Determination of cinnamic acid in human urine by flow injection chemiluminescence

Fan, Xuemei; Wang, Shumin; Su, Zhikui; Chen, Fengying; Liu, Yanfeng; Liu, Ping; Zheng, Xingwang; Cui, Fengling

doi:10.1590/S0100-40422011000800020

Abstract

It was found that cinnamic acid can react with potassium permanganate in the acidic medium and produce chemiluminescence, which was greatly enhanced by glyoxal. Under the optimum conditions, the linear range for the determination of cinnamic acid was 1.0×10-8 to 1.0×10-4 mol L-1 with a detection limit of 8.0×10-9 mol L-1, the relative standard deviation was 1.7% for 2.0×10-6 mol L-1 cinnamic acid solution in nine repeated measurements. This method was found to be novel0simple0fast and sensitive, it was successfully applied to the determination of cinnamic acid in human urine. Furthermore, the possible reaction mechanism was also discussed.

flow injection chemiluminescence; potassium permanganate; cinnamic acid

ARTIGO

Determination of cinnamic acid in human urine by flow injection chemiluminescence

Xuemei FanI, ^* * e-mail: fanxuemei527@163.com ; Shumin Wang^I; Zhikui Su^I; Fengying Chen^I; Yanfeng Liu^I; Ping Liu^I; Xingwang Zheng^II; Fengling Cui^III

^IDepartment of Chemistry and Chemical Engineering, Shuoluo University, Shuoluo 726000, P. R. China

^IISchool of Chemistry and Material Science, Shaanxi Normal University, Xi'an 710062, P. R. China

^IIICollege of Chemistry and Environment Science of Henan Normal University, Xinxiang 453007, P. R. China

ABSTRACT

It was found that cinnamic acid can react with potassium permanganate in the acidic medium and produce chemiluminescence, which was greatly enhanced by glyoxal. Under the optimum conditions, the linear range for the determination of cinnamic acid was 1.0×10^-8 to 1.0×10^-4 mol L^-1 with a detection limit of 8.0×10^-9 mol L^-1, the relative standard deviation was 1.7% for 2.0×10^-6 mol L^-1 cinnamic acid solution in nine repeated measurements. This method was found to be novel0simple0fast and sensitive, it was successfully applied to the determination of cinnamic acid in human urine. Furthermore, the possible reaction mechanism was also discussed.

Keywords: flow injection chemiluminescence; potassium permanganate; cinnamic acid.

INTRODUCTION

Cinnamic acid is an important substance because it is widely used in perfume, food, photographic, polymer and pharmaceutical industries, as well as for clinical and toxicological Studies.¹ Until now, many methods have been reported for its determination, such as titrimetry,^2,3 differential-pulse polarography,⁴ spectrophotometry,⁵ mass spectrometry,⁶ HPLC,⁷ electrokinetic capillary chromatography,⁸ capillary electrophoresis,⁹ gas chromatography¹⁰ and liquid chromatography¹¹. However, there are many disadvantages over these methods, such as long-response time, reagent consumption, complicated operation, etc.¹²

Chemiluminescence (CL) is defined as the emission of electromagnetic radiation (usually in the visible or near-infrared region) produced by a chemical reaction. Since the appearance of the highly sensitive photomultiplier tube in the 1950s, CL has been known as a powerful and important analytical technique for its advantages such as higher sensitivity, lower detection limits, wider linear ranges and simpler instrument (no excitation light source and no spectroscope).¹³ Though the CL have many advantages, normally the amount of energy released during a chemical reaction dissipates as heat, therefore the chemiluminescence reagents having been investigated was limited. At present, the chemiluminescence reagents named luminol,^14-16 lucigen,^17,18 peroxidate,¹⁹ tris(2,2^,-bipyridyl)ruthenium(II)^20,21 and potassium permanganate^22-25 have been widely used in analytical chemistry. Up until now, only one article had been published for the determination of cinnamic acid by CL method, and it was based on Ru(bipy)₃²⁺-KMnO₄ System.²⁶ However, this method needed expensive reagent, furthermore, the linear ranges was narrower. Consequently, development of a more novel CL detection procedure for cinnamic acid analysis should be of interest.

In our laboratory, glyoxal was found to enhance the CL emission intensity by the reaction of cinnamic acid with KMnO₄ in sulfuric acid medium. Based on this reaction, we developed a novel flow injection chemiluminescence method for the determination of cinnamic acid. Compared with the previous reported chemiluminescence method, the present method was inexpensive, sensitive and showed wider calibration ranges. Furthermore, the possible reaction mechanism was also discussed in this paper.

EXPERIMENTAL

Apparatus

The IFFM-E flow injection CL analyzer (Xi'an Remex Electronic Instrument High-Tech Ltd., China) was equipped with an automatic injection system and a detection system. The schematic diagram of the CL flow system employed was shown in Figure 1. PTFE tube (0.8 mm i.d.) was used to connect all of the components in the flow system. The photomultiplier tube was operated at -600 V, the flow cell was a coil of glass tube that was positioned in front of the detection window of the PMT. The CL signal was treated with a personal computer.

Reagents

All chemical reagents were of analytical grade and were purchased from Xi'an Chemical Reagent Factory(Xi'an, China). All solutions were made in ultrapure water puriûed in a Milli-Q system (Millipore, Sartorius, Germany).

The stock standard solution (1.00×10^-3 mol L^-1) of cinnamic acid was prepared by dissolving 0.0148 g cinnamic acid in water. Potassium permanganate stock solution (1.0×10^-2 mol L^-1) was prepared by dissolving potassium permanganate in water. Working solutions were prepared by appropriate dilution of stock solution with water before use. glyoxal solution (4%, v/v) was prepared in water.

Analytical procedures

As shown in Figure 1, at first, the reagent stream KMnO₄ solution and H₂SO₄ solution used as the oxidizer mixed with cinnamic acid, then, the mixture was injected into glyoxal solution. At last, the mixed solution was transferred into CL cell, and the CL signal I which was proportional to the concentration of corresponding cinnamic acid was recorded.

RESULTS AND DISCUSSION

Kinetic curves of CL reaction

The kinetic curve was tested with a static system in the absence and presence of glyoxal, the typical CL kinetic curve was shown in Figure 2. It can be seen that the CL reaction of cinnamic acid and KMnO₄ in sulfuric acid solution was so rapid that the CL intensity reached a maximum at 1.1 s. It was also indicated that the CL intensity greatly enhanced in the presence of glyoxal.

Optimization of experimental conditions

Analytical procedure

KMnO₄ act only as the oxidant for the determination of cinnamic acid in this CL system. In order to achieve the optimum procedure of determination, two analytical procedures (Figure 1) were investigated. Under the same conditions, we found that the former obtained the greater CL emission intensity than the latter. Therefore, the 1.1 procedure was used subsequently in this study.

Effect of acid type and concentration

It was observed that the CL signal of KMnO₄-cinnamic acid system was stronger in acid solution than in neutral or basic solution. Four different acids of different concentrations were used as the mediums, the results were shown in Table 1. The results showed maximum CL intensity was obtained with 0.05 mol L^-1 H₂SO₄. The effect of H₂SO₄ concentration on the CL intensity of this system was shown in Figure 3.

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Effect of KMnO₄ concentration

KMnO₄ is the important oxidant for the determination of cinnamic acid in this CL system. In order to investigate the effect of the concentration of KMnO₄ on the CL intensity. The effect of 1.0×10^-5 to 1.0×10^-3 mol L^-1 KMnO₄ was examined, and the results was shown in Figure 4. It can be observed that the CL intensity increased with increasing KMnO₄ concentration up to 5.0×10^-4 mol L^-1. Larger concentration of KMnO₄ could lower the CL intensity. Thus, 5.0×10^-4 mol L^-1 KMnO₄ was used in the work.

Effect of glyoxal concentration

The primary investigation found that glyoxal could enhance the CL intensity of cinnamic acid with KMnO₄ in acidic medium. The effect of the concentration of glyoxal on the CL intensity was studied in the range of 0.5-10% and the result was shown in Figure 5. It showed that the CL intensity increased with increasing glyoxal concentration up to 4% (V/V). When the concentration of glyoxal continued increasing, the CL intensity keeped constant basically. Therefore, 4% (V/V) glyoxal was used in subsequent experiments.

Effect of surfactants

The effect of some surfactants (non-ionic PEG, cationic CTMAB and anionic SDBS) on the CL intensity was tested. The results showed that SDBS lowered the CL intensity about for seven times, CTMAB and PEG had no effect on the analytical signal. Therefore, these surfactants were not used for the further work.

Effect of flow rate

The flow rates of peristaltic pump P₁ and P₂ were investigated. It was found that the CL intensity increased with increasing the flow rate of P₁ and the CL intensity reached the maximum at 3.5 mL min^-1 and then keeped constant. The CL intensity also increased with the increasing flow rate of P₂ and the CL intensity reached the maximum at 2.0 mL min^-1. So 3.5 and 2.0 mL min^-1 were, respectively, selected for the flow rates of P₁ and P₂.

Linear response range, detection limit and precision

Under the above optimum conditions, the CL intensity versus cinnamic acid concentration was measured. The regression equation, correlation coefficients and the detection limit were summarized in Table 2. The reproducibility was examined using 2.0×10^"6 mol L^-1 cinnamic acid (n = 9) and the relative standard deviation was 1.7 %.

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Interference

Under the selected experimental conditions, the interference tests of some foreign species were performed. The results showed that 1000-fold K⁺, Na⁺, NO₃^-, EDTA, 800-fold Zn²⁺, Ca²⁺, Cd²⁺, Al³⁺, Mg²⁺, Ni²⁺, Pb²⁺, Ba²⁺, NH₄⁺, CO₃^2", SO₄^2", PO₄^3", 500-fold Cl^", Fe²⁺, Cu²⁺, Cr³⁺, Fe³⁺, Co²⁺, starch, fructose glucose, lactose, 100-fold urea, uric acid, 50-fold methanol, ethanol and two fold ascorbic acid were not interfered with the determination of 2.0×10^"6 mol L^-1 cinnamic acid at the confidence level of 95%. So, the method had a high selectivity.

Application

The human urine sample was obtained from a healthy person and the proposed method was directly applied to the determination of cinnamic acid in human urine without any retreatment. In order to decrease the background of the determination, the sample was diluted for 25-fold. The spiked samples were prepared by mixing the standard and the diluted sample. By this method, the determination results (Table 3) were close to those obtained by the LC methods.²⁷ Compared with the previous reported method for the determination of cinnamic acid, the advantages of using the present method had a good reproducibility and sensitivity.

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Possible reaction mechanism

It was reported that KMnO₄ could react with some reductants in the presence of formaldehyde to produce¹O₂¹O₂ (¹³%g¹³%g), a complex oxygen molecule of single state, which could transform into ³O₂(³Σg), a triplet state oxygen. During the transformation, it could produce CL and the formaldehyde could accelerate oxidation reaction rate.²⁸ Thus, the cinnamic acid could also react with KMnO₄ to produce CL and the CL reaction could be accelerated by glyoxal.

Based on the above discussions, the possible reaction mechanism was suggested as following:

MnO₄^- + glyoxal + H⁺ + cinnamic acid →¹O₂ (¹Δg) + Mn(II-IV) +H₂O + products

2¹O₂ (¹Δg)→ ¹O₂¹O₂(¹Δg¹Δg) ¹O₂¹O₂(¹Δg¹Δg)→2³O₂(³Σg) + hΝ

CONCLUSION

A novel flow injection analysis method has been proposed, it was based on that cinnamic acid can react with potassium permanganate in the acidic medium and produce chemiluminescence, which was greatly enhanced by glyoxal. Comparing to the previous methods for determination of cinnamic acid, the proposed method showed its advantages in simplicity, sensitivity, selectivity and avoided expensive reagent consumption. This method was successfully used in the determination of cinnamic acid in human urine.

ACKNOWLEDGEMENTS

This project was financially supported by the Science Foundation of Shuoluo College, P. R. China (No. 10SKY015) and National Natural Science Foundation of China (No. 30970696).

Recebido em 21/2/11; aceito em 11/4/11; publicado na web em 10/6/11

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*

e-mail:

fanxuemei527@163.com

Publication Dates

Publication in this collection
06 Oct 2011
Date of issue
2011

History

Received
21 Feb 2011
Accepted
11 Apr 2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Grayson, M.; Encyclopedia of Chemical Technology, Wiley: New York, 1981.

[2] 2. Majer, J. R.; Ellis, M; Anal. Chim. Acta 1984, 165, 237.

[3] ³
Chinese Pharmacopoeia, People Hygiene Press : Beijing, 1995, chap. 2.

[4] 4. Ferreira, V. S.; Melios, C. B.; Zanoni, M. V.; Stradiotto, N. R.; Analyst 1996, 121, 263.

[5] 5. Bounias, M.; Daurade, M. H.; Lizzi, Y.; Analysis 1989, 17, 201.

[6] 6. Zhang, J.; Chen, M.; Ju, W. Z.; Liu, S. J.; Xu, M. J.; Chu, J. H.; Wu, T.; J. Pharm. Biomed. Anal. 2010, 51, 685.

[7] 7. Sladkovský, R.; Solich, P.; Opletal, L.; J. Pharm. Biomed. Anal. 2001, 24, 1049.

[8] 8. Lu, Y.; Wu, C.; Yuan, Z.; Fitoterapia 2004, 75, 267.

[9] 9. Li, L. J.; Feng, J.; Chen, W.; Chinese J. Anal. Chem 2007, 35, 401.

[10] 10. Biemer, T. A.; Asral, N.; Albanese, J. A.; J. Chromatogr 1992, 623, 395.

[11] 11. Cheng, J.; Li, Y. S.; Roberts, R. L.; Walker, G.; Talanta 1997, 44, 1807.

[12] 12. Qu, P.; Yan, S. C.; Lu, H.; Lu, Z. H.; Microchim. Acta 2008, 163, 321.

[13] 13. Li, B. X.; Guo, L. L.; Xu, C. L.; Ma, L. M.; Spectrochim. Acta, Part A 2008, 71, 892.

[14] 14. Lu, J. Q.; He, W. W.; Zhou, X. W.; Chin. Chem. Lett. 2006, 17, 1233.

[15] 15. Ensafi, A. A.; Khayamian, T.; Hasanpour, F.; J. Pharm. Biomed. Anal 2008, 48, 140.

[16] 16. Nalewajko, E.; Wiszowata, A.; KojŁo, A.; J. Pharm. Biomed. Anal 2007, 43, 1673.

[17] 17. Uketa, H.; Sarker, A. K.; Kawana, D.; Sawamura, M.; Anal. Chim. Acta 2001, 438, 137.

[18] 18. Afanasev, I. B.; Ostrakhovitch, E. A.; Mikhalchik, E. V. M.; Korkina, L. G.; Luminescence 2001, 16, 305.

[19] 19. Nakashima, K.; Kawaguehi, S.; Givens, R. S.; Anal. Sci. 1990, 6, 833.

[20] 20. Anastos, N.; Barnett, N. W.; Lewis, S. W.; Gathergood, N. S. J.; NoelSims, D.; Talanta 2005, 67, 354.

[21] 21. Gorman, B. A.; Barnett, N. W.; Anal. Chim. Acta 2005, 541, 119.

[22] 22. Barnett, N. W.; Hindson, B. J.; Jones, P.; Smith, T. A.; Anal. Chim. Acta 2002, 451, 181.

[23] 23. Zhuang, Y. F.; Song, H. L.; J. Pharm. Biomed. Anal. 2007, 44, 824.

[24] 24. Li, L. N.; Li, N. B.; Luo, H. Q.; Anal. Sci. 2005, 21, 963.

[25] 25. Zhang, D. Y.; Ma, Y. J.; Zhou, M.; Li, L.; Chen, H.; Anal. Sci. 2006, 22, 183.

[26] 26. Han, H. Y.; He, Z. K.; Zeng, Y. E.; Anal. Chim. Acta 1999, 402, 113.

[27] 27. Luo, G. M.; Yang, W. L.; Lai, X. W.; Xie, S. X.; Liu, X. W.; YaowuFenxi Zazhi 1996, 16, 338.

[28] 28. He, Y. H.; Lu, J. R.; Chin. J. Anal. Chem. 2002, 30, 598.

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Determination of cinnamic acid in human urine by flow injection chemiluminescence

Abstract

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