DISCRIMINATION OF BRANDS OF STRONG AROMA TYPE LIQUORS USING SYNCHRONOUS FLUORESCENCE SPECTROSCOPY AND CHEMOMETRICS METHODS

The application of synchronous fluorescence spectroscopy combined with chemometrics using pretreated spectra was explored to develop a rapid, low-cost, and nondestructive method for discriminating between brands of different strong aroma type liquors. Principal component analysis, partial least square discriminant analysis, support vector machine, and back-propagation artificial neural network techniques were used to classify and predict the brands of liquor samples. Compared with the other models, the SVM model achieved the best results, with an identification rate of 100% for the calibration set, and 96.67% for the prediction set. The overall results showed that synchronous fluorescence spectroscopy with an efficient chemometrics method can be used successfully to identify different brands of liquor.

китайский ликер, синхронная флуоресцентная спектроскопия, распознавание напитков, хемометрия распознавания, chinese liquor, synchronous fluorescence spectroscopy, discrimination of liquors, chemometrics of discrimination

1. W. Fan, M. C. Qian, J. Agric. Food Chem., 54, 2695-2704 (2006).

2. Y. Xu, D. Wang, W. Fan, X. Mu, J. Chen, Adv. Biochem. Eng. Biotechnol., 122, 189-233 (2010).

3. Y. Ma, D. Huo, H. Qin, C. Shen, P. Yang, C. Hou, J. Appl. Spectrosc., 84, 361-368 (2017).

4. P. Cheng, W. Fan, Y. Xu, Food Res. Int., 54, 1753-1760 (2013).

5. P. Cheng, W. Fan, Y. Xu, Food Control, 35, 153-158 (2014).

6. W. Fan, M.C. Qian, J. Agric. Food Chem., 53, 7931-7938 (2005).

7. P. Wang, Z. Li, T. Qi, X. Li, S. Pan, Food Chem., 169, 230-240 (2015).

8. H. Qin, D. Huo, L. Zhang, L. Yang, S. Zhang, M. Yang, C. Shen, C. Hou, Food Res. Int., 45, 45-51 (2012).

9. M. Liu, X. Han, K. Tu, L. Pan, J. Tu, L. Tang, P. Liu, G. Zhan, Q. Zhong, Z. Xiong, Food Control, 26, 564-570 (2012).

10. Q. Zhang, C. Xie, S. Zhang, A. Wang, B. Zhu, L. Wang, Z. Yang, Sens. Actuators B: Chem., 110, 370-376 (2005).

11. Z. Li, P. Wang, C. Huang, H. Shang, S. Pan, X. Li, Food Anal. Methods, 7, 1337-1344 (2014).

12. V. Uríčková, J. Sádecká, Spectrochim. Acta, A, 148, 131-137 (2015).

13. D. Dong, W. Zheng, W. Wang, X. Zhao, L. Jiao, C. Zhao, Food Chem., 155, 45-49 (2014).

14. H. Qiao, W. Zhang, W. Wang, J. Biosci. Bioeng., 115, 405-411 (2013).

15. Y. Wan, F. Pan, M. Shen, Spectrochim. Acta, A, 96, 605-610 (2012).

16. D. Patra, A. K. Mishra, Trends Anal. Chem., 21, 787-798(2002).

17. F. Cui, Q. Zhang, X. Yao, H. Luo, Y. Yang, L. Qin, G. Qu, Y. Lu, Pestic. Biochem. Phys., 90, 126-134 (2008).

18. J. Sádecká, J. Tóthová, P. Májek, Food Chem., 117, 491-498 (2009).

19. J. Sádecká, V. Uríčková, K.Hroboňová, P. Májek, Food Anal. Methods, 8, 58-69 (2015).

20. M. Tomková, J. Sádecká, K. Hroboňová, Food Anal. Methods, 8, 1258-1267 (2015).

21. J. Sádecká, M. Jakubíková, P. Májek, A. Kleinová, Food Chem., 196, 783-790 (2016).

22. J. Tan, R. Li, Z. Jiang, Food Chem., 184, 30-36 (2015).

23. H. Hotelling, J. Educ. Psychol., 24, 417-520 (1933).

24. W. Li, L. Bagnol, M. Berman, R. A. Chiarella, M. Gerber, Int. J. Pharm., 380, 49-54 (2009).

25. P. Geladi, B. Kowalski, Anal. Chim. Acta, 185, 1-17 (1986).

26. M. Barker, W. Rayens, J. Chemometr., 17, 166-173 (2003).

27. C. Cortes, V. Vapnik, Mach. Learn., 20, 273-297 (1995).

28. U. Thissen, M. Pepers, B. Üstün, W.J. Melssen, L. M. C. Buydens, Chemometr. Intell. Lab. Syst., 73, 169-179 (2004).

29. S. S. Keerthi, C. Lin, Neural Comput., 15, 1667-1689 (2003).

30. R. H. Nielsen, Proc. Int. Joint Conf. Neural Networks, IEEE Press, 593-605 (1989).

31. J. J. More, Lect. Notes Math., 630, 105-116 (1978).

32. Y. Liu, X. Luo, Z. Shen, J. Lu, X. Ni, Opt. Rev., 13, 303-307 (2006).

33. S. Wagner, K. Scholz, M. Donegan, L. Burton, J. Wingate, W. Volkel, Anal. Chem., 78, 1296-1305 (2006).