 200 µg/L SbIII + SbV mixture containing 0, 25, 50, 75 and
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100% SbIII. Sb speciation was determined every 50 mL aliquots of the filtrate. The results
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indicated that 200 mL of filtrate needed to be discarded before collecting filtrate for effective
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retention of SbV by the cartridge.
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To reduce the discarded volume, cartridges were preconditioned by passing a certain
155
volume of Sb solution. 15 mL of solutions containing 1 mg/L of SbIII or SbV was used to
156
precondition the cartridge, with SbV solution showing a better result (data not shown). The 7
157
conditioning was determined by applying 15 mL of 1 mg/L SbV to the cartridge and analyzing the
158
discarded solution in 10 mL intervals after the first 50 mL of solution was discarded.
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Preconditioning of the cartridge using SbV solution reduced the discarded filtrate volume from
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200 to ~100 mL.
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Discarding ~100 mL of filtrate was still too much so citric acid was used to condition the
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cartridge. Citric acid reacts with both SbIII and SbV to form anionic complexes [23]. The
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cartridge with citric acid media retained SbIII-citrate complex. SbV [Sb(OH)6 ] is present as
164
[Sb(OH)3(C6O7H5)]– whereas SbIII [Sb2(C4O6H2)2]2 is present as [Sb(C6O7H6)2]– in citric acid
165
solution [23]. An anion exchange cartridge adsorbs Sb from the samples according to Eq. 1:
–
–
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RCl + [Sb(C6O7H6)2] R–Sb(C6O7H6)2 + Cl
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Where RCl stands for anion exchange cartridge saturated with Cl . This negatively-
168 169
Eq. 1 –
–
–
charged [Sb(C6O7H6)2] complex replaces Cl on the cartridge. Solution of 200 µg/L SbIII + SbV mixture containing 0, 25, 50, 75 and 100% SbIII in 2 mM
170
citric acid at pH 4, 6, and 8 was used to condition the cartridge. Using a cartridge that had
171
already been preconditioned with 15 mL of 1 mg/L SbV to reduce SbV + SbIII anion exchange
172
sites, 70 mL of the SbIII + SbV solution was passed through the cartridge. To determine optimal
173
pH, sample in every 10 mL aliquot was collected for Sb speciation. Using the optimal pH,
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different SbIII proportions of 200 µg/L SbIII + SbV mixture in 2 mM citric acid were applied to the
175
column. To determine discarded volume, every 15 mL of filtrate was collected and analyzed for
176
Sb speciation.
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Sb Speciation in Plant Tissues and Spent Growth Media
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Since the As-hyperaccumulator P. vittata was efficient in Sb accumulation in the roots, it was used to test the efficiency of Sb speciation using the cartridge [24]. P. vittata was 8
180
propagated from spores in our laboratory. Uniform plants with 3–4 fronds were selected and
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acclimatized hydroponically in 0.2X Hoagland solution (HS) with constant aeration under cool
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and warm fluorescent lamps (the total light intensity~200 micromoles per m2) with temperature
183
of 23–28ºC and ~70% humidity for 4 weeks. After 4 weeks of acclimatization, P. vittata were
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transferred to 0.5 mM CaCl2 (pH 6) for 24 h to desorb surface nutrients from the roots. Then P.
185
vittata was divided into 3 treatments: control (DI water), 8 mg/L SbIII, and 8 mg/L SbV, all
186
adjusted to pH 6. After 24 h, P. vittata roots were washed to desorb apoplastic Sb in an ice-cold
187
solution containing 1 mM Na2HPO4 and 0.5 mM Ca(NO3)2, pH 6 for 10 min. The plant tissues
188
were used for Sb extraction and speciation.
189
Plant tissues were extracted using a modified method by Okkenhaug et al. [25] with Sb
190
extraction efficiency of 70–92% in plants [24]. Briefly, plants were harvested and washed
191
thoroughly in DI water. They were separated into the roots and fronds, which were freeze-dried
192
for 2 d. Dry tissues were ground with liquid nitrogen to fine powder in a ceramic mortar and
193
freeze-dried for an additional 2 d. Powdered tissue samples (~50 mg) were shaken at 100 rpm
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with 10 mL of 100 mM citric acid for 4 h and then sonicated at 42 kHz for 1 h (VWR DHT
195
Ultrasonic Cleaner B3500A). The 10 mL extracts containing 100 mM citric acid were diluted 5
196
times to 50 mL with DI water and filtered (45 m filter) before separation of Sb species. The
197
samples were further diluted 10 times with DI water. At this stage, the initial citric acid
198
concentration of 100 mM in the extracts was diluted down to 2 mM and the pH of the extracts
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adjusted to 6.0 by use of NaOH and/or HCl.
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In addition to plant biomass, we also tested Sb speciation in spent growth media. Spent
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media were obtained after growing P. vittata in 0.2X HS for 8 d. To reduce interference from
202
other ions, the 0.2X HS was diluted 40 times with DI water to 0.005X HS. The diluted HS at 9
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0.005X contained 14 µg/L H3BO3, 17µg/L MnSO4.H2O, 0.5µg/L CuSO4.5H2O, 1.1 µg/L
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ZnSO4.7H2O, 0.5 µg/L (NH4)6MO7O24.4H2O, 44.5 nM H2SO4, 168 µg/L Na2EDTA, 139.5 µg/L
205
FeSO4, 4.7 mg/L Ca(NO3)2.4H2O, 2.6 mg/L MgSO4.7H2O, 3.3 mg/L KNO3 and 0.6 mg/L
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NH4H2PO4 [26].
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Cartridge-based Sb speciation in plant roots and growth media were tested. The extracted
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plant samples and growth media were first passed through the cartridge, which were
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preconditioned with SbV, and then determined for Sb by GFAAS. To verify the accuracy of the
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cartridge method, the extractions from P. vittata roots treated with 8 mg/L SbIII or SbV for 24 h
211
were also analyzed for Sb speciation using HPLC–ICP–MS.
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Results and discussion
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SbV Retention on Cartridge in DI Water
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The silica-based, hydrophilic, anion-exchange cartridge retains anionic SbIII or SbV
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species via exchange with Cl , with non-negatively charged ions being passing through the
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cartridge. However, the cartridge had a higher affinity to SbV as SbV was retained on the
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cartridge instead of SbIII (Figure 1).
–
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To assess impact of solution pH and discarded filtrate volumes (filtrate volume required
219
to condition the cartridge for Sb separation), solutions containing 100 µg/L SbIII or SbV at pH 4,
220
6, or 8 were applied to the cartridge and Sb retained on the cartridge was determined (Figure 1).
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The pH of SbIII or SbV solutions had little impact on Sb retention on the cartridge. As expected,
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SbV was rapidly retained on the cartridge whereas SbIII gradually released after 10 mL of filtrate
223
volume. The results showed that the cartridge had an ability to separate SbV from SbIII. Further
224
experiments on discarded filtrate volume were studied at pH 6.
10
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Under pH 6, the cartridge required to discard 200 mL filtrate to achieve good SbV and
226
SbIII separation (Figure 2A). The amount of SbV retained on the cartridge after passing through
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250 mL solution equaled 50 µg SbV. Thus the cartridge had an ability to retain at least 50 µg SbV
228
and after discarding the first 200 mL of filtrate, the cartridge effectively retained SbV while
229
passing SbIII (Figure 2A).
230
The 200 mL discard volume was too much, thus effort was to reduce the discarded filtrate
231
volume. Based on our data, preconditioning the cartridge with 15 mL of 1 mg/L SbV, it reduced
232
the discarded volume from 200 to 110 mL (Figure 2B).
233
SbIII Retention on Cartridge under Citric Acid
234
Due to its high Sb stability and strong negative charge complex, 2 mM citric acid was
235
used to condition the sample to better separate SbV from SbIII. Citric acid forms a complex with
236
either SbIII or SbV. In presence of citric acid, the SbIII-tartrate complex from potassium
237
antimonyltartrate is replaced by the SbIII-citrate complex ([Sb(C6O7H6)2] ) and SbV(Sb(OH) 6) is
238
transformed to [Sb(OH)3(C6O7H5)] ) [23]. Both forms of SbIII- and SbV-citrate complexes are
239
negatively charged and SbIII-citrate has a higher affinity to the cartridge, which allows it to be
240
retained on the cartridge. Citric acid was not only used for separation of SbIII from SbV, but it
241
also helped to stabilize SbIII in the solution [23].
–
–
–
242
Solutions containing different concentrations of SbIII and SbV at pH 4, 6 and 8 were
243
passed through the cartridge and analyzed for Sb. The pH impacted the Sb retention on the
244
cartridge in both SbIII and SbV solutions (Table 2). At pH 4 and 6, the cartridge retained 96 and
245
99% SbIII and 3 and 1% SbV whereas at pH 8, it retained 1% of either SbIII or SbV. The data
246
indicated that the cartridge accurately separated SbIII from SbV at pH 4 and 6 from the mixtures of
247
SbV and SbIII. 11
248
At pH 6, the best SbIII retention (~99%) was achieved while allowing ~99% SbV to pass
249
through the cartridge. We then determined the minimum discarded filtrate volume for accurate
250
results (Figure 2C). Sample mixtures of SbIII + SbV in 2 mM citric acid at pH 6 were passed
251
through cartridges preconditioned using SbV. Samples with >50% SbIII in the mixture showed
252
~99% retention of SbIII after discarding 45 mL of filtrate. On the other hand, with SbIII at 0 and
253
25%, 60 mL of filtrate needed to be discarded to achieve optimal retention. So 60 mL of filtrate
254
was discarded for Sb speciation in 2 mM citric acid (pH 6) using cartridges preconditioned with
255
15 mL of 1 mg/L SbV.
256
Sb Speciation in Plant Biomass and Growth Media
257
Cartridge-based Sb speciation was applied to plant biomass (P. vittata roots) and growth
258
media, including spent 0.005X HS media after growing P. vittata for 8 d and 0.005X HS spiked
259
with Sb (Table 3). SbIII was 100% retained by the cartridge, but its retention dropped slightly (4–
260
12%) in the presence of SbV in P. vittata roots (Table 3). The HS samples were spiked with
261
different concentrations of SbIII and SbV containing 2 mM citric acid at pH 6. The cartridge was
262
preconditioned with 15 mL 1 mg/L SbV and the first 60 mL of filtrate was discarded. The spent
263
HS growth media contained different nutrients and organic acids from root exudates [27],
264
however, they did not impact SbIII retention on the cartridge. Accurate recovery of SbIII from Sb
265
mixtures confirmed the ability of cartridge on Sb speciation (Table 3). For example, the cartridge
266
retained 2–3% Sb from solution containing 0% SbIII (100% SbV), 22–27% from solution
267
containing 25% SbIII, 47–50% from solution containing 50% SbIII, and 72–76% from solution
268
containing 75% SbIII (Table 3). Without SbV, the cartridge showed 100% SbIII retention from all
269
samples (Table 3).
12
270
To verify the ability of SbIII retention by the cartridge in 2 mM citric acid, Sb extraction
271
of P. vittata roots treated with 8 mg/L SbIII or SbV for 24 h were used. Using the optimized
272
parameters, the cartridge showed effective retention of SbIII in P. vittata roots extracts with 92
273
and 104% SbV recovery from SbIII and SbV treatments, respectively (Table 4). The same samples
274
were also analyzed using HPLC–ICP–MS. Sb speciation from HPLC–ICP–MS verified that no
275
SbIII from P. vittata root extractions passed through the cartridge as there was no detection of
276
SbIII (Table 4). Our data showed that cartridge-based Sb speciation can be used to separate SbIII
277
from SbV in P. vittata roots or plant growth medium.
278
Conclusions
279
This study showed the first application of a solid phase extraction using an anion
280
exchange resin for Sb speciation in plant biomass and hydroponic growth media. The
281
concentration of SbV was determined by GFAAS after retention of SbIII by the cartridge. The
282
separation of SbIII from SbV in the presence of citric acid was conducted at pH 6 with SbV-
283
preconditioned cartridges after discarding the first 60 mL of filtrate. Retention of SbIII on the
284
cartridge under citric acid condition was confirmed by HPLC–ICP–MS, with 100% SbIII
285
retention and 92–104% SbV recovery from P. vittata roots treated with SbIII and SbV. The
286
method described here is simple and efficient because of the availability of the cartridge used and
287
the avoidance of manual injection to a GFAAS and potential variations of self-pack resin
288
columns.
289
Acknowledgements
290 291
This research was supported in part by the National Natural Science Foundation of China (No. 21277070), UF/IFAS and the Royal Thai Government.
292 13
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[10] I. Shtangeeva, E. Steinnes, S. Lierhagen, Uptake of different forms of antimony by wheat and rye seedlings, Environ. Sci. Pollut. Res., 19 (2012) 502-509.
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[11] P.J. Craig, S.N. Forster, R.O. Jenkins, D. Miller, An analytical method for the detection of methylantimony species in environmental matrices: methylantimony levels in some UK plant material, Analyst, 124 (1999) 1243-1248.
322 323 324
[12] K. Müller, B. Daus, J. Mattusch, H.-J. Stärk, R. Wennrich, Simultaneous determination of inorganic and organic antimony species by using anion exchange phases for HPLC–ICPMS and their application to plant extracts of Pteris vittata, Talanta, 78 (2009) 820-826.
325 326
[13] H.R. Hansen, S.A. Pergantis, Analytical techniques and methods used for antimony speciation analysis in biological matrices, J. Anal. At. Spectrom., 23 (2008) 1328-1340. 14
327 328 329 330
[14] A.M. García, M.C.P. Rodríguez, J.E.S. Uria, A. Sanz-Medel, Sb(III) and Sb(V) separation and analytical speciation by a continuous tandem on-line separation device in connection with inductively coupled plasma atomic emission spectrometry, Fresen. J. Anal. Chem., 353 (1995) 128-132.
331 332 333
[15] J.M. Serafimovska, S. Arpadjan, T. Stafilov, Speciation of dissolved inorganic antimony in natural waters using liquid phase semi-microextraction combined with electrothermal atomic absorption spectrometry, Microchem. J., 99 (2011) 46-50.
334 335
[16] S. Saracoglu, M. Soylak, M. Dogan, L. Elci, Speciation of antimony using Chromosorb 102 resin as a retention medium, Anal. Sci., 19 (2003) 259-264.
336 337 338
[17] C. Yu, Q. Cai, Z.-X. Guo, Z. Yang, S.B. Khoo, Antimony speciation by inductively coupled plasma mass spectrometry using solid phase extraction cartridges, Analyst, 127 (2002) 1380-1385.
339 340 341
[18] F. Sánchez Rojas, C. Bosch Ojeda, J.M. Cano Pavón, An ion-exchange method for speciation of antimony by flow injection electrothermal atomic absorption spectrometry, Talanta, 71 (2007) 918-922.
342 343 344
[19] L. Łukaszczyk, W. Żyrnicki, Speciation analysis of Sb(III) and Sb(V) in antileishmaniotic drug using Dowex 1×4 resin from hydrochloric acid solution, J. Pharm. Biomed. Anal., 52 (2010) 747-751.
345 346 347 348
[20] C. Huang, B. Hu, Z. Jiang, Simultaneous speciation of inorganic arsenic and antimony in natural waters by dimercaptosuccinic acid modified mesoporous titanium dioxide microcolumn on-line separation and inductively coupled plasma optical emission spectrometry determination, Spectrochim. Acta B, 62 (2007) 454-460.
349 350 351
[21] D. Mendil, H. Bardak, M. Tuzen, M. Soylak, Selective speciation of inorganic antimony on tetraethylenepentamine bonded silica gel column and its determination by graphite furnace atomic absorption spectrometry, Talanta, 107 (2013) 162-166.
352 353
[22] A. Żwir-Ferenc, M. Biziuk, Solid Phase Extraction Technique – Trends, Opportunities and Applications, Pol. J. Environ. Stud., 15 (2006) 677-690.
354 355 356
[23] J. Zheng, A. Iijima, N. Furuta, Complexation effect of antimony compounds with citric acid and its application to the speciation of antimony(III) and antimony(V) using HPLCICP-MS, J. Anal. At. Spectrom., 16 (2001) 812-818.
357 358 359
[24] R. Tisarum, J.T. Lessl, X. Dong, L.M. de Oliveira, B. Rathinasabapathi, L.Q. Ma, Antimony uptake, efflux and speciation in arsenic hyperaccumulator Pteris vittata, Environ. Pollut., 186 (2014) 110-114.
360 361 362 363
[25] G. Okkenhaug, Y.-G. Zhu, J. He, X. Li, L. Luo, J. Mulder, Antimony (Sb) and arsenic (As) in Sb mining impacted paddy soil from Xikuangshan, China: differences in mechanisms controlling soil sequestration and uptake in rice, Environ. Sci. Technol., 46 (2012) 31553162. 15
364 365
[26] A.O. Fayiga, L.Q. Ma, B. Rathinasabapathi, Effects of nutrients on arsenic accumulation by arsenic hyperaccumulator Pteris vittata L., Environ. Exp. Bot., 62 (2008) 231-237.
366 367 368 369
[27] S. Tu, L. Ma, T. Luongo, Root exudates and arsenic accumulation in arsenic hyperaccumulating Pteris vittata and non-hyperaccumulating Nephrolepis exaltata, Plant Soil, 258 (2004) 9-19.
16
370 371 372
Figure Captions
373
Values are the mean of three replicates+ standard error.
374
Figure 2. Percentage of Sb retained on the cartridge in DI water at pH 6 after discarding 200 mL
375
of filtrates (A) and after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding
376
110 mL of filtrates (B), and percentage of Sb retained on the cartridge in 2 mM citric acid at pH 6
377
after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding 60 mL of filtrates
378
(C). Values are the mean of three replicates+standard error.
Figure 1. Percentage of SbIII and SbV retained on the cartridge in DI water at different pH.
379 380 381
17
382
Table 1. Graphite furnace temperature program for Sb determination. Step
Temperature (ºC)
Time (s)
Gas flow rate (mL/min)
1
85
5.0
300
2
95
40.0
300
3
120
10.0
300
4
700
5.0
300
5
700
1.0
300
6
700
2.0
0.0
7
2,000
0.7
0.0
8
2,000
2.0
0.0
9
2,000
2.0
300
383 384 385 386 387 388 389 390 391 392
18
393
Table 2. Sb retained on the cartridge after being preconditioned with 15 mL of 1 mg/L SbV in 2
394
mM citric acid at different pH and after discarding 70 mL of filtratea. Sb concentration(µg/L)
395
a
Sb expectedon cartridge (%)
Sb retained on cartridge (%)
SbIII 200
SbV 0
100
pH 4 96 ± 0.5
pH 6 99 ± 0.4
pH 8 1.0±1.7
150
50
75
74 ± 0.1
74 ± 0.1
41 ± 0.5
100
100
50
48 ± 1.4
50 ±0.5
27 ± 1.2
50
150
25
27 ± 1.0
23 ±0.9
11 ±0.7
0
200
0
3.0 ± 0.4
0.6± 0.2
1.0± 1.8
Values are the mean of three replicates + standard error.
396 397
19
398
Table 3. Sb retained on the cartridge from growth media (0.005X HS fresh and spent media) and
399
P. vittata roots after the cartridge being preconditioned with 15 mL of 1 mg/L SbV in 2 mM citric
400
acid and after discarding 60 mL of filtratea. Sb concentrations (µg/L) SbIII SbV
401 402
Sb expected on cartridge (%)
fresh HS media
100 200 0 100 ± 0.0 75 150 50 76 ± 0.6 50 100 100 50 ± 0.4 25 50 150 27 ± 1.7 0 0 200 3.0 ± 1.5 a Values are the mean of three replicates + standard error. b
Sb retained (%) spent HS media
P. vittata roots
100 ± 0.0 75 ± 0.2 47 ± 2.3 24 ± 2.2 2.0 ± 2.4
100 ± 0.0 72 ± 0.6 48 ± 1.0 22 ± 0.3 2.0 ± 2.1
HS = Hoagland solution.
403
20
404
Table 4. Sb speciation in P. vittata roots extraction after exposure to 8 mg/L SbIII or SbV for 24 h
405
by HPLC–ICP–MS before and after passing through the cartridge a. Treatment
406 407 408
Sb concentration (mg/kg) SbIII SbV
SbV recovery from the cartridge (%)
Control –Before 0.5 ± 0.1 µg/kg 0.2 ± 0.0 µg/kg b –After nd 0.2 ± 0.0 µg/kg III Sb –Before 289 ± 87.6 456 ± 43.2 a –After nd 421 ± 43.0 a 92 ± 2 V Sb –Before 1.4 ± 0.4 45.6 ± 3.6 b –After nd 47.6 ± 7.1 b 104 ± 5 a Values are the mean of three replicates+standard error, and columns with the same letters are not significantly different. b
nd =not detected (<0.2 μg/L SbIII).
409 410
21
III
Sb pH 4 III
Sb pH 6
411 412
Figure 1. Percentage of SbIII and SbV retained on the cartridge in DI water at different pH.
413
Values are the mean of three replicates+ standard error.
414
22
III
V
III
V
III
V
Sb :Sb =200:0 Sb :Sb =150:50 Sb :Sb =100:100 III
V
III
V
Sb :Sb =50:150 Sb :Sb =0:200
415
416
417 418
Figure 2. Percentage of Sb retained on the cartridge in DI water at pH 6 after discarding 200 mL
419
of filtrates (A) and after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding
420
110 mL of filtrates (B), and percentage of Sb retained on the cartridge in 2 mM citric acid at pH 6
421
after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding 60 mL of filtrates
422
(C). Values are the mean of three replicates+standard error. 23
423
SPE cartridge selectively retained SbV in DI water and SbIII in citric acid
424
425 426 427
Highlights
428
A SEP cartridge method was developed for antimony speciation in biological matrices.
429
While SbV was retained by cartridge in DI water, SbIII was retained in citric acid.
430
92-104% SbV recovery for As-hyperaccumulator P. vittata roots containing SbIII & SbV
431
The SEP cartridge procedure is effective and reproducible for Sb speciation.
432 433
24
PII: DOI: Reference:
S0039-9140(15)30198-3 http://dx.doi.org/10.1016/j.talanta.2015.07.073 TAL15838
To appear in: Talanta Received date: 14 April 2015 Revised date: 22 July 2015 Accepted date: 28 July 2015 Cite this article as: Rujira Tisarum, Jing–Hua Ren, Xiaoling Dong, Hao Chen, Jason T. Lessl and Lena Q. Ma, A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge, Talanta, http://dx.doi.org/10.1016/j.talanta.2015.07.073 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting galley proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
1 2 3 4
A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge
5 6 7 8
Rujira Tisaruma,b, Jing–Hua Rena, Xiaoling Dongb, Hao Chenb, Jason T. Lessla,b and Lena Q.
9
Maa,b*
10 11 12
a
13
University, Jiangsu 210046, China
14
b
State Key Lab of Pollution Control and Resource Reuse, School of the Environment, Nanjing
Soil and Water Science Department, University of Florida, Gainesville, FL 32611 USA
15 16 17 18 19 20
________________________
21
*
22
Environment, Nanjing University, Jiangsu 210046, China; Tel./fax: +86 025 8969 0631,
23
[email protected]
24
Corresponding author. State Key Lab of Pollution Control and Resource Reuse, School of the
1
25
Abstract
26
A selective separation method based on anion exchange cartridge was developed to determine
27
antimony (Sb) speciation in biological matrices by graphite furnace atomic absorption
28
spectrophotometry (GFAAS). The selectivity of the cartridge towards antimonite [SbIII] and
29
antimonate [SbV] reversed in the presence of deionized (DI) water and 2 mM citric acid. While
30
SbV was retained by the cartridge in DI water, SbIII was retained in citric acid media. At pH 6,
31
SbIII and SbV formed SbIII- and SbV-citrate complexes, but the cartridge had higher affinity
32
towards the SbIII-citrate complex. Separation of SbIII was tested at various concentrations in fresh
33
and spent growth media and plant tissues. Our results showed that cartridge-based Sb speciation
34
was successful in plant tissues, which was confirmed by HPLC–ICP–MS. The cartridge retained
35
SbIII and showed 92–104% SbV recovery from arsenic hyperaccumulator Pteris vittata roots
36
treated with SbIII and SbV. The cartridge procedure is an effective alternative for Sb speciation,
37
offering low cost, reproducible results, and simple Sb analysis using GFAAS.
38 39
Keywords: antimony; speciation; antimonite; antimonate; solid phase extraction
40 41
2
42 43
Introduction Antimony (Sb) is a toxic element and is commonly associated with sulfur minerals [1].
44
Total Sb concentrations in the earth’s crust are 0.2–0.3 mg/kg whereas the background
45
concentrations in surface soil are 0.02–7.01 mg/kg [2]. Sb has been used in batteries, car brake
46
linings and in fire retardants and it is released to the environment at 38,000 tons per year from
47
both natural and anthropogenic sources [3]. A steady increase of Sb levels in snow and ice in the
48
Arctic and in the aerosol samples from Tokyo indicate that Sb contamination is a worldwide
49
environmental problem [4].
50
Sb is a possible carcinogen, with no known biological function [5]. It induces keratitis,
51
dermatitis, conjunctivitis and gastritis and has been shown to cause lung cancer in rats [6]. In
52
plants, Sb inhibits photosynthesis and decreases utilization of essential elements [7]. The toxicity
53
of Sb largely depends on its chemical species, with inorganic species being more toxic than
54
organic [8] and the reduced inorganic species SbIII being 10 times more toxic than the oxidized
55
SbV species [6].
56
The amount and type of Sb taken up by plants vary with species. For example, rye takes
57
up more SbV than SbIII whereas wheat and rice take up more SbIII than SbV [9, 10]. Sb in plant
58
tissues exists as both inorganic and organic forms, with inorganic Sb being the dominant species
59
[11, 12]. Thus, information on Sb speciation is important to understand Sb behavior in the
60
environment as well as Sb translocation and transformation in plants.
61
There are several analytical techniques to analyze total Sb, such as low cost equipment
62
graphite furnace atomic absorption spectrophotometry (GFAAS) and high cost equipment
63
inductively coupled plasma mass spectrometry (ICP–MS). In term of Sb speciation, the
64
commonly used analytical method couples HPLC with ICP–MS [13]. Other Sb speciation 3
65
methods focus on Sb separation based on the affinity of SbIII for sulfur group (–S). For example,
66
pyrrolidine dithiocarbamate (PDC) containing –S group has been used for SbIII separation with
67
non-polar organic solvents such as methyl isobuthyl ketone [14] or xylene [15]. However, this
68
technique has the disadvantage of requiring manual injection of the organic media into the
69
graphite furnace [15]. Using a column to separate SbIII–PDC complexes has been developed to
70
overcome liquid–liquid extraction methods. Separating SbIII–PDC complexes requires a solid
71
phase extraction (SPE) based on Chromosorb®self-packed resin column [16], which might cause
72
inaccurate results. The non-polar SPE Isolute® silica-based octyl cartridge retains SbIII–PDC
73
complex [17], but the cartridge is not globally available.
74
In addition to PDC chelating agent, there are several SPE techniques for Sb speciation.
75
For example, an ionic Amberlite® IRA 910 resin for adsorbing SbV[18], Dowex® 1x4 resin for
76
retaining SbIII–Cl complex [19], and modified columns with dimercaptosuccinic acid or
77
tetraethylenepentamine for retaining SbIII [20, 21]. However, those techniques have not been
78
successful for Sb speciation as they are limited by graphite furnace analysis, procedure
79
complication and commercial availability. For example, an ionic Amberlite® IRA 910 column
80
requires self-packing and the Dowex® 1x4 column requires HCl elution, which is impractical for
81
analysis by GFAAS. Furthermore, dimercaptosuccinic acid to chemically modifying mesoporous
82
TiO2 micro-columns or tetraethylenepentamine to bind silica gel columns are not commercially
83
available so they need be synthesized in a laboratory. The reproducibility of those results
84
remains uncertain.
85
The pre-packed strong anion exchange cartridges proposed in this study have the ability
86
to separate SbIII from SbV, which can be detected by GFAAS or ICP. The cartridges are
87
reasonably priced and ready for immediate use. In addition, they are reproducible and 4
88
commercially available worldwide. This work was the first application of SPE in separating Sb
89
speciation in plant biomass and hydroponic nutrient media. It also sheds light on Sb speciation in
90
plant tissues and media while offering an alternative method against expensive HPLC technique.
91
The aim of this study was to investigate a silica-based anion exchange cartridge for SbIII
92
and SbV separation under pH controlled conditions for Sb analysis by GFAAS. Furthermore, the
93
results from Sb speciation in the roots of As hyperaccumulator Pteris vittata were confirmed by
94
HPLC–ICP–MS.
95
Material and methods
96
All chemicals were of analytical reagent grade. Standard stock solutions of SbIII and SbV
97
(1 g/L) were prepared by dissolving potassium antimonyltartrate (C8H4K2O12Sb2·3H2O, Fisher)
98
and potassium hexahydroxyantimonate (KSb(OH)6, Sigma–Aldrich) in DI water and hot DI
99
water, respectively. The SbIII and SbV stock solutions were stored in a refrigerator at 4ºC.
100
Working solutions were freshly prepared daily by further dilution from these stock solutions to
101
the ranges needed. A citric acid solution was prepared by dissolving monohydrate citric acid
102
(HOC(COOH)(CH2COOH)2.H2O, J.T. Baker) in DI water. NaOH and HCl were used for pH
103
adjustments. All labware used in this study was washed and soaked in 1 M nitric acid for 24 h
104
and rinsed several times with tap water followed by DI water before use.
105
Instrument for Sb Analysis and Speciation
106
An AA240Z Zeeman atomic absorption spectrometer, equipped with a GTA 120 graphite
107
furnace was used together with an Agilent Technology Sb hollow cathode lamp as the light
108
source at 10 mA. The wavelength for Sb was 217.6 nm, with peak area mode being used. The
109
linear range was 10150 μg/L with the slit at 0.2 nm. Partition-coated graphite tubes (Agilent
110
Technologies) along with a programmable sample dispenser and background corrector were used. 5
111
An ultra-high purity Argon gas was used as the purge gas. A 10 μL of sample and 5 μL of 500
112
mg/L palladium nitrate modifier solution containing 0.25% citric acid in 2.5% nitric acid were
113
introduced with an auto-sampler. The graphite furnace temperature program for Sb
114
determination was given in Table 1.
115
In addition to GFAAS, HPLC–ICP–MS was used to verify the accuracy of the cartridge-
116
based method in 2 mM citric acid system. A Hamilton PRP–X100 AEC column (250x4.1 mm,
117
10 µM; Hamilton, UK) with a guard column combined with a Waters 2695 HPLC system to
118
separate Sb species. The mobile phase consisted of 20 mM EDTA–(NH4)2 and 2 mM potassium
119
hydrogen phthalate adjusted to pH 4.5 with ammonium hydroxide. The sample was sonicated
120
and filtered (0.22 µm), with 50 µL being injected with a flow rate at 1.2 mL/min at 40°C. A
121
Nexion 300X inductively coupled plasma–mass spectrometry (ICP–MS) (Perkin–Elmer, USA)
122
was connected to HPLC to analyze Sb concentration. SbV and SbIII standard solutions at 10 µg/L
123
were run to obtain retention time. Stock solutions of Sb species were prepared from
124
C8H4K2O12Sb2·3H2O (Sigma–Aldrich, >99%) and KSb(OH)6 (Fluka, >99%) with DI water. The
125
stock solution at 1 g/L was stored in the dark at 3°C until use. All standard solutions were diluted
126
from stock solution with 2 mM citric acid on the day of analysis. SbIII and SbV standard solutions
127
were calibrated on ICP–MS using a 100 mg/L multi-element environmental calibration standard
128
(PerkinElmer, in 5% HNO3). The detection limit of the instrument was 0.2 and 0.4 μg/L for SbIII
129
and SbV, respectively.
130
Optimization of Cartridge-Based Sb Separation
131
SPE is an extraction method common in liquid chromatography where solid and liquid
132
phases are interacted to separate chemical compounds of interest [22]. The sorbents for SPE
133
refer to the stationary phase used in the columns [22]. Anion exchange column such as 6
134
Hamiltion PRP–X100 and Synchropak Q300 have been used for Sb speciation by HPLC [3, 23].
135
However, the affinity of Sb species towards the solid phase depends on SbIII complex [3]. SbIII-
136
citrate complex has a higher affinity towards the solid phase than SbV-citrate complex whereas
137
without citrate complexing agent, the affinity of SbV is greater than SbIII [3].
138
The Sep-Pak AccellPlus QMA Plus Short cartridges used in this study was obtained from
139
Waters (WAT020545, Milford, MA). The cartridge contains a silica-based, hydrophilic, strong
140
anion exchanger with pore size of 300 Å, and sorbent particle size of 37–55 µm. The silica
141
backbone in the cartridge contains quaternary ammonium group as anion-charged site and Cl as
142
anion exchanger. Anionic compounds from the sample were exchanged to Cl .
143
–
–
To test the efficiency of the cartridge in SbV retention, 45 mL of SbIII or SbV solution was
144
passed through the cartridge at a flow rate of 10 mL/min. SbIII or SbV solution at 200 µg/L was
145
prepared in DI water at pH 4, 6, or 8. The filtrate from the cartridge was collected for Sb analysis
146
by GFAAS. The sample without cartridge filtration was used for total Sb concentration. The
147
SbIII or SbV concentrations were calculated from a difference between total Sb and Sb passed
148
through the cartridge.
149
To ensure better separation of SbV from SbIII, the discarded filtrate volume was
150
determined by applying 250 mL of 200 µg/L SbIII + SbV mixture containing 0, 25, 50, 75 and
151
100% SbIII. Sb speciation was determined every 50 mL aliquots of the filtrate. The results
152
indicated that 200 mL of filtrate needed to be discarded before collecting filtrate for effective
153
retention of SbV by the cartridge.
154
To reduce the discarded volume, cartridges were preconditioned by passing a certain
155
volume of Sb solution. 15 mL of solutions containing 1 mg/L of SbIII or SbV was used to
156
precondition the cartridge, with SbV solution showing a better result (data not shown). The 7
157
conditioning was determined by applying 15 mL of 1 mg/L SbV to the cartridge and analyzing the
158
discarded solution in 10 mL intervals after the first 50 mL of solution was discarded.
159
Preconditioning of the cartridge using SbV solution reduced the discarded filtrate volume from
160
200 to ~100 mL.
161
Discarding ~100 mL of filtrate was still too much so citric acid was used to condition the
162
cartridge. Citric acid reacts with both SbIII and SbV to form anionic complexes [23]. The
163
cartridge with citric acid media retained SbIII-citrate complex. SbV [Sb(OH)6 ] is present as
164
[Sb(OH)3(C6O7H5)]– whereas SbIII [Sb2(C4O6H2)2]2 is present as [Sb(C6O7H6)2]– in citric acid
165
solution [23]. An anion exchange cartridge adsorbs Sb from the samples according to Eq. 1:
–
–
166
RCl + [Sb(C6O7H6)2] R–Sb(C6O7H6)2 + Cl
167
Where RCl stands for anion exchange cartridge saturated with Cl . This negatively-
168 169
Eq. 1 –
–
–
charged [Sb(C6O7H6)2] complex replaces Cl on the cartridge. Solution of 200 µg/L SbIII + SbV mixture containing 0, 25, 50, 75 and 100% SbIII in 2 mM
170
citric acid at pH 4, 6, and 8 was used to condition the cartridge. Using a cartridge that had
171
already been preconditioned with 15 mL of 1 mg/L SbV to reduce SbV + SbIII anion exchange
172
sites, 70 mL of the SbIII + SbV solution was passed through the cartridge. To determine optimal
173
pH, sample in every 10 mL aliquot was collected for Sb speciation. Using the optimal pH,
174
different SbIII proportions of 200 µg/L SbIII + SbV mixture in 2 mM citric acid were applied to the
175
column. To determine discarded volume, every 15 mL of filtrate was collected and analyzed for
176
Sb speciation.
177
Sb Speciation in Plant Tissues and Spent Growth Media
178 179
Since the As-hyperaccumulator P. vittata was efficient in Sb accumulation in the roots, it was used to test the efficiency of Sb speciation using the cartridge [24]. P. vittata was 8
180
propagated from spores in our laboratory. Uniform plants with 3–4 fronds were selected and
181
acclimatized hydroponically in 0.2X Hoagland solution (HS) with constant aeration under cool
182
and warm fluorescent lamps (the total light intensity~200 micromoles per m2) with temperature
183
of 23–28ºC and ~70% humidity for 4 weeks. After 4 weeks of acclimatization, P. vittata were
184
transferred to 0.5 mM CaCl2 (pH 6) for 24 h to desorb surface nutrients from the roots. Then P.
185
vittata was divided into 3 treatments: control (DI water), 8 mg/L SbIII, and 8 mg/L SbV, all
186
adjusted to pH 6. After 24 h, P. vittata roots were washed to desorb apoplastic Sb in an ice-cold
187
solution containing 1 mM Na2HPO4 and 0.5 mM Ca(NO3)2, pH 6 for 10 min. The plant tissues
188
were used for Sb extraction and speciation.
189
Plant tissues were extracted using a modified method by Okkenhaug et al. [25] with Sb
190
extraction efficiency of 70–92% in plants [24]. Briefly, plants were harvested and washed
191
thoroughly in DI water. They were separated into the roots and fronds, which were freeze-dried
192
for 2 d. Dry tissues were ground with liquid nitrogen to fine powder in a ceramic mortar and
193
freeze-dried for an additional 2 d. Powdered tissue samples (~50 mg) were shaken at 100 rpm
194
with 10 mL of 100 mM citric acid for 4 h and then sonicated at 42 kHz for 1 h (VWR DHT
195
Ultrasonic Cleaner B3500A). The 10 mL extracts containing 100 mM citric acid were diluted 5
196
times to 50 mL with DI water and filtered (45 m filter) before separation of Sb species. The
197
samples were further diluted 10 times with DI water. At this stage, the initial citric acid
198
concentration of 100 mM in the extracts was diluted down to 2 mM and the pH of the extracts
199
adjusted to 6.0 by use of NaOH and/or HCl.
200
In addition to plant biomass, we also tested Sb speciation in spent growth media. Spent
201
media were obtained after growing P. vittata in 0.2X HS for 8 d. To reduce interference from
202
other ions, the 0.2X HS was diluted 40 times with DI water to 0.005X HS. The diluted HS at 9
203
0.005X contained 14 µg/L H3BO3, 17µg/L MnSO4.H2O, 0.5µg/L CuSO4.5H2O, 1.1 µg/L
204
ZnSO4.7H2O, 0.5 µg/L (NH4)6MO7O24.4H2O, 44.5 nM H2SO4, 168 µg/L Na2EDTA, 139.5 µg/L
205
FeSO4, 4.7 mg/L Ca(NO3)2.4H2O, 2.6 mg/L MgSO4.7H2O, 3.3 mg/L KNO3 and 0.6 mg/L
206
NH4H2PO4 [26].
207
Cartridge-based Sb speciation in plant roots and growth media were tested. The extracted
208
plant samples and growth media were first passed through the cartridge, which were
209
preconditioned with SbV, and then determined for Sb by GFAAS. To verify the accuracy of the
210
cartridge method, the extractions from P. vittata roots treated with 8 mg/L SbIII or SbV for 24 h
211
were also analyzed for Sb speciation using HPLC–ICP–MS.
212
Results and discussion
213
SbV Retention on Cartridge in DI Water
214
The silica-based, hydrophilic, anion-exchange cartridge retains anionic SbIII or SbV
215
species via exchange with Cl , with non-negatively charged ions being passing through the
216
cartridge. However, the cartridge had a higher affinity to SbV as SbV was retained on the
217
cartridge instead of SbIII (Figure 1).
–
218
To assess impact of solution pH and discarded filtrate volumes (filtrate volume required
219
to condition the cartridge for Sb separation), solutions containing 100 µg/L SbIII or SbV at pH 4,
220
6, or 8 were applied to the cartridge and Sb retained on the cartridge was determined (Figure 1).
221
The pH of SbIII or SbV solutions had little impact on Sb retention on the cartridge. As expected,
222
SbV was rapidly retained on the cartridge whereas SbIII gradually released after 10 mL of filtrate
223
volume. The results showed that the cartridge had an ability to separate SbV from SbIII. Further
224
experiments on discarded filtrate volume were studied at pH 6.
10
225
Under pH 6, the cartridge required to discard 200 mL filtrate to achieve good SbV and
226
SbIII separation (Figure 2A). The amount of SbV retained on the cartridge after passing through
227
250 mL solution equaled 50 µg SbV. Thus the cartridge had an ability to retain at least 50 µg SbV
228
and after discarding the first 200 mL of filtrate, the cartridge effectively retained SbV while
229
passing SbIII (Figure 2A).
230
The 200 mL discard volume was too much, thus effort was to reduce the discarded filtrate
231
volume. Based on our data, preconditioning the cartridge with 15 mL of 1 mg/L SbV, it reduced
232
the discarded volume from 200 to 110 mL (Figure 2B).
233
SbIII Retention on Cartridge under Citric Acid
234
Due to its high Sb stability and strong negative charge complex, 2 mM citric acid was
235
used to condition the sample to better separate SbV from SbIII. Citric acid forms a complex with
236
either SbIII or SbV. In presence of citric acid, the SbIII-tartrate complex from potassium
237
antimonyltartrate is replaced by the SbIII-citrate complex ([Sb(C6O7H6)2] ) and SbV(Sb(OH) 6) is
238
transformed to [Sb(OH)3(C6O7H5)] ) [23]. Both forms of SbIII- and SbV-citrate complexes are
239
negatively charged and SbIII-citrate has a higher affinity to the cartridge, which allows it to be
240
retained on the cartridge. Citric acid was not only used for separation of SbIII from SbV, but it
241
also helped to stabilize SbIII in the solution [23].
–
–
–
242
Solutions containing different concentrations of SbIII and SbV at pH 4, 6 and 8 were
243
passed through the cartridge and analyzed for Sb. The pH impacted the Sb retention on the
244
cartridge in both SbIII and SbV solutions (Table 2). At pH 4 and 6, the cartridge retained 96 and
245
99% SbIII and 3 and 1% SbV whereas at pH 8, it retained 1% of either SbIII or SbV. The data
246
indicated that the cartridge accurately separated SbIII from SbV at pH 4 and 6 from the mixtures of
247
SbV and SbIII. 11
248
At pH 6, the best SbIII retention (~99%) was achieved while allowing ~99% SbV to pass
249
through the cartridge. We then determined the minimum discarded filtrate volume for accurate
250
results (Figure 2C). Sample mixtures of SbIII + SbV in 2 mM citric acid at pH 6 were passed
251
through cartridges preconditioned using SbV. Samples with >50% SbIII in the mixture showed
252
~99% retention of SbIII after discarding 45 mL of filtrate. On the other hand, with SbIII at 0 and
253
25%, 60 mL of filtrate needed to be discarded to achieve optimal retention. So 60 mL of filtrate
254
was discarded for Sb speciation in 2 mM citric acid (pH 6) using cartridges preconditioned with
255
15 mL of 1 mg/L SbV.
256
Sb Speciation in Plant Biomass and Growth Media
257
Cartridge-based Sb speciation was applied to plant biomass (P. vittata roots) and growth
258
media, including spent 0.005X HS media after growing P. vittata for 8 d and 0.005X HS spiked
259
with Sb (Table 3). SbIII was 100% retained by the cartridge, but its retention dropped slightly (4–
260
12%) in the presence of SbV in P. vittata roots (Table 3). The HS samples were spiked with
261
different concentrations of SbIII and SbV containing 2 mM citric acid at pH 6. The cartridge was
262
preconditioned with 15 mL 1 mg/L SbV and the first 60 mL of filtrate was discarded. The spent
263
HS growth media contained different nutrients and organic acids from root exudates [27],
264
however, they did not impact SbIII retention on the cartridge. Accurate recovery of SbIII from Sb
265
mixtures confirmed the ability of cartridge on Sb speciation (Table 3). For example, the cartridge
266
retained 2–3% Sb from solution containing 0% SbIII (100% SbV), 22–27% from solution
267
containing 25% SbIII, 47–50% from solution containing 50% SbIII, and 72–76% from solution
268
containing 75% SbIII (Table 3). Without SbV, the cartridge showed 100% SbIII retention from all
269
samples (Table 3).
12
270
To verify the ability of SbIII retention by the cartridge in 2 mM citric acid, Sb extraction
271
of P. vittata roots treated with 8 mg/L SbIII or SbV for 24 h were used. Using the optimized
272
parameters, the cartridge showed effective retention of SbIII in P. vittata roots extracts with 92
273
and 104% SbV recovery from SbIII and SbV treatments, respectively (Table 4). The same samples
274
were also analyzed using HPLC–ICP–MS. Sb speciation from HPLC–ICP–MS verified that no
275
SbIII from P. vittata root extractions passed through the cartridge as there was no detection of
276
SbIII (Table 4). Our data showed that cartridge-based Sb speciation can be used to separate SbIII
277
from SbV in P. vittata roots or plant growth medium.
278
Conclusions
279
This study showed the first application of a solid phase extraction using an anion
280
exchange resin for Sb speciation in plant biomass and hydroponic growth media. The
281
concentration of SbV was determined by GFAAS after retention of SbIII by the cartridge. The
282
separation of SbIII from SbV in the presence of citric acid was conducted at pH 6 with SbV-
283
preconditioned cartridges after discarding the first 60 mL of filtrate. Retention of SbIII on the
284
cartridge under citric acid condition was confirmed by HPLC–ICP–MS, with 100% SbIII
285
retention and 92–104% SbV recovery from P. vittata roots treated with SbIII and SbV. The
286
method described here is simple and efficient because of the availability of the cartridge used and
287
the avoidance of manual injection to a GFAAS and potential variations of self-pack resin
288
columns.
289
Acknowledgements
290 291
This research was supported in part by the National Natural Science Foundation of China (No. 21277070), UF/IFAS and the Royal Thai Government.
292 13
293
References
294 295 296
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[4] M. Krachler, J. Zheng, R. Koerner, C. Zdanowicz, D. Fisher, W. Shotyk, Increasing atmospheric antimony contamination in the northern hemisphere: snow and ice evidence from Devon Island, Arctic Canada, J. Environ. Monit., 7 (2005) 1169-1176.
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325 326
[13] H.R. Hansen, S.A. Pergantis, Analytical techniques and methods used for antimony speciation analysis in biological matrices, J. Anal. At. Spectrom., 23 (2008) 1328-1340. 14
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[14] A.M. García, M.C.P. Rodríguez, J.E.S. Uria, A. Sanz-Medel, Sb(III) and Sb(V) separation and analytical speciation by a continuous tandem on-line separation device in connection with inductively coupled plasma atomic emission spectrometry, Fresen. J. Anal. Chem., 353 (1995) 128-132.
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[15] J.M. Serafimovska, S. Arpadjan, T. Stafilov, Speciation of dissolved inorganic antimony in natural waters using liquid phase semi-microextraction combined with electrothermal atomic absorption spectrometry, Microchem. J., 99 (2011) 46-50.
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[16] S. Saracoglu, M. Soylak, M. Dogan, L. Elci, Speciation of antimony using Chromosorb 102 resin as a retention medium, Anal. Sci., 19 (2003) 259-264.
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[17] C. Yu, Q. Cai, Z.-X. Guo, Z. Yang, S.B. Khoo, Antimony speciation by inductively coupled plasma mass spectrometry using solid phase extraction cartridges, Analyst, 127 (2002) 1380-1385.
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[18] F. Sánchez Rojas, C. Bosch Ojeda, J.M. Cano Pavón, An ion-exchange method for speciation of antimony by flow injection electrothermal atomic absorption spectrometry, Talanta, 71 (2007) 918-922.
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[23] J. Zheng, A. Iijima, N. Furuta, Complexation effect of antimony compounds with citric acid and its application to the speciation of antimony(III) and antimony(V) using HPLCICP-MS, J. Anal. At. Spectrom., 16 (2001) 812-818.
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360 361 362 363
[25] G. Okkenhaug, Y.-G. Zhu, J. He, X. Li, L. Luo, J. Mulder, Antimony (Sb) and arsenic (As) in Sb mining impacted paddy soil from Xikuangshan, China: differences in mechanisms controlling soil sequestration and uptake in rice, Environ. Sci. Technol., 46 (2012) 31553162. 15
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[26] A.O. Fayiga, L.Q. Ma, B. Rathinasabapathi, Effects of nutrients on arsenic accumulation by arsenic hyperaccumulator Pteris vittata L., Environ. Exp. Bot., 62 (2008) 231-237.
366 367 368 369
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16
370 371 372
Figure Captions
373
Values are the mean of three replicates+ standard error.
374
Figure 2. Percentage of Sb retained on the cartridge in DI water at pH 6 after discarding 200 mL
375
of filtrates (A) and after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding
376
110 mL of filtrates (B), and percentage of Sb retained on the cartridge in 2 mM citric acid at pH 6
377
after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding 60 mL of filtrates
378
(C). Values are the mean of three replicates+standard error.
Figure 1. Percentage of SbIII and SbV retained on the cartridge in DI water at different pH.
379 380 381
17
382
Table 1. Graphite furnace temperature program for Sb determination. Step
Temperature (ºC)
Time (s)
Gas flow rate (mL/min)
1
85
5.0
300
2
95
40.0
300
3
120
10.0
300
4
700
5.0
300
5
700
1.0
300
6
700
2.0
0.0
7
2,000
0.7
0.0
8
2,000
2.0
0.0
9
2,000
2.0
300
383 384 385 386 387 388 389 390 391 392
18
393
Table 2. Sb retained on the cartridge after being preconditioned with 15 mL of 1 mg/L SbV in 2
394
mM citric acid at different pH and after discarding 70 mL of filtratea. Sb concentration(µg/L)
395
a
Sb expectedon cartridge (%)
Sb retained on cartridge (%)
SbIII 200
SbV 0
100
pH 4 96 ± 0.5
pH 6 99 ± 0.4
pH 8 1.0±1.7
150
50
75
74 ± 0.1
74 ± 0.1
41 ± 0.5
100
100
50
48 ± 1.4
50 ±0.5
27 ± 1.2
50
150
25
27 ± 1.0
23 ±0.9
11 ±0.7
0
200
0
3.0 ± 0.4
0.6± 0.2
1.0± 1.8
Values are the mean of three replicates + standard error.
396 397
19
398
Table 3. Sb retained on the cartridge from growth media (0.005X HS fresh and spent media) and
399
P. vittata roots after the cartridge being preconditioned with 15 mL of 1 mg/L SbV in 2 mM citric
400
acid and after discarding 60 mL of filtratea. Sb concentrations (µg/L) SbIII SbV
401 402
Sb expected on cartridge (%)
fresh HS media
100 200 0 100 ± 0.0 75 150 50 76 ± 0.6 50 100 100 50 ± 0.4 25 50 150 27 ± 1.7 0 0 200 3.0 ± 1.5 a Values are the mean of three replicates + standard error. b
Sb retained (%) spent HS media
P. vittata roots
100 ± 0.0 75 ± 0.2 47 ± 2.3 24 ± 2.2 2.0 ± 2.4
100 ± 0.0 72 ± 0.6 48 ± 1.0 22 ± 0.3 2.0 ± 2.1
HS = Hoagland solution.
403
20
404
Table 4. Sb speciation in P. vittata roots extraction after exposure to 8 mg/L SbIII or SbV for 24 h
405
by HPLC–ICP–MS before and after passing through the cartridge a. Treatment
406 407 408
Sb concentration (mg/kg) SbIII SbV
SbV recovery from the cartridge (%)
Control –Before 0.5 ± 0.1 µg/kg 0.2 ± 0.0 µg/kg b –After nd 0.2 ± 0.0 µg/kg III Sb –Before 289 ± 87.6 456 ± 43.2 a –After nd 421 ± 43.0 a 92 ± 2 V Sb –Before 1.4 ± 0.4 45.6 ± 3.6 b –After nd 47.6 ± 7.1 b 104 ± 5 a Values are the mean of three replicates+standard error, and columns with the same letters are not significantly different. b
nd =not detected (<0.2 μg/L SbIII).
409 410
21
III
Sb pH 4 III
Sb pH 6
411 412
Figure 1. Percentage of SbIII and SbV retained on the cartridge in DI water at different pH.
413
Values are the mean of three replicates+ standard error.
414
22
III
V
III
V
III
V
Sb :Sb =200:0 Sb :Sb =150:50 Sb :Sb =100:100 III
V
III
V
Sb :Sb =50:150 Sb :Sb =0:200
415
416
417 418
Figure 2. Percentage of Sb retained on the cartridge in DI water at pH 6 after discarding 200 mL
419
of filtrates (A) and after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding
420
110 mL of filtrates (B), and percentage of Sb retained on the cartridge in 2 mM citric acid at pH 6
421
after cartridge being preconditioned with 15 mL of 1 mg/L SbV and discarding 60 mL of filtrates
422
(C). Values are the mean of three replicates+standard error. 23
423
SPE cartridge selectively retained SbV in DI water and SbIII in citric acid
424
425 426 427
Highlights
428
A SEP cartridge method was developed for antimony speciation in biological matrices.
429
While SbV was retained by cartridge in DI water, SbIII was retained in citric acid.
430
92-104% SbV recovery for As-hyperaccumulator P. vittata roots containing SbIII & SbV
431
The SEP cartridge procedure is effective and reproducible for Sb speciation.
432 433
24