Interference-free, green microanalytical method for total mercury and methylmercury determination in biological and environmental samples using small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry

An analytical method for the quantification of total Hg and CH3Hg+ in biological tissues (fish, mushroom) and water sediment was developed based on small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry using a low-resolution microspectrometer as...

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Veröffentlicht in:	Talanta (Oxford) 2020-09, Vol.217, p.121067-121067, Article 121067
Hauptverfasser:	Angyus, Simion Bogdan, Darvasi, Eugen, Ponta, Michaela, Petreus, Dorin, Etz, Radu, Senila, Marin, Frentiu, Maria, Frentiu, Tiberiu
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Schlagworte:	Electrothermal vaporization Green analytical method Mercury Methylmercury Miniaturized instrumentation Optical emission spectrometry
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description	An analytical method for the quantification of total Hg and CH3Hg+ in biological tissues (fish, mushroom) and water sediment was developed based on small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry using a low-resolution microspectrometer as detector. Sample preparation was carried out according to the procedure recommended by JRC Technical Report of European Commission for the determination of CH3Hg+ in seafood and adapted by us for lower consumption of reagents. Amounts of 0.1 – 0.5 g sample were subjected to extraction in 5 ml of 47% HBr then CH3Hg+ was extracted in 2 × 1 ml toluene and back-extracted in 2 ml aqueous solution of 1% l-cysteine. Total Hg/CH3Hg+ were quantified in 10 μl of acidic extract/l-cysteine solution after electrothermal vaporization and measurement of 253.652 nm Hg signal in the episodic emission spectra. Under the optimal working conditions of system (70 °C sample drying, 1300 °C sample vaporization, 10 W plasma power and 150 ml min−1 Ar flow) the limits of detection were 7.0 μg kg−1 total Hg and 3.5 μg kg−1 CH3Hg+. Comparison of slopes in external calibration and standard addition procedure revealed the lack of non-spectral interferences of multimineral matrix, so that the calibration against Hg2+ standards was adopted. Pooled recovery of total mercury/methylmercury was 101 ± 7%/100 ± 7%, while precision assessed from measurements of real samples was in the range 1.6-9.6%/2.7-12.8%. The proposed method validated according to Eurachem Guide 2014 is selective and complies with demands in European legislation (Decisions 657/2002; 333/2007; 836/2011) and Association of Official Analytical Chemists Guide in terms of performances for food control. The method displays a high degree of greenness by circumventing cold vapor generation, use of small amounts of reagents and full-miniaturized instrumentation resulting in low analytical costs without reducing results quality. Besides, the method is simple and rapid, since it uses external calibration curves prepared from Hg2+standard solutions both for total Hg and CH3Hg+ determination. [Display omitted] •Total Hg and CH3Hg+ were directly quantified in biological samples and water sediments.•Quantification is based on external calibration using Hg2+ standards.•The method is free from non-spectral interferences and complies with GAC practice.•Method validation proved compliance with EU legislation relative to food control.
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Sample preparation was carried out according to the procedure recommended by JRC Technical Report of European Commission for the determination of CH3Hg+ in seafood and adapted by us for lower consumption of reagents. Amounts of 0.1 – 0.5 g sample were subjected to extraction in 5 ml of 47% HBr then CH3Hg+ was extracted in 2 × 1 ml toluene and back-extracted in 2 ml aqueous solution of 1% l-cysteine. Total Hg/CH3Hg+ were quantified in 10 μl of acidic extract/l-cysteine solution after electrothermal vaporization and measurement of 253.652 nm Hg signal in the episodic emission spectra. Under the optimal working conditions of system (70 °C sample drying, 1300 °C sample vaporization, 10 W plasma power and 150 ml min−1 Ar flow) the limits of detection were 7.0 μg kg−1 total Hg and 3.5 μg kg−1 CH3Hg+. Comparison of slopes in external calibration and standard addition procedure revealed the lack of non-spectral interferences of multimineral matrix, so that the calibration against Hg2+ standards was adopted. Pooled recovery of total mercury/methylmercury was 101 ± 7%/100 ± 7%, while precision assessed from measurements of real samples was in the range 1.6-9.6%/2.7-12.8%. The proposed method validated according to Eurachem Guide 2014 is selective and complies with demands in European legislation (Decisions 657/2002; 333/2007; 836/2011) and Association of Official Analytical Chemists Guide in terms of performances for food control. The method displays a high degree of greenness by circumventing cold vapor generation, use of small amounts of reagents and full-miniaturized instrumentation resulting in low analytical costs without reducing results quality. Besides, the method is simple and rapid, since it uses external calibration curves prepared from Hg2+standard solutions both for total Hg and CH3Hg+ determination. 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Sample preparation was carried out according to the procedure recommended by JRC Technical Report of European Commission for the determination of CH3Hg+ in seafood and adapted by us for lower consumption of reagents. Amounts of 0.1 – 0.5 g sample were subjected to extraction in 5 ml of 47% HBr then CH3Hg+ was extracted in 2 × 1 ml toluene and back-extracted in 2 ml aqueous solution of 1% l-cysteine. Total Hg/CH3Hg+ were quantified in 10 μl of acidic extract/l-cysteine solution after electrothermal vaporization and measurement of 253.652 nm Hg signal in the episodic emission spectra. Under the optimal working conditions of system (70 °C sample drying, 1300 °C sample vaporization, 10 W plasma power and 150 ml min−1 Ar flow) the limits of detection were 7.0 μg kg−1 total Hg and 3.5 μg kg−1 CH3Hg+. Comparison of slopes in external calibration and standard addition procedure revealed the lack of non-spectral interferences of multimineral matrix, so that the calibration against Hg2+ standards was adopted. Pooled recovery of total mercury/methylmercury was 101 ± 7%/100 ± 7%, while precision assessed from measurements of real samples was in the range 1.6-9.6%/2.7-12.8%. The proposed method validated according to Eurachem Guide 2014 is selective and complies with demands in European legislation (Decisions 657/2002; 333/2007; 836/2011) and Association of Official Analytical Chemists Guide in terms of performances for food control. The method displays a high degree of greenness by circumventing cold vapor generation, use of small amounts of reagents and full-miniaturized instrumentation resulting in low analytical costs without reducing results quality. Besides, the method is simple and rapid, since it uses external calibration curves prepared from Hg2+standard solutions both for total Hg and CH3Hg+ determination. [Display omitted] •Total Hg and CH3Hg+ were directly quantified in biological samples and water sediments.•Quantification is based on external calibration using Hg2+ standards.•The method is free from non-spectral interferences and complies with GAC practice.•Method validation proved compliance with EU legislation relative to food control.</description><subject>Electrothermal vaporization</subject><subject>Green analytical method</subject><subject>Mercury</subject><subject>Methylmercury</subject><subject>Miniaturized instrumentation</subject><subject>Optical emission spectrometry</subject><issn>0039-9140</issn><issn>1873-3573</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><recordid>eNqFkUtr3DAUhUVpoNMkPyGgZRf1VA8_V6WEpg0EsmnXQpauZzTIkivJA85v76LyOF1nI8G953ycy0HojpI9JbT-ctonaaVLcs8IyzNGSd28QzvaNrzgVcPfox0hvCs6WpIP6GOMJ0II44Tv0N9HlyAMEMApKIYA8Bkf8uvwaFTw0km7JKOkxSOko9d48AEnny6DoOawYOn0ZbnY_xMNmTkaJ5PxDhuHe-OtP1wwqxrc2QTvRnArJ8pxshDxHI074DhKa4toXiDrLKgUfDpmWhae5eSDedmoSk5SmWTOYBes_JwRGk9WZv8WPfmgjthPW3oYTYyrL04XZg4clht0NUgb4fb1v0a_H77_uv9ZPD3_eLz_9lQoXrJUyKYbKGVtpZuaDmXbVnVZyop1Wqu-Jj1UoBiBsqUVB94DDH3fDU1TM9b0rKb8Gn3auFPwf2aISeQ0CmwuDfwcBSsp4VVJWJul1SbNF8QYYBBTMKMMi6BErG2Lk3htW6xti63t7Pu6-SDfcTYQRFRm7VSbkA8W2ps3CP8AY93AvA</recordid><startdate>20200901</startdate><enddate>20200901</enddate><creator>Angyus, Simion Bogdan</creator><creator>Darvasi, Eugen</creator><creator>Ponta, Michaela</creator><creator>Petreus, Dorin</creator><creator>Etz, Radu</creator><creator>Senila, Marin</creator><creator>Frentiu, Maria</creator><creator>Frentiu, Tiberiu</creator><general>Elsevier B.V</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope></search><sort><creationdate>20200901</creationdate><title>Interference-free, green microanalytical method for total mercury and methylmercury determination in biological and environmental samples using small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry</title><author>Angyus, Simion Bogdan ; Darvasi, Eugen ; Ponta, Michaela ; Petreus, Dorin ; Etz, Radu ; Senila, Marin ; Frentiu, Maria ; Frentiu, Tiberiu</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c342t-a79f11285d761f4885644a529ddcb60be5ec20e48153e3beefbb9f776227b2613</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2020</creationdate><topic>Electrothermal vaporization</topic><topic>Green analytical method</topic><topic>Mercury</topic><topic>Methylmercury</topic><topic>Miniaturized instrumentation</topic><topic>Optical emission spectrometry</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Angyus, Simion Bogdan</creatorcontrib><creatorcontrib>Darvasi, Eugen</creatorcontrib><creatorcontrib>Ponta, Michaela</creatorcontrib><creatorcontrib>Petreus, Dorin</creatorcontrib><creatorcontrib>Etz, Radu</creatorcontrib><creatorcontrib>Senila, Marin</creatorcontrib><creatorcontrib>Frentiu, Maria</creatorcontrib><creatorcontrib>Frentiu, Tiberiu</creatorcontrib><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><jtitle>Talanta (Oxford)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Angyus, Simion Bogdan</au><au>Darvasi, Eugen</au><au>Ponta, Michaela</au><au>Petreus, Dorin</au><au>Etz, Radu</au><au>Senila, Marin</au><au>Frentiu, Maria</au><au>Frentiu, Tiberiu</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Interference-free, green microanalytical method for total mercury and methylmercury determination in biological and environmental samples using small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry</atitle><jtitle>Talanta (Oxford)</jtitle><date>2020-09-01</date><risdate>2020</risdate><volume>217</volume><spage>121067</spage><epage>121067</epage><pages>121067-121067</pages><artnum>121067</artnum><issn>0039-9140</issn><eissn>1873-3573</eissn><abstract>An analytical method for the quantification of total Hg and CH3Hg+ in biological tissues (fish, mushroom) and water sediment was developed based on small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry using a low-resolution microspectrometer as detector. Sample preparation was carried out according to the procedure recommended by JRC Technical Report of European Commission for the determination of CH3Hg+ in seafood and adapted by us for lower consumption of reagents. Amounts of 0.1 – 0.5 g sample were subjected to extraction in 5 ml of 47% HBr then CH3Hg+ was extracted in 2 × 1 ml toluene and back-extracted in 2 ml aqueous solution of 1% l-cysteine. Total Hg/CH3Hg+ were quantified in 10 μl of acidic extract/l-cysteine solution after electrothermal vaporization and measurement of 253.652 nm Hg signal in the episodic emission spectra. Under the optimal working conditions of system (70 °C sample drying, 1300 °C sample vaporization, 10 W plasma power and 150 ml min−1 Ar flow) the limits of detection were 7.0 μg kg−1 total Hg and 3.5 μg kg−1 CH3Hg+. Comparison of slopes in external calibration and standard addition procedure revealed the lack of non-spectral interferences of multimineral matrix, so that the calibration against Hg2+ standards was adopted. Pooled recovery of total mercury/methylmercury was 101 ± 7%/100 ± 7%, while precision assessed from measurements of real samples was in the range 1.6-9.6%/2.7-12.8%. The proposed method validated according to Eurachem Guide 2014 is selective and complies with demands in European legislation (Decisions 657/2002; 333/2007; 836/2011) and Association of Official Analytical Chemists Guide in terms of performances for food control. The method displays a high degree of greenness by circumventing cold vapor generation, use of small amounts of reagents and full-miniaturized instrumentation resulting in low analytical costs without reducing results quality. Besides, the method is simple and rapid, since it uses external calibration curves prepared from Hg2+standard solutions both for total Hg and CH3Hg+ determination. [Display omitted] •Total Hg and CH3Hg+ were directly quantified in biological samples and water sediments.•Quantification is based on external calibration using Hg2+ standards.•The method is free from non-spectral interferences and complies with GAC practice.•Method validation proved compliance with EU legislation relative to food control.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.talanta.2020.121067</doi><tpages>1</tpages></addata></record>
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subjects	Electrothermal vaporization Green analytical method Mercury Methylmercury Miniaturized instrumentation Optical emission spectrometry
title	Interference-free, green microanalytical method for total mercury and methylmercury determination in biological and environmental samples using small-sized electrothermal vaporization capacitively coupled plasma microtorch optical emission spectrometry
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