Authors:
Şerife Saçmacı*
Affiliation(s):
Department of Chemistry, Erciyes University, Faculty of Sciences, TR-38039, Kayseri, TURKEY
Dates:
Received: 18 July, 2017; Accepted: 30 August 2017; Published: 31 August, 2017
*Corresponding author:
Şerife Saçmacı, Erciyes University, Department of Chemistry, Faculty of Sciences, TR-38039, Kayseri, TURKEY, Tel: +90 352 4374937; fax: +90 352 4374933, E-mail: @;
Citation:
Saçmacı Ş (2017) Coprecipitation procedure for speciation of chromium in some dairy food product and water samples by FAAS. Int J Agric Sc Food Technol 3(3): 055-060. DOI: 10.17352/2455-815X.000023
Copyright:
© 2017 Saçmacı Ş. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Keywords:
Coprecipitation, trace element, α-Benzoin oxime, FAAS, food samples
Article options
Abstract

A new method based on the coprecipitation procedure (CP) for separation/speciation using flame atomic absorption spectrometric (FAAS) determination was proposed for the determination of Cr(III)/Cr(VI) in some real samples with Co(II)/α-Benzoin oxime precipitate. It enabled a very selective, basic and rapid method for chromium determination to be developed. The analytical variables including pH, amount of α-Benzoin oxime, amount of Co(II) as carrier element, and sample volume were investigated for the quantitative recoveries Cr(III)/Cr(VI). No interfering effects were observed from the concomitant ions when present in real samples. Cr(III) was quantitatively recovered on Co(II)/α-Benzoin oxime precipitate at a pH range of 7–10, while Cr(VI) was not quantitatively recovered for any of the pHs. The calibration graph was linear in the range of 1.0–10.0 mg L-1. Under the optimized conditions, detection limits of 0.01 µg L-1 and the relative standard deviations of 1.1% were found. The preconcentration factor was found to be 1000. The precipitate was dissolved in 0.1 mL of concentrated HNO3, and made up to 1.0 mL with deionized ultra pure water. The validation of the presented CP was checked by the analysis of certified reference materials. The method was applied for the determination of Cr(III)/Cr(VI) in real samples such as natural waters and some dairy food samples, and good results were obtained (relative standard deviations <2%, recoveries >95%).

Main article text

Introduction

Increasing industrialization and human activities have caused the emission of various pollutants into the air, soil, sediments, water and biota [1]. As a consequence of environmental pollution and the use of various fertilizers, pesticides and herbicides, contaminants may enter the food chain resulting in elevated concentrations of toxic elements and organic substances in food stuffs [2]. Once it enters the environment, its toxicity is determined to a large extent by its chemical form and species transformation [3]. Dietary factors can also influence trace element reference values in the tissues of humans [4]. Growing concern about the quality of food has initiated numerous investigations on the presence of essential and toxic trace elements in different foodstuffs [5,6]. In food analysis, extended analytical efforts have been undertaken to obtain reliable results for trace element determinations.

It is well known that the toxicological and biological properties of most elements depend on their chemical forms. Information about the oxidation state of trace elements is as important to know as its chemical structure. It has been reported that the same metal ion may possess different levels of toxicity in its various oxidation states, which are responsible for their different physico-chemical and biological activities [7]. Speciation analysis of toxic heavy metals has special importance due to its impact on environmental chemistry, ecotoxicology, clinical toxicology and food industry.

Chromium is one of the most abundant elements on earth and it is mainly present in Cr(0), Cr(III) and Cr(VI) oxidation states, which have different toxicities, motilities and bio-availabilities. Metallic chromium is mainly found in alloys, such as stainless steel, but also in chrome-plated objects. Cr(III) which exists in natural waters in hydrolyzed Cr(H2O)4OH2+ form and complexes, and is even adsorbed on colloidal matter. It is an essential micronutrient in the body and combines with various enzymes to transform sugar, protein and fat. Cr(III) is also used in a number of commercial products, including dyes, paint pigments and salts for leather tanning. Cr(VI) is found as CrO42-, HCrO4- or Cr2O72- depending on the pH of the medium. It is known to be carcinogenic and mutagenic and it induces dermatitis. It occurs in a range of compounds used in industrial processes, such as chrome plating [8-11].

Chromium is an analyte of interest to the above industries and in the environment because, like other metals, it is not biodegradable. Once it enters the environment, its toxicity is determined to a large extent by its chemical form (e.g., Cr(VI) which is much more toxic than Cr(III)) [12]. The World Health Organization (WHO) recommends a guideline value of 0.05 mg L−1 for Cr in drinking water [13].

Sensitive and accurate determination of metals at trace level is one of the important aims of analytical chemistry [14]. The quantification of trace metals in food samples has routinely been conducted by inductively coupled plasma optical emission spectrometry (ICP-OES) [15], inductively coupled plasma mass spectrometry (ICP-MS) [16], and flame atomic absorption spectrometry (FAAS) [17-20]. In many cases, the analytical instrumentation available does not present the sensitivity requirements necessary to analyze chromium in food samples. Thus, several procedures have been developed for the separation and preconcentration of chromium, including liquid–liquid extraction [9], solid phase extraction [10], coprecipitation [21], and X-ray fluorescence [22].

The coprecipitation method is useful for the preconcentration of trace metal ions and is one of the most useful ways for the preconcentration/separation of trace elements from a sample matrix, and variety of coprecipitants have been studied [23-26]. This preconcentration purpose is characterized by the formation of insoluble compounds.

In the present work, we proposed a method which can be used for the determination of Cr(III) and also for the preconcentration and speciation of Cr(III/VI) species. The Co(II)-α Benzoin oxime system was proposed as a new procedure for the efficient and selective determination of Cr(III). The results presented herein summarize the most important features of the Cr(III) determination and stripping efficiencies for the CPs, as well as the selectivity of the α Benzoin oxime for Cr(III) when it appears in the presence of other metals in the aqueous phases. The Cr(III) was quantitatively separated from Cr(VI) and preconcentrated. Cr(VI) concentrations were obtained as the respective differences between total chromium and Cr(III).

To our knowledge, flame atomic absorption spectrometry (FAAS) together with the Co(II)/α-Benzoin oxime system has not been used for the determination of Cr(III). The developed method was tested for the determination of chromium in some water samples and dairy food samples. The method can also be employed for the separation and speciation of chromium species in various natural waters.

Experimental

Instrumentation and materials

A PerkinElmer model AAnalyst 800 flame atomic absorption spectrometer (Norwalk, CT, USA) equipped with a deuterium background correction system and an air-acetylene burner was used for the determination of Cr(III) in the aqueous phase after the CP procedure. The wavelength used was 357.9 nm. A spectral bandwidth of 0.7 nm, acetylene flow rate of 1.4 L min−1, and nebulizer flow rate of 10.0 mL min−1 were the conventional working parameters. A pH meter with a glass and calomel electrode pair (Nel pH 900), a magnetic stirrer (Chiltern) and an MLTW–54 model centrifuge (www.coleparmer.com) were used for centrifugation purposes.

Experimental animals
Reagents and standard solutions

All the reagents used were of the highest available purity and at least of analytical reagent grade (Merck, Darmstadt, Germany). Deionized ultra pure water was used for the preparation of the solutions. Cr(III) and Cr(VI) stock solutions (1000 mg L−1) were prepared from Cr(NO3)3·9H2O and K2CrO4 [10]. From these solutions, dilute working solutions were prepared on a daily basis. The calibration curve was established using the standard solutions prepared in 1 mol L−1 HNO3 by dilution of the stock solutions. A 0.1% (w/v) solution of α-Benzoin oxime was prepared by dissolving 0.1 g of the reagent in 100 mL of methanol. The glassware used was cleaned by soaking overnight in dilute HNO3 (1:5) and then rinsed with deionized water several times.

The reduction of Cr(VI) to Cr(III) was an carried out using hydroxylamine hydrochloride as the reducing agent. The following buffer solutions were used for the presented preconcentration procedure: HCl/KCl buffer for pH 1.0–2.0; CH3COONa/CH3COOH buffer for pH 3.0–5.0; CH3COONH4/CH3COOH buffer for pH 6.0–7.0 and NH3/NH4Cl buffer for pH 8.0-10.0.

Preparation of food samples

A 0.5-g amount of the standard reference material (INCT-TL-1 tea leaves; http://www.ist-world.org) was dissolved with a mixture of 10 mL of concentrated HNO3 and 2 mL of concentrated H2O2 on a hot plate. After completing the dissolution process, all the sample solutions were clear. The volume of the samples was diluted to approximately 25 mL using deionized water. The final measurement volume of the sample solutions was 1 mL.

The second certified reference material was an SPS-WW2 Batch 108 waste water (http://www.ist-world.org) sample. The pHs of 10-mL aliquots of the samples were adjusted to 8.0 with NH3/NH4Cl buffer solution. Then the Co(II)/α-Benzoin oxime CP given above was applied to these sample solutions.

First of all, 1.0-g aliquots from each of the food samples were treated with 10 mL of nitric acid and then heated until a clear solution was obtained. After this, the evaporation was continued almost to dryness, and 10 mL of nitric acid was again added to the moist residue. The mixture was evaporated to near dryness and then 2 mL of concentrated H2O2 was added to each food sample solution. After completing the dissolution process, the sample solution was filtered through a cellulose filter paper and then it was washed with 1–2 mL of 1 mol L−1 HNO3. The filtrate was diluted to 25 mL with deionized ultra pure water. These sample solutions were analyzed by using the procedure described above. The final measurement volume of the sample solutions was 1 mL. A blank digest was carried out in the same way.

The method was also applied to various water samples. First, the pHs of the water samples were adjusted to 8.0 with NH3/NH4Cl buffer solution and then the coprecipitation procedure was applied. The concentration of Cr(III) in the final measurement solution was determined by FAAS.

Recommended procedure

The CP method was tested with model solutions prior to its application to real samples. Twenty five milliliter portions of aqueous solutions containing 20 μg each of Cr(III) were placed into centrifuge tubes. The pH of the solutions was adjusted to 8.0 with NH3/NH4Cl buffer solution (1 mL). Then 0.25 mL of 1000 mg L−1 Co(II) as a carrier element and 0.1 mL of 0.1% (w/v) α-Benzoin oxime solution were added to the sample. After the formation of the precipitate, the sample solution was centrifuged at 3000 rpm for 10 min. The supernatant was removed. The precipitate which remained adhering to the bottom of the tube was dissolved with 0.1 mL of concentrated HNO3. Then the final volume was completed to 1 mL with deionized ultra pure water. The analytes in the final solution were determined by FAAS.

Results and Discussion

Effect of pH

Adjustment of the pH value was the first parameter considered on the speciation of Cr(III) and Cr(VI) with the Co(II)/α-Benzoin oxime complex using the CP. Different pH buffer solutions were added to the experimental solution in the range of 1–10 for this study and then the CP was applied. The effect of pH on the recoveries of Cr(III) and Cr(VI) ions are given in figure 1. The recoveries of Cr(III) were quantitative in the pH range of 7.0–10.0, while Cr(VI) was not quantitatively recovered for any of the pHs. Therefore, subsequent experiments were performed at pH 8.0.

  1. Figure 1:
    Effect of pH on the recoveries of Cr(III)/Cr(VI) ions (n = 3).
Effect of the amount of α-Benzoin oxime

The effects of the amount of α-Benzoin oxime on the recovery of Cr(III)/Cr(VI) ions on the CP system were also investigated at pH 8.0. Different amounts of α-Benzoin oxime were tested in the range of 0.0–400 µL of 0.1% (w/v) α-Benzoin oxime. Quantitative recovery was achieved in the range of 150–400 µL of coprecipitating reagent. The results are shown in figure 2. When the experiments were performed without α-Benzoin oxime at pH 8.0, the recovery values were not quantitative (≤ 15%) for studying the metal ions. These results show that α-Benzoin oxime reagent is necessary for the quantitative recoveries of Cr(III)/Cr(VI) ions. For all the subsequent works, 250 μL of 0.1% (w/v) α-Benzoin oxime solution was used.

  1. Figure 2:
    Effect of the amount of α-Benzoin oxime (n = 3).
Effect of the amount of cobalt(II) as carrier element

The effects of the amount of Co(II) as carrier element on the recoveries of Cr(III)/Cr(VI) ions were also investigated. The recoveries were not quantitative values without Co(II). The recoveries of Cr(III) were enhanced in the range of 0.1–1.0 mg of Co(II) for the formation of Co(II)/α-Benzoin oxime precipitate at pH 8.0. The results are shown in figure 3. In the light of these results, a 0.3 mg amount of Co(II) was selected as carrier in all subsequent works.

  1. Figure 3:
    Effect of the amount of the Co(II) on the recovery of Cr(III)/Cr(VI) ions (n = 3.)
Effects of duration time

The effects of duration time for the Co(II)/α-Benzoin oxime precipitate on the recoveries of Cr(III)/Cr(VI) were also studied in the time range of 5–30 min. Quantitative recoveries for Cr(III) were obtained after 5 min of duration time while Cr(VI) was not quantitatively recovered at any duration time. The further studies were performed at 5 min duration time.

Effect of the centrifugation rate and time

For this purpose, a series of experiments were conducted at different centrifugation rates varying from 1000 to 4000 rpm for 10 min at optimal conditions for Co(II)/α-Benzoin oxime precipitate. The recoveries sharply increased up to the centrifugation rate of 2500 rpm, and then remained almost constant. As the optimal centrifugation rate, 3000 rpm was selected (figure 4).

  1. Figure 4:
    Effect of centrifugation rate on the recoveries of Cr(III)/Cr(VI) ions (n = 3).

Another important parameter is the centrifugation time for the Co(II)/α-Benzoin oxime CP. In order to get the best centrifugation time, the experiments were performed in the range of 5–30 min under the optimized conditions. The results showed that the centrifugation time had a significant influence on the signals of the analytes. The best results were obtained after 10 min centrifugation time. The Cr(III) signals were nearly constant beyond the centrifugation time of 10 min, as can be seen from figure 5. The optimum centrifugation time for this process was chosen as 10 min.

  1. Figure 5:
    Effect of centrifugation time of on the recoveries of Cr(III)/Cr(VI) ions (n = 3).
Sample volume and preconcentration factor

The effect of sample volume is a very important parameter for the CP. The effect of sample volume on the recoveries of Cr(III) was examined in the range of 25–1000 mL by using model solutions prepared at the optimal conditions. The results of this study are shown in figure 6. The results show that the quantitative recoveries were obtained up to 1000 mL of sample volume for Cr(III) ions except for Cr(VI). The preconcentration factor was calculated by the ratio of the highest sample volume and the lowest final volume for Cr(III). Eventually, a preconcentration factor of 1000 can be achieved when the final volume was 1.0 mL.

  1. Figure 6:
    Effect of sample volume on the recoveries of Cr(III)/Cr(VI) ions (n = 3).
Determination of total chromium

In order to reduce Cr(VI) to Cr(III), various reducing reagents were studied. The pH of a 25 mL aliquot of the test solution including 20 µg of Cr(III) was brought to pH 1 with 2 mol L−1 H2SO4. Then, 10-mL of reducing reagent was added to this solution, and it was heated for 30 min on a hot plate. As reducing agent, 5% (w/v) Na2SO3, 5% (w/v) HONH2·HCl, 5% (w/v) KI and 5% (w/v) NaNO2 solutions and ethanol were tested and then the described procedure was applied. The obtained recovery values were ≤20%. The quantitative recoveries were obtained by another reducing procedure as follows: to 25 mL of the test solution were added 0.25 mL of 1 mol L−1 HNO3 and 1 mL of 1% (w/v) HONH2·HCl, respectively. The solution was allowed to stand at room temperature for 30 min [10]. After the reduction of Cr(VI) to Cr(III), the pH was adjusted to 8.0 with NH3/NH4Cl buffer for Co(II)/α-Benzoin oxime precipitate and the volume was made up to 25 mL with deionized water. These results show that the recoveries of total chromium were higher than 98%.

Effect of matrix ions

To detect potential interferences on the Co(II)/α-Benzoin oxime precipitate of Cr(III) (20 μg), various amounts of Na+, K+, Ca2+, Mg2+, Cl-, SO+2- and PO+3-, and also Fe(III), Cu(II), Zn(II) and Ni(II) ions at mg L-1 and/or higher levels may have interferic effects on the determinations of Cr(III) ions by flame atomic absorption spectrometry. The results are given in table 1. These results show that this Co(II)/α-Benzoin oxime procedure could be applied successfully for the speciation of Cr(III) and Cr(VI) at pH 8.0. These potentially interfering ions did not interfere under the experimental conditions used.

  1. avatar

    Table 1:

    Influences of some foreign ions on the recoveries of Cr(III) (pH 8.0, initial sample volume: 25 mL, final sample volume: 1 mL).

Analytical performance of the method

The analytical performances of the procedure for chromium species were calculated using the results obtained from FAAS measurements. The precision of the method was found to be 1.1% as the relative standard deviation by analyzing tap water samples (n = 8).The limit of detection (LOD) of the presented coprecipitation study was calculated as 0.01 μg L-1 under optimal experimental conditions (pH: 8.0, sample volume: 1000 mL, final volume: 1 mL) by applying the developed procedure and analyzing 20 blank solutions (3s). In the calculation of the LOD of the method, the 1000-fold preconcentration factor was taken into consideration.

The equation of the calibration curve obtained after applying the CP was A = 0.0452CCr + 0.0005, where A is the absorbance and CCr is the chromium(III) concentration. Linearity was observed over the range of 0.5–10 mg L−1 (r2 = 0.998).

Application of some real samples

The validation of the presented procedure was performed by the analysis of two certified reference materials (CRM), namely INCT-TL-1 tea leaves and SPS-WW2 Batch 108 waste water sample. The certified and observed values for certified reference materials are given in table 2. The results found were in good agreement with the certified values of CRMs. Our data showed excellent agreement with the certified values.

  1. avatar

    Table 2:

    The determination of chromium in the standard reference materials (n = 3).

The recovery studies for Cr(III) ions were performed for tap water, red mullet and green tea samples. Certain amounts of the analytes were spiked to the sample solutions in order to estimate the accuracy of the presented procedure. The results are given in table 3. Good agreement was obtained between the added and found analyte contents using the recommended procedure.

  1. avatar

    Table 3:

    The determination of Cr(III) in various samples after the application of the CP (n = 3).

The proposed method was also successfully applied for the determination of Cr(III) and total chromium in some food samples (Table 4) and water samples (tap water, mineral water, well water and waste water) (Table 5).

  1. avatar

    Table 4:

    The determination of Cr(III) in various samples after the application of the CP (n = 3).

  1. avatar

    Table 5:

    Speciation of Cr (III) and Cr (VI) and total chromium in some natural water samples (sample volume: 250 mL, n = 3, mg L−1).

Conclusions

The Co(II)/α-Benzoin oxime coprecipitative preconcentration procedure described above facilitates a selective enrichment of Cr(III) in the presence of Cr(VI) from very dilute solutions. The coprecipitation methods could be performed within about 30 min. The preconcentration factor was achieved as 1000. The achieved detection limits of the analytes are superior to some preconcentration/separation methods. The method was also free of interference compared to conventional procedures to determine the analyte metal ions. The presented coprecipitation method can be applied not only to water but also to food samples. Consequently, the procedures are fast, precise, reliable and economic.

References
  1. Milacˇicˇ R, LeskovÐek H, DolinÐek F, Hrcˇek D (1995) A complex study of air pollution with cadmium, lead and polycyclic aromatic      hydrocarbons, sulfur dioxide, and black smoke in the Zasvaje industrialized urban region in Slovenia. Ann Chim 85:131–148 Link: https://goo.gl/HUWCMM
  2. Fichet D, Boucher G, Radenac G, Miramand P (1999) Concentration and mobilisation of Cd, Cu, Pb, and Zn by meiofauna populations living in harbour sediment: their role in the  heavy metal flux from sediment to food web. Sci Total Environ 243-244: 267–272 Link: https://goo.gl/kKgytD
  3. Shun-Xing Li, Feng-Ying Zheng, Hua-Sheng Hong, Nan-sheng Deng, Lu-Xiu Lin (2009) Influence of marine phytoplankton, transition metals and sunlight on the species distribution of chromium in surface seawater. Marine Environmental Research  67: 199-206 Link: https://goo.gl/WyY77N
  4. Minoia C, Sabbioni E, Ronchi A, Gatti A, Pietra R, et al (1994) Trace element reference values in tissues from inhabitants of the European Community. IV. Influence of dietary factors. Sci Total Environ 141: 181–195 Link: https://goo.gl/ZsNJoF
  5. Coni E, Caroli S, Ianni D, Bocca A (1994) A methodological approach to the assessment of trace elements in milk and dairy products. Food Chem 50: 203–201 Link: https://goo.gl/5KgU1p
  6. Cabrera C, Lorenzo ML, De Mena C, Lopez MC (1996) Chromium, copper, iron, manganese, selenium and zinc levels in dairy products: in vitro study of absorbable fractions. Int J Food Sci Nutr 47: 331–339 Link: https://goo.gl/epG4MA
  7. M. Stoeppler (1992) Hazardous Metals in the Environment, Techniques and Instrumentation in Analytical Chemistry. 84: 177-230 Link: https://goo.gl/NtDvjp
  8. V. Go´mez, M.P. Callao (2006) Chromium determination and speciation since 2000. Trends in Analytical Chemistry 25: 1006-1015 Link: https://goo.gl/ndHo2E
  9. Sacmaci S, Kartal Ş (2011) Speciation, separation and enrichment of Cr(III) and Cr(VI) inenvironmental samples by ion-pair solvent extraction using a β-diketone ligand, Intern. J Environ Anal Chem  91: 448–461 Link: https://goo.gl/8Bk8qR
  10. Sacmaci S, Kartal Ş, Yılmaz Y, Sacmaci M, Soykan C (2012) A new chelating resin: Synthesis, characterization and application for speciation of chromium (III)/(VI) species. Chemical Engineering Journal 181– 182: 746– 753 Link: https://goo.gl/rghgty
  11. Serkan Ş, Sacmaci S, Kartal Ş, Saçmacı M, Şahin U, et al (2014) Development of a new on-line system for the sequential speciation and determination of chromium species in various samples using a combination of chelating and ion exchange resins. Talanta120: 391–397 Link: https://goo.gl/HoXnrP
  12. G.F. Nordberg, B.A. Fowler, M. Nordberg, L (2007) Friberg Handbook on the Toxicology of Metals, Academic Press, Burlington. Link: https://goo.gl/PNQN1r
  13. X Guan, D He, J Ma, G Chen (2010) Application of permanganate in the oxidation ofmicropollutants: a mini review, Front. Environ Sci Eng China 4: 405–413 Link:  https://goo.gl/L84F7L
  14. Guoqiang Xiang∗, Yingming Zhang, Xiuming Jiang, Lijun He, Lu Fan et al (2010)  Determination of trace copper in food samples by flame atomic absorption spectrometry after solid phase extraction on modified soybean hull. Journal of Hazardous Materials 179:     521–525 Link: https://goo.gl/eYqEDr
  15. AS Al Khalifa, Dilshad Ahmad (2010) Determination of key elements by ICP-OES in commercially available infant formulae and baby foods in Saudi Arabia. African Journal of Food Science 4: 464 - 468 Link: https://goo.gl/M9Sh7z   
  16. Shun-xing li, Lu-xiu lin, Feng-ying zheng, Qing-xiang wang (2011) Metal Bioavailability and Risk Assessment from Edible Brown Alga Laminaria japonica, Using Biomimetic Digestion and Absorption System and Determination by ICP-MS. J Agric Food Chem 59: 822–828 Link: https://goo.gl/ALkfVE
  17. Teslima Daşbaşı, Saçmacı Ş, Ahmet Ülgen, Kartal Ş (2015)  A solid phase extraction procedure for the determination of Cd(II) and Pb(II) ions in food and water samples by flame atomic absorption spectrometry. Food Chemistry 174: 591–596 Link: https://goo.gl/r4r5Ck
  18. Teslima Daşbaşı, Saçmacı Ş, Nevin Çankaya, Cengiz Soykan (2016)  A new synthesis, characterization and application chelating resin for determination of some trace metals in honey samples by FAAS. Food Chemistry 203: 283–291 Link: https://goo.gl/xJQiV8
  19. Esra Yıldız, Saçmacı Ş, Kartal Ş, Mustafa Saçmacı (2016) A new chelating reagent and application for coprecipitation of some metals in food samples by FAAS. Food Chemistry 194: 143–148 Link: https://goo.gl/sULerf
  20. Teslima Daşbaşı, Saçmacı Ş, Nevin Çankaya, Cengiz Soykan (2016) Synthesis, characterization and application of a new chelating resin for solid phase extraction, preconcentration and determination of trace metals in some dairy samples by flame atomic absorption spectrometry. Food Chemistry 211:  68–73 Link: https://goo.gl/Nk33GX
  21. Şerife Saçmacı, Şenol Kartal (2010) Determination of some trace metal ions in various samples by FAAS after separation/preconcentration by copper(II)-BPHA coprecipitation method. Microchim Acta  170: 75–82 Link: https://goo.gl/26xL8b
  22. Fengying Zhenga, Xiaofeng Lin, Huiwu Yu, Shunxing Li, Xuguang Huang (2016) Visible-light photoreduction, adsorption, matrix conversion and membrane separation for ultrasensitive chromium determination in natural water by X-ray fluorescenceSensors and Actuators B. Chemical  226: 500-505 Link: https://goo.gl/sH8RL8  
  23. Minami T, Atsumi K, Ueda J (2003) Determination of cobalt and nickel by graphite-furnace atomic absorption spectrometry after coprecipitation with scandium hydroxide. Anal Sci 19: 313–315 Link: https://goo.gl/Equ6Pc
  24. Ueda J, Mizui C (1988) Preconcentration of gallium(III) and indium (III) by coprecipitation with hafnium hydroxide for electrothermal atomic absorption spectrometry. Anal Sci 4: 417–421 Link: https://goo.gl/bacpPF
  25. Minamisawa H, Ilzima A, Minamisawa M, Tanaka S, Arai N, Et al. (2004) Preconcentration of gallium by coprecipitation with synthetic zeolites prior to determination by electrothermal atomic absorption spectrometry. Anal Sci 20: 683–687 Link: https://goo.gl/dzTZ4D
  26. Zolotov YA, Kuz’min NM (1990) Preconcentration of trace elements. 81 Link: https://goo.gl/8ynsrE

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