Ultra-High-Throughput Analytical Strategy Based on UHPLC-DAD in

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Ultra-High-Throughput Analytical Strategy Based on UHPLC-DAD in Combination with Syringe Filtration for the Quantification of 9 Synthetic Colorants in Beverages: Impacts of Syringe Membrane Types and Sample pH on Recovery Je Young Shin, and Mun Yhung Jung J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.7b03882 • Publication Date (Web): 30 Oct 2017 Downloaded from http://pubs.acs.org on October 30, 2017

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Journal of Agricultural and Food Chemistry is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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Ultra-High-Throughput Analytical Strategy Based on UHPLC-DAD in Combination with

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Syringe Filtration for the Quantitation of 9 Synthetic Colorants in Beverages: Impacts of

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Syringe Membrane Types and Sample pH on Recovery

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Je Young Shin and Mun Yhung Jung*

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Department of Food Science and Biotechnology, Graduate School, Woosuk University,

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Samnye-ro 443, Samnye-eup, Wanju-gun, Jeonbuk Province 565-701, Republic of Korea. Tel)

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82-63-290-1438 Fax) 82-63-291-9312, e-mail) [email protected]

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*To whom correspondence should be addressed.

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ABSTRACT

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An ultra-high-throughput approach based on UHPLC-DAD in combination with simple

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syringe filtration was successfully developed and validated for the quantitation of 9 synthetic

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colorants in beverages. The recoveries of the colorants from the beverages were found to be

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dramatically affected by the syringe filter membrane types and pH of the sample solution.

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The high recoveries of the 9 colorants (92.7 - 105.9%) were achieved by the syringe filtration

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with PVDF membrane following the pH adjustment of sample solution at pH 7.0. The sample

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treatment procedure was very simple and took only 1 min. The fast chromatographic

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separation (1 min) of the nine synthetic colorants was achieved by UHPLC-DAD using a

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C18-core-shell column. This analytical approach (UHPLC-DAD combined with syringe

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filtration) took only approximately 3 min. The established method was ultrafast, sensitive,

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precise, accurate and reliable. The method was successfully applied to rapidly determine the

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9 colorants in 17 beverages.

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Keywords: Synthetic colorant, syringe filter, beverages, UHPLC–DAD, method validation

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 INTRODUCTION

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Food colorants are commonly used for increasing the commercial values, acceptability and

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appetite of various foods including beverages. Colored beverages are popular in the market

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due to the visual preference of consumers.1 Synthetic colorants are preferred in beverages due

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to their low price and high stability against light, temperature, and oxygen, as compared to

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natural colorants.2 However, synthetic colorants have been reported to increase various

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human health risks including allergy and asthmatic reaction, DNA damage, hyperactivity, and

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carcinogenesis.3-8 The use of synthetic colorants in foods and beverages is strictly regulated

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by legislation throughout the world.9 Thus, the contents of synthetic colorants in beverages

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should be continuously monitored.

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Many analytical techniques including thin-layer chromatography, liquid chromatography,

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adsorptive voltammetry, spectrophotometric methods, and differential pulse polarography

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have been developed for the determination of synthetic food colorants.10-16 Most popular

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methods for the determination of synthetic food colorants are liquid chromatographic

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methods in combination with diode array detectors (DADs), ultraviolet (UV), or mass

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spectrometer (MS).12-16 However, high throughput analytical methods for the determination

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of synthetic colorants in the food products are still required, especially in the laboratories

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facing the challenges of saving the analytical time and treating the large amount of samples in

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a short period. UHPLC with a core-shell column may provide the dramatic increase in

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analytical speed.17,18 However, the UHPLC in combination with core shell column has never

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been previously applied for the fast separation of synthetic colorants. In addition, for the fast

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analysis of colorants, not only the fast chromatographic separation but also rapid sample

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preparation techniques are required. However, time consuming sample preparation techniques

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(extraction and purification) have been generally practiced for the determination of the

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synthetic colorants. Simple dilution and direct syringe filtration has been previously

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introduced for the chromatographic analysis of synthetic colorants in beverages.14,19-22 In our

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preliminary study, however, it was found that considerable amounts of colorants were

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retained in the filter membranes of certain types of syringe filters, resulting in the significant

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losses of the target colorants during syringe filtration. We also found that the retention

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behavior of the synthetic colorants was greatly dependent on the syringe membrane types and

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pH of the sample solution. To date, however, the impact of the types of syringe filter

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membrane on the recovery of synthetic colorants in beverages has never been previously

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studied. 14,19-22 Furthermore, the impact of pH of the sample solution for the recovery of the

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colorants during syringe filtration has not been also reported.

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The main objective of this research was to develop and validate an ultrafast analytical method

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based on UHPLC-DAD combined with syringe filtration for the determination of nine

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synthetic colorants (Indigo Carmine, Erythrosine B, Tartrazine, Sunset Yellow FCF, Fast

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Green FCF, Brilliant Blue FCF, Allura Red AC, Amaranth, and Ponceau 4R) in beverages. To

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achieve this, the optimum sample preparation conditions such as the impact of syringe types

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(cellulose, nylon, PES, and PVDF) and pH of the sample solution on the recovery of the

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colorants were studied. UHPLC-DAD using a core-shell column was also established for the

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ultrafast separation and quantification of the synthetic colorants in beverages. The chemical

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structures of nine synthetic colorants are shown in Figure 1.

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 MATERIALS AND METHODS

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Reagents and samples

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Synthetic colorant standards such as Tartrazine (E102, 95% purity), Sunset Yellow FCF (E

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110, 90% purity), Indigo carmine (E 132, 95% purity), Ponceau 4R (E 124, 82 % purity),

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Amaranth (E123, 90.0% purity). Erythrozine B (E127, 95.0% purity), Fast Green FCF (E143,

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85.0% purity), Allura red AC (E 129, 80% purity) and Brilliant Blue FCF (E 133, 95 %

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purity) were obtained from Tokyo Chemical Industry (Tokyo, Japan). Ammonium acetate

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and HPLC-grade methanol were purchased from Riedel-de Haen (Seelze, Germany) and JT

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Baker Chemical (Phillipsburg, NJ), respectively. Acetonitrile and water (HPLC-grade) were

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obtained from Fisher Scientific (Fair Lawn. NJ). The syringe filters of different membrane

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types (pore size, 0.45 µm; PVDF, Nylon, Cellulose, and PES) were purchased from Agela

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Technologies (Bonna-Agela Technologies Inc., Wilmington, DE, USA). Colored beverages

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(n=17) with synthetic colorant additive were purchased from several local markets.

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Preparation of standard solutions

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Individual standard stock solutions containing each colorant (500 mg/L) were prepared with

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distilled deionized water. Then, working standard solutions (0.05–50.0 mg/L) were prepared

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by a serial dilution of the stock standard solutions with deionized water. The standards

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solutions were stored in a refrigerator (4-6 ºC) until used. It was found that the stability of the

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standard solutions were stable at least for 53 days in the refrigerator.

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Sample preparation

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Carbonated beverages were transferred into 50 mL-capacity polypropylene conical tubes

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(SPL Lifesciences Co. Ltd, Pocheonsi, Republic of Korea) and placed in a sonication bath for

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10 min at room temperature to remove the CO2 gas. Noncarbonated beverages were not

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treated in the sonication bath. The impact of filter types (Nylon, PVDF, Cellulose, and PES)

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on the recovery of the colorants was studied by determining the recovered colorant contents

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after the filtration of the standard solution (10.0 mg/L) with the syringe filters. To study the

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impact of pH of the sample solution on the recovery of the colorants, the beverage samples

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spiked with the colorants at three different concentrations (1.0, 4.0, and 10.0 mg/L) were

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prepared. Then, the pH of the spiked beverage samples (20 mL) was adjusted to pH 3.5, 4.5,

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5.0, 5.5, 6.0, 6.5, 7.0, and 7.5 with 10% sodium hydroxide solution and then brought to 25

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mL with distilled water. Then, the sample solutions were filtered with a syringe filter (PVDF).

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UHPLC-DAD was conducted for the calculation of the recovery rates.

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UHPLC-DAD analysis

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UHPLC-DAD method was conducted with a Nexera UHPLC system (Shimadzu, Tokyo,

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Japan) consisting of dual-pump (LC-30 AD), auto-sampler (SIL-30AC), semi-micro

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photodiode array detector (SPD-M20A), and controller (CTO-20AC). The column used was a

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2.1 x 100 mm x 2.1 mm i.d., 2.6 µm, core-shell Kinetex C18 (Phenomenex, Torrance, CA,

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USA). The mobile phase system was composed of 0.02M ammonium acetate in water (A)

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and methanol/ acetonitrile (80:20, v/v) (B). The mobile phase gradient program for the

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UHPLC was as following: gradient program of 0-0.10 min, 10% B; 0.10-0.20 min 45% B;

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0.20-0.45 min 50% B; 0.45-0.55 min 70% B; 0.55-0.75 min 90% B; 0.75-1.20 min, 100% B;

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1.20-1.60 min, 100% B; 1.60-1.70 min, 10% B; 1.80-2.00 min. 10% B. The flow rate of

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mobile phase was 1.0 mL/min. The injection volume was 5 µL and the column temperature

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was maintained at 40 o C. Quantification of the colorants was performed by the DAD detector

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at the appropriate absorbance wavelengths (Table 1). Identifications of the chromatographic

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peaks were performed by matching with the retention times of the authentic colorants. The

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identities of colorants were further confirmed by comparing their scanning absorption spectra

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with those of the standard colorants.

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Method validations

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The working standard solutions (0.05, 0.10, 0.25, 0.50, 1.0, 5.0, 10.0, and 50.0 mg/L) were

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analyzed by the UHPLC-DAD and UHPLC-MS/MS methods to draw the standard calibration

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curves for the colorants. Then, the linearities of the curves, limit of detection (LOD), and

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limit of quantification (LOQ) were obtained. The LOD and LOQ were calculated by the

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formulas: LOD = 3.0 x standard error of y-intercept/slope, and LOQ = 10 x standard error of

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y-intercept/slope. Intra-day precision was studied by the 10 times repeated analysis of the

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standard solutions at the concentrations of 0.25, 2.0, and 5.0 mg/L. Inter-day precision of the

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method was also studied by the repeated analysis of the nine common synthetic colorants at

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the concentrations of 0.25, 2.0, and 5.0 mg/L for 6 different dates in triplicate analysis per

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sample for each day. Accuracy of the method was tested by analyzing the sample beverage

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spiked at the concentrations of 1.0, 4.0, and 10.0 mg/L.

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Statistical analysis

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A SPSS statistical analysis program (SPSS 14.0 K, SPSS) was used for conducting the

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Tukey’s multiple-range test to ascertain the statistical differences in the obtained quantitative

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data at α = 0.05 by using.

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 RESULTS AND DISCUSSION

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UHPLC-DAD method optimization

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The UHPL-DAD method was performed with a sub-3 µm core-shell C18 column, which has

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been known to provide high separation efficiency similar to a sub-2 µm fully porous columns,

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while maintaining lower back pressure. A series of experiments was conducted to obtain the

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optimal separation condition. Due to the lower column back pressure with the core-shell

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column, high flow rate (1 mL/min) of mobile phases could be applied. The mobile phase

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system was composed of 0.02M ammonium acetate in water and methanol: acetonitrile

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(80:20 v/v). The mobile phase gradient program was optimized to obtain the efficient

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separation of the nine colorants. In this study, a satisfactory ultrafast chromatographic

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separation (less than 1 min) was achieved for all the 9 synthetic colorants including the

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critical pair of Fast Green FCF and Brilliant Blue FCF (Figure 2). The resolution (R) of the

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critical pair of Fast Green FCF and Brilliant Blue FCF was calculated to be 0.93, which was

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acceptable for the quantification purpose (Figure 2). A fast HPLC-DAD method, which took

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13 min chromatographic running time for the analysis of 3 synthetic colorants (Amaranth,

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Sunset Yellow, and Tartrazine), has been previously reported.14 Chemometrics-assisted

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HPLC-DAD has been reported to take 6 min for the separation of six synthetic colorants

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(Allura Red, Amaranth, Brilliant Blue, Carmine, Sunset Yellow, and Tartrazine).19 A

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previously reported UHPLC-DAD-MS/MS method took 3 min for the separation of 10

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synthetic colorants (Allura Red AC, Amaranth, Brilliant Blue FCF, Erythrosine B,

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Carmoisine, Indigo Carmine, Paten Blue V, Ponceau 4R, Sunset Yellow FCF, and

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Tartrazine).23 However, these previous chromatographic methods could not be directly

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compared with the present technique due to the different target colorants for the analysis. A

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previous HPLC-DAD method,24 took 18 min for the separation of the same type of nine

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synthetic colorants. Korea Food and Drug Administration official method (KFDA official

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method 2.4.1) includes the 20 min of chromatographic running time for the same nine

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synthetic colorants. Our present UHPLC-DAD method took only 1 min for the

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chromatographic separation of the same nine synthetic colorants.

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Standard curves, linearity, LOD and LOQ, and repeatability

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The established UHPLC-DAD was conducted to obtain the calibration curves, linearity, LOD

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and LOQ of authentic standard solutions. Table 1 shows the linearity and equations of the

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standard curves, LOD and LOQ for the nine synthetic colorant as obtained by the UHPLC-

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DAD. The UHPLC-DAD provided excellent linearity of the standard calibration curves in the

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tested concentration range. The coefficients of the determination (r2) of the curves were

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higher than 0.999. UHPLC-DAD method provided low LOD and LOQ. The LODs of the

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UHPLC-DAD for the synthetic colorants were in the ranges of 0.04 – 0.15 mg/L. The intra-

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day repeatability of the UHPLC-DAD method was obtained by 10 repeated injection of the

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standard solutions at the concentrations of 0.25, 2.0, and 5.0 mg/L. The relative standard

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deviation (% RSD) was in the range of 0.01 – 1.07% for the intra-day repeated analysis,

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showing excellent intra-day precision. The inter-day repeatability with standard solutions at

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the three different concentrations was also conducted by the repeated analysis for six

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different dates. The relative standard deviation (% RSD) was in the range of 0.04 – 0.67% for

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the inter-day analysis of the colorants in standard solutions. The results clearly indicated that

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the UHPLC-DAD method had excellent intra- and inter day-precisions for the colorants.

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Sample preparation

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Fast analysis of colorants requires not only the fast chromatographic separation but also rapid

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sample preparation technique. Table 2 shows the effects of syringe filter membrane type on

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the recovery rates of the colorants in the standard solution (standards dissolved in distilled

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water, 10.0 mg/L). The result clearly showed that the recovery rate was greatly different with

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the types of filter membrane and colorant. PVDF showed the highest recovery rates of

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colorants, ranging from 98.5 to 102.1 %. Cellulose type syringe filter showed also acceptable

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recovery rates for all the tested colorants. Nylon type syringe filter provide the poor recovery

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rates, ranging from 0 to 61.7%. The high retention of synthetic food colorants in nylon

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membrane syringe filter may be due to the amide groups in its chemical structure. The amide

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groups in nylon membrane may exist in a hydride of two resonance structures (ne as a dipole),

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which could form ion-dipole interaction and hydrogen bonding with polar colorants. The

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strong binding capacity of nylon membrane with certain analytes including acetaminophen,

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ibuprofen, and loratadine has been previously reported.25,26 However, this is the first report on

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the high retention of the synthetic colorants in nylon syringe filter. PES syringe filter showed

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selectively low recovery rate for Erythrosine B. The recovery rates of Erythrosine B was

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24.3%. Direct syringe filtration for the HPLC analysis of synthetic colorants in beverages has

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been previously reported.13,14,20-22 However, our result was not consistent with the those of the

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previous reports. The recovery rates of Tartrazine, Amaranth, Ponceau 4R and Sunset Yellow

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FCF using nylon syringe filter for the sample treatment from soft drink have been reported to

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be in the range of 95.5 – 102.1%.22 However, our data showed that the nylon syringe filter

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showed the least recovery rates among the tested syringe filters, resulting in the recovery of

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61.7, 46.7, 42.5 and 49.8% for Tartrazine, Amaranth, Ponceau 4R and Sunset Yellow FCF,

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respectively. It has been previously reported that the recovery of three synthetic colorants

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(Tartrazine, Amaranth, and Sunset Yellow FCF) by direct syringe filter of beverages were in

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the range of 97 - 105%.14 Unfortunately, the authors did not specify the syringe filter type

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used for the sample preparation. Our results showed that these colorants (Tartrazine,

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Amaranth, and Sunset Yellow FCF) were fully recovered by the PVDF, cellulose and PES

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type syringe filters, but nylon syringe filter provided the low recovery of the colorants (Table

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2). In a previous report, the recovery of Carmoisine from fruit flavored drink by direct

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syringe filter has been reported to be 97.9%.21 However, the authors did not specify the type

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of syringe they used. Furthermore, the study on the recovery of other colorants from the

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beverages has not been conducted. Our data clearly showed the recovery of colorants was

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greatly dependent on the types of syringe filter. We conducted experiments to check the

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recovery of the colorants from the beverage sample with PVDF syringe filter, which showed

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excellent recovery of all the tested colorants in the standard solutions. However, the recovery

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rate of the colorants in the real beverage sample was unexpectedly greatly lower than those in

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pure standard solutions. We assumed that these low recovery rates was due to the pH

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difference between the real sample and standard solution. The pH values of standard solution

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and the sport drink were pH 7.0 and pH 3.5, respectively. Thus we studied the effects of pH

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of the beverage on the recovery rates of colorants with PVDF syringe filter (Table 3). The

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results showed that the pH of the sample solution greatly affected the recovery of the

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colorants from the beverage. For example, Erythrosine B was not recovered at all at pH 3.5 of

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the sample solution with PVDF syringe filter. However, the recovery rate of Erythrosine B

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increased dramatically as pH increased, reaching full recovery rate (approximately 100 %) at

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pH 7.0. There was no significant difference in recovery rates of colorants between pH 7 and

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7.5, so we selected pH 7.0 as an extraction condition for the extraction of the colorants from

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beverages. This pretreatment process is very simple and efficient for the analysis of synthetic

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colorants from the beverages. The results suggested that the sample preparation technique

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with the PVDF syringe at pH 7.0 of the sample solution gives high accuracy of the method as

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assessed by studying the recovery of spiked beverage with different concentrations of

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synthetic colorant. The simple syringe filtration technique provided high accuracy and

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rapidity for the sample preparation. To our knowledge, the pH dependent recovery of

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colorants by syringe filter has never been previously reported.

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Application of the method

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The established analytical approach was applied to determine the synthetic colorant in 17

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beverages available in Korean market. Figure 3 showed exemplary chromatograms of the

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synthetic colorant in commercial beverages. No interference was found in the UHPLC-DAD

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chromatograms of all the tested beverage samples. The contents of synthetic colorants in the

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beverages are shown in Table 4. There was a great variation on the type and contents of

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colorants in the samples depending on the products. Single colorant was found in 9 beverage

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products. Mixtures of two different colorants were found in nine out of 17 beverages tested.

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Mixtures of three different colorants were found in one beverage product. Only four colorants

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(Tartrazine, 0.73 - 10.81 mg/L; Sunset Yellow FCF, 1.17 - 57.98 mg/L; Allura Red AC, 1.00

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- 56.23 mg/L; and Brilliant Blue FCF, 1.14 - 6.92 mg/L) were found in the beverages. Allura

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Red AC and Sunset Yellow FCF were the most widely employed colorants in the beverages

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tested, followed by Tartrazine, Brilliant Blue FCF, and Ponceau 4R in a decreasing order.

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The concentrations of synthetic colorants in the beverages were in the range of 0.73 – 57.98

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mg/L. The contents of synthetic colorant in all the tested beverages were lower than the legal

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maximum limits set by Korean Food & Drug Administration. Our present data were within

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the range of the previously reported values of the synthetic colorants in beverages. The

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contents of synthetic colorants in 28 soft drinks in Korean market has been previously

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reported.24 The authors reported that the mean concentration of colorants in the soft drinks

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was 16.68 mg kg-1 with the ranges of 27.77 - 69.45 mg/kg of Sunset Yellow FCF, 0.89 -

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16.50 mg/kg of Tartrazine, 1.61 - 33.60 mg/kg of Allura Red AC, 2.79 - 56.19 mg/kg of

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Amaranth, and 0.21 - 7.20 mg/kg of Brilliant Blue FCF.24 The contents of synthetic colorants

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in four commercial beverages in Korean market has been also previously reported.27 The

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results showed that the mean contents of total synthetic colorants in the 4 beverages was 0.22

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mg kg-1 with the ranges of 0.00 - 2.83 mg/kg of Tartrazine, 0.00 - 0.40 mg/kg of Sunset

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Yellow FCF, 0.00 - 0.58 mg/kg of Brilliant Blue FCF, and 0.00 - 02.13 mg/kg of Allura Red

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AC.27 In a previous report,15 the contents of synthetic colorants in 13 soft drinks in Italian

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market were reported to be in the range of 0.23 - 473.21 mg/L. The contents of synthetic

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colorants in 4 fruit juices in China were reported to be in the range of 0.99 - 11.55 mg/L.28

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The contents of synthetic colorants in a carbonated drink and a fruit-flavored drink in China

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has been reported to be 9.07 and 1.58 mg/kg, respectively.29

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In summary, an analytical approach based on a syringe filtration combined with UHPLC-

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DAD was successfully developed and validated for the ultrafast quantification of nine

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synthetic colorants in beverages. It was found, for the first time, that syringe types and pH of

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the sample solution dramatically affected the recovery of the colorants from the samples. The

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filtration with PVDF membrane syringe filter at pH 7.0 of the sample solution provided the

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highest recovery (92.7-105.9%) of all the 9 synthetic colorants tested. The sample preparation

297

procedure was very simple and took only approximately 1 min. The UHPLC-DAD using core

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shell C18 column was developed for the ultrafast satisfactory separation of the nine colorants.

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The established method provided high linearity of standard calibration curves, low LOD and

300

LOQ, and high precision and accuracy for the determination of nine synthetic colorants. The

301

method was successfully applied to analyze the synthetic colorants in 17 beverages in Korea

302

Market. The total analytical time including the sample preparation and chromatographic

303

operation for the quantification of nine synthetic colorants in beverages was approximately 3

304

min. We believe that this analytical method would be an efficient tool for the rapid analysis of

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synthetic colorants in beverages.

306 307

 ASSOCIATED CONTENT

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The supporting information:

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This material is available free of charge via the Internet at http://pubs.acs.org.

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Table S1. Effect of pH of the Sample Solution on the Recovery Rates of Authentic Colorant

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from the Spiked Non-Colored Sport Drink (1, 4, and 10 mg/L Spiked) with PVDF Syringe

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Filter.

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Table S2. Intra-day Repeatability of Contents of Authentic Colorants in Standard Solutions

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Obtained from 10 Repeated Analysis by the UHPLC-DAD Method

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Table S3. Inter-day Repeatability of Contents of Authentic Colorants Obtained from Six

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Different Day Analysis

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Figure S1. UV/Vis scanning spectra of 9 synthetic tar colorant standards obtained by

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UHPLC-DAD

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 AUTHOR INFORMATION

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Corresponding Author

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*Phone: +82-63-290-1438. Fax: +82-63-290-1435. E-mail: [email protected]

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Notes

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The authors declare no competing financial interest.

326 327

 REFRENCES

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(1) Shen, Y.; Zhang, X.; Prinyawiwatkul, W.; Xu, Z. Simultaneous determination of red and

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yellow artificial food colourants and carotenoid pigments in food products. Food Chem. 2014.

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157, 553-558.

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(2) Olgun, F.A.O.; Ozturk, B.D.; Apak, R. Determination of synthetic food colorants in

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water-soluble beverages individually by HPLC and totally by Ce (IV)-oxidative

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spectrophotometry. Food Anal. Methods. 2012, 5, 1335-1341.

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(3) Amchova, P.; Kotolova H.; Ruda-Kucerova J. Health safety issues of synthetic food

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colorants. Regul. Toxicol. Pharm. 2015, 914-922.

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(4) Mpountoukas, P.; Pantazaki, A.; Kostareli, E.; Christodoulou, P.; Kareli, D.; Poliliou, S.;

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performance liquid chromatography. Food Chem. 2013, 141, 182-186.

445 446

447

Figure 1. Chemical structures of nine synthetic colorant standards.

448 449

Figure 2. UHPLC-DAD chromatograms of mixed nine colorant standards.

450 451

Figure 3. UHPLC-DAD chromatograms of the synthetic colorants in selected beverages

452

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Table 1. Linear Equations of Standard Curves, Retention Time (tR), Detection Wavelength (nm), LOD, and LOQ of Nine Authentic Colorants by the UHPLC-DAD Method

456 Colorant

tR

Detection Wavelength (nm)

Standard curve

LOD (mg/L)

LOQ (mg/L)

Tartrazine

0.345

420

y = 19857x-1212.1

0.14

0.46

Amaranth

0.423

520

y =11168x -1930.7

0.05

0.17

Indigo Carmine

0.486

600

y = 15313x -2.74

0.06

0.19

Ponceau 4R

0.514

520

y =10662x -369.75

0.04

0.13

Sunset Yellow FCF

0.564

480

y = 11085x -318.48

0.06

0.21

Allura Red AC

0.599

520

y = 13551x - 418.13

0.08

0.25

Fast Green FCF

0.701

600

y =43092x+ 917.70

0.15

0.50

Brilliant Blue FCF

0.734

600

y = 22422x - 997.35

0.04

0.14

Erythrosine B

0.905

520

y = 19174x +543.96

0.12

0.40

457 458 459 460 461 462 463 464 465 466 467 468 469

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Table 2. Effects of Syringe Filter Membrane Type on the Recovery Rates of Colorants in the Standard Solutions. Recovery rate (%)1) Compound

472

Nylon

PVDF

Cellulose

PES

Tartrazine

61.7±0.3c

99.2±0.5ab

98.7±0.4b

100.1±0.6a

Amaranth

46.7±0.9b

101.9±0.2a

101.2±0.3a

100.5±0.7a

Indigo Carmine

55.8±1.0d

102.1±0.7a

95.3±0.5c

99.7±1.0b

Ponceau 4R

42.5±0.6b

99.2±0.3a

99.8±0.4a

100.2±0.2a

Sunset Yellow FCF

49.8±0.5c

99.3±0.9a

96.9±0.9b

98.4±0.9ab

Allura Red AC

32.1±0.4d

100.9±0.7a

98.7±0.4b

94.6±0.8c

Fast Green FCF

57.5±0.9c

97.9±0.1a

90.0±1.0b

95.0±0.6a

Brilliant Blue FCF

61.2±0.4d

98.5±0.9b

90.2±0.8c

104.3±0.7a

Erythrosine B

0

99.6±0.6a

98.6±0.5a

24.3±0.7b

1)

The data with same superscript within the same row are not statistically different at α=0.05.

473

474

475

476

477

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478 479

Table 3. Contents of Synthetic Colorants in Beverages Containing Synthetic Colorants as Determined by the Established UHPLC Following Simple Syringe Filtration Mean content Sample

Colorants

RSD(%) (mg/L)

B-1

Tartrazine

10.81

0.13

Sunset Yellow FCF

15.18

0.30

Allura Red AC

1.00

4.68

Tartrazine

3.36

0.23

Sunset Yellow FCF

1.17

0.41

Tartrazine

5.02

0.50

Brilliant Bule FCF

1.43

2.57

B-4

Tartrazine

1.58

0.09

B-5

Tartrazine

1.56

0.48

Allura Red AC

3.36

1.30

Tartrazine

1.63

1.29

Allura Red AC

10.56

0.82

Tartrazine

0.73

5.05

Brilliant Bule FCF

2.73

0.28

B-8

Sunset Yellow FCF

13.72

0.46

B-9

Sunset Yellow FCF

57.98

0.20

B-10

Allura Red AC

29.27

0.54

Brilliant Bule FCF

6.92

2.90

Allura Red AC

56.23

0.79

B-2

B-3

B-6

B-7

B-11

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Journal of Agricultural and Food Chemistry 25

B-12

Brilliant Bule FCF

3.51

0.97

B-13

Brilliant Bule FCF

3.74

0.65

B-14

Allura Red AC

17.11

1.16

Brilliant Bule FCF

1.14

0.16

Brilliant Bule FCF

6.07

0.40

Allura Red AC

31.97

0.36

B-16

Brilliant Bule FCF

3.38

0.51

B-17

Allura Red AC

0.93

5.01

B-15

480

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Fig 1

Allura Red AC

Amaranth

Erythrosine B

Fast Green FCF

Ponceau

Sunset Yellow FCF

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Brilliant Blue FCF

Indigo Carmine

Tartazine

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Journal of Agricultural and Food Chemistry

Fig 2

Dataf ile Name:151023)9mix_10ppm.lcd mAU 300 Ch1-520nm,4nm Ch2-420nm,4nm Ch3-480nm,4nm Ch4-600nm,4nm 200

Sunset Yellow FCF

Tartrazine

Ponceau 4R Indigo Carmine

Fast Green FCF

Allura Red AC

Erythrosine B

Brilliant Blue FCF

Amaranth

100

0 0.0

0.1

0.2

0.3

0.4

0.5

0.6

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0.7

0.8

0.9

min

Journal of Agricultural and Food Chemistry

Fig 3

Sunset yellow FCF Tartrazine B-1 Allura Red FCF

Allura Red AC

Peak intensity

B-10

Brilliant Blue FCF

Allura Red AC B-11

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Ultrafast Analysis of Synthetic Colorants in Beverages Simple Treatment for High Recovery

DatafUltrafast ile Name:151023)9mix_10ppm.lcd Separation mAU 300 Ch1-520nm,4nm Ch2-420nm,4nm Ch3-480nm,4nm Ch4-600nm,4nm 200

100

1 min pH 7.0 adjustment

0

PVDF Syringe filter

0.0

0.1

0.2

0.3

0.4

0.5

0.6

UHPLC-DAD

0.7

0.8

0.9

min

0.94 min

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