RU2681650C1 - Method for determining mercury in fish and fish products - Google Patents

Abstract

FIELD: analytical chemistry.SUBSTANCE: invention relates to analytical chemistry and can be used to determine mercury in fish and fish products. To do this, homogenize the meat of fish or fish products and place the sample in a mixture of 1 % solution of potassium permanganate, nitric, perchloric and sulfuric acids, deionized water in the ratio 1:10:10:50:200. Mixture is boiled until the bottom layer is completely clear, then cooled and diluted with water in the original volume. Polymethacrylate matrix in which diphenylcarbazone is immobilized for 15 minutes is placed in the prepared sample. After that, the matrix is removed, dried with filter paper and measure the optical density of the treated matrix at 550 nm. Conduct a visual assessment of the intensity of the color of the matrix on the color scale, and the quantitative content of mercury is determined by the graph of the dependence of the concentration of mercury in the solution on the optical density of the matrix with immobilized diphenylcarbazone after interaction with mercury.EFFECT: invention provides for the rapid determination of mercury in samples without the use of toxic solvents and additional equipment.1 cl, 3 dwg, 1 ex, 1 tbl

Description

The invention relates to analytical chemistry, namely to the analysis of food products that are examined by excitation by optical means, and can be used to determine mercury in food products.

A known method for the determination of mercury in fish [US 20050208670 A1, publ. 09/22/2005], in which a fish sample is crushed and dissolved in a mixture of inorganic acids to release the mercury contained in it. Then the solution is placed in the cell for electrolysis and measure the potential difference between the electrodes for 10 minutes. This method can detect up to 0.2 μg of mercury in the sample.

However, incomplete conversion of mercury from a biological sample to a solution leads to underestimated analysis results.

A known method for determining mercury in fish oil [Cheng-Hung Yao, Shiuh-Jen Jiang, A.C. Sahayam, Yeou-Lih Huang Speciation of mercury in fish oils using liquid chromatography inductively coupled plasma mass spectrometry. Microchemical Journal, Volume 133, July 2017, Pages 556-560], including the use of liquid chromatography followed by pneumatic inhaled mass spectrometry with inductively coupled plasma. A C8 reverse phase column and a solution containing 0.6% vol. 2-mercaptoethanol and 3% methanol, as the mobile phase, the result is obtained within 6 minutes. The detection limits for mercury are from 0.013 to 0.026 ng / ml.

A known method for determining mercury in fish samples [Siqi Zhu, Beibei Chen, Man He, Tong Huang, Bin Hu Specification of mercury in water and fish samples by HPLC-ICP-MS after magnetic solid phase extraction Talanta Volume 171, 15 August 2017, Pages 213-219], in which mercury is sorbed from fish samples onto magnetic Fe ₃ O ₄ -SiO ₂ nanoparticles coated with γ-mercaptopropyltrimethoxysilane. Then, the resulting particles are separated by high performance liquid chromatography with a methanol liquid phase. The mercury detection limit is 0.5 ng / L.

However, the use of toxic solvents requires strict observance of safety standards, and the need to use expensive analytical equipment significantly increases the cost of analysis.

A known method for determining mercury in fish [Armin Fashi, Mohammad Reza Yaftian, Abbasali Zamani Electromembrane extraction-preconcentration followed by microvolume UV-Vis spectrophotometric determination of mercury in water and fish samples. Food Chemistry 221 (2017) 714-720], which is selected as a prototype.

In this method, in preparation for analysis, 5 g of homogenized fish is transferred to a 50 ml flask and a mixture of 1 ml of deionized water, 1 ml of nitric acid, 1 ml of perchloric acid, 5 ml of sulfuric acid and 0.1 ml of a solution of 1% permanganate is added. potassium. Then the contents of the flask are boiled until a clear solution is obtained. This solution was cooled, the volume was adjusted to 50 ml with water and filtered using a membrane filter (made from bis (2-ethylhexyl) phosphate and impregnated with 2% octanol) under the influence of an electric field (at a constant potential of 70 V). A portion of the filtered solution with a volume of 8 μl was taken with a microsyringe and complexing reagent (20 μl of phosphate buffer, 80 μl of a solution of 1,2-pyridylazo-2-naphthol in methanol with a concentration of 0.002 mol / l) was added to a previously prepared solution. Mercury forms a colored complex with 1,2-pyridylazo-2-naphthol, which can be detected visually or spectrophotometrically at a wavelength of 554 nm in the range of 0.040-9.500 mg / kg with a detection limit of 0.012 mg / kg.

The use of toxic solvents of octanol and methanol, as well as membrane filtration of the sample, limit the possibilities of using this method.

The technical result of the proposed method is the rapid determination of mercury in fish and fish products without the use of toxic solvents and additional equipment.

The method for determining mercury in fish and fish products, as well as in the prototype, includes the homogenization of fish meat or fish product, a sample of which is placed in a mixture of 1% solution of potassium permanganate, nitric, perchloric and sulfuric acids, deionized water in a ratio of 1:10:10: 50: 200; the mixture is boiled until the bottom layer is completely clarified, cooled, diluted with water according to the initial volume, using a color-forming reagent, the optical density of the obtained mercury complex is measured, which is used to judge the mercury content in the test sample.

According to the invention, diphenylcarbazone is used as a color-forming reagent, immobilized in a polymethacrylate matrix, which is placed for 15 minutes in a prepared sample, removed, dried with filter paper, the absorbance of the treated matrix is measured at 550 nm. A visual assessment of the color intensity of the matrix is carried out on a colorimetric scale, and the quantitative content of mercury is determined by plotting the concentration of mercury in the solution as a function of the optical density of the matrix with immobilized diphenylcarbazone after interaction with mercury.

Diphenylcarbazone immobilized into a polymethacrylate matrix and giving it a pink tint is used as a color-forming reagent. At pH 6, mercury ions interact with immobilized diphenylcarbazone to form a color complex; as a result, the matrix changes color from pink to purple. The color intensity of the polymethacrylate matrix is directly proportional to the concentration of mercury ions in the analyzed sample.

The choice of diphenylcarbazone immobilized into a polymethacrylate matrix as a color-forming reagent is due to the fact that it is a specific indicator for mercury, which gives a clearer, contrasting transition of color in acidic media from pink to violet for 15 minutes, which is necessary and sufficient for visual indication, and also avoids the interfering effects of other metals that may be present in the sample.

The use of a polymethacrylate matrix with immobilized diphenylcarbazone made it possible to determine the mercury content with a detection limit of 0.04 mg / kg at the MPC level in the range of 0.2-20 mg / kg. The use of such a color-forming reagent eliminates the stage of membrane filtration and eliminates the use of a number of chemical reagents, including toxic, which reduced the analysis time and made it cheaper and more affordable.

In FIG. Figure 1 shows a colorimetric scale for determining mercury in a concentration range of 0.2-20 mg / kg.

In FIG. 2 shows the absorption spectra of: diphenylcarbazone immobilized in a polymethacrylate matrix - curve 1; a complex immobilized in the polymethacrylate matrix of diphenylcarbazone with mercury after contact with a sample containing mercury at a concentration of 20 mg / kg - curve 2; 10 mg / kg - curve 3; 1 mg / kg - curve 4; 0.2 mg / kg - curve 5.

In FIG. Figure 3 shows a calibration graph of the optical density of the complex of mercury with diphenylcarbazone versus mercury concentration in the range of 0.2-20 mg / kg.

Table 1 presents the results of the determination of mercury in fish and fish products (number of measurements n = 3-4, measurement reliability P = 0.95) on a colorimetric scale.

The color-forming complexing agent of diphenylcarbazone was immobilized into a transparent polymethacrylate matrix measuring 6.0 × 8.0 × 0.6 mm by sorption of diphenylcarbazone from its aqueous-ethanol solution at a concentration of 0.002 M for 6 min in a static mode at pH 6. The matrix acquired a weak pink coloring.

5 g of fish (fish product) was added to a 50 ml flask and a mixture of 20 ml of water, 1 ml of nitric acid, 1 ml of perchloric acid, 5 ml of sulfuric acid and 0.1 ml of a solution of 1% potassium permanganate was added. The resulting solution was boiled until a clear solution was obtained, cooled to room temperature and the volume was adjusted to 50 ml with water.

Then, a polymethacrylate matrix with immobilized diphenylcarbazone was introduced into the test solution and mixed thoroughly for 15 minutes, removed, dried with filter paper, and the optical density of the matrix was measured on an Evolution 60 spectrophotometer at a wavelength of 550 nm. Depending on the concentration of mercury, the optical density value changes. The presence of mercury ions in the solution was visually (semi-quantitatively) observed when the color of the matrix changed from pink to violet due to the formation of a complex of mercury with diphenylcarbazone in it (Fig. 1). This is evidenced by the absorption spectra (Fig. 2), where the maximum absorption of the matrix with immobilized diphenylcarbazone - 520 nm (curve 1) corresponds to a pink color, and the absorption maximum of 550 nm corresponds to shades of purple color of different intensities (curves 2-5) depending on mercury content in a standard solution.

Quantitative assessment of mercury concentration was carried out according to the calibration graph (Fig. 3).

To visually test the determination of mercury content, a colorimetric scale was obtained (Fig. 1) by scanning samples obtained during the construction of calibration dependences. When the mercury content was visually determined after contact with the mercury solution, the absorption of the polymethacrylate matrix was not measured, and their color was compared with the colorimetric scale.

The results of determining the mercury content in the homogenized muscle tissue of carp, minced pike, in the homogeneous solid content of canned fish Saira Atlantica are presented in table 1.

Claims (1)

A method for determining mercury in fish and fish products, comprising homogenizing fish meat or fish product, a sample of which is placed in a mixture of 1% solution of potassium permanganate, nitric, perchloric and sulfuric acids, deionized water in a ratio of 1: 10: 10: 50: 200; the mixture is boiled until the bottom layer is completely clarified, cooled, diluted with water according to the initial volume, using the color-forming reagent, the optical density of the mercury complex is measured, which is used to judge the mercury content in the test sample, characterized in that diphenylcarbazone immobilized in polymethacrylate is used as the color-forming reagent the matrix, which is placed for 15 min in the prepared sample, is removed, dried with filter paper, and then the optical density is measured m Atritics at 550 nm, a visual assessment of the color intensity of the matrix is carried out on a colorimetric scale, and the quantitative content of mercury is determined by plotting the concentration of mercury in solution versus the optical density of the matrix with immobilized diphenylcarbazone after interaction with mercury.

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