TECHNOLOGIES TO IMPROVE THE STABILITY OF POLYPHENOLIC COMPOUNDS IN DRUG DISCOVERY (REVIEW)

Natural polyphenols are valuable compounds possessing scavenging properties towards radical oxygen species, and complexing properties towards proteins. Therefore, phenolic compounds have attracted increasing attention as potential agents for preventing and treating many oxidative stress-related diseases, such as cardiovascular diseases, cancer, ageing, diabetes mellitus and neurodegenerative diseases. Polyphenolic compounds are characterized by a very high sensitivity to several environmental factors including physical, chemical and biological conditions and can be oxidized very quickly with a considerable loss in activity. Development of new approaches to stabilisation and protection of these compounds from degradation and therefore to improve their biological activity is of interest. The literature describes many encapsulation methods, many of which have been successfully used for plant polyphenols. This review provides some plant polyphenols and their basic chemical and biological properties as well as methods of encapsulating polyphenols, which are divided into physical, physico-chemical, chemical methods and other methods of stabilization.

polyphenol, antioxidant, bioavailability, encapsulation

1. J.P. Spencer, M.M. Abd El Mohsen, A.M. Minihane, J.C. Mathers. Biomarkers of the intake of dietary polyphenols: strengths, limitations and application in nutrition research // Br J Nutr. 2008. № 99. P. 12.

2. I.R. Redovnikovic, K. Delonga, S. Mazor , V. Dragovic-Uzelac , M. Caric and J. Vorkapic-Furac. Polyphenolic Content and Composition and Antioxidative Activity of Different Cocoa Liquors // Czech J. Food Sci. 2009. № 5: 330-337.

3. M. D’Archivio, C. Filesi, R. Di Benedetto, R. Gargiulo, C. Giovannini, R. Masella. Polyphenols, dietary sources and bioavailability // Ann Ist super Sanita. 2007. V. 43, № 4. P. 348.

4. M. Lamprecht. Antioxidants in Sport Nutrition. © 2015 by Taylor & Francis Group, LLC, 2015.

5. S. Kuriyama; T. Shimazu; K. Ohmori; N. Kikuchi; N. Nakaya; Y. Nishino; Y. Tsubono; I.Tsuji. Green tea consumption and mortality due to cardiovascular disease, cancer, and all causes in Japan: The Ohsaki study // JAMA 2006. № 296. Р. 1255-1265.

6. H. Checkoway; K. Powers; T. Smith-Weller; G.M. Franklin; W.T. Longstreth Jr.; P.D. Swanson. Parkinson’s disease risks associated with cigarette smoking, alcohol consumption, and caffeine intake // Am. J. Epidemiol. 2002. № 155. Р. 732-738.

7. T.L. Zern; R.J. Wood; C. Greene; K.L. West; Y. Liu; D. Aggarwal; N.S. Shachter; M.L. Fernandez. Grape polyphenols exert a cardioprotective effect in pre- and postmenopausal women by lowering plasma lipids and reducing oxidative stress // J. Nutr. 2005. № 135. Р. 1911-1917.

8. Y.J. Jeong; Y.J. Choi; H.M. Kwon; S.W. Kang; H.S. Park; M. Lee; Y.H. Kang. Differential inhibition of oxidized LDL-induced apoptosis in human endothelial cells treated with different flavonoids // Br. J. Nutr. 2005. № 93. Р. 581-591.

9. B. Fuhrman; N. Volkova; R. Coleman; M. Aviram. Grape powder polyphenols attenuate atherosclerosis development in apolipoprotein E deficient (E0) mice and reduce macrophage atherogenicity // J. Nutr. 2005. № 135. Р. 722-728.

10. G.P. Hubbard; S. Wolffram; R. de Vos; A. Bovy; J.M. Gibbins; J.A. Lovegrove. Ingestion of onion soup high in quercetin inhibits platelet aggregation and essential components of the collagen-stimulated platelet activation pathway in man: A pilot study // Br. J. Nutr. 2006. № 96. Р. 482-488.

11. J. Hallund; S. Bugel; T. Tholstrup; M. Ferrari; D. Talbot; W.L. Hall; M.Reimann; C.M. Williams; N. Wiinberg. Soya isoflavone-enriched cereal bars affect markers of endothelial function in postmenopausal women // Br. J. Nutr. 2006. № 95. Р. 1120-1126.

12. J. Hodgson; K. Croft. Dietary flavonoids: Effects on endothelial function and blood pressure // J. Sci. Food Agric. 2006. № 86. Р. 2492-2498.

13. M. Balu, P. Sangeetha, D. Haripriya, C. Panneerselvam. Rejuvenation of antioxidant system in central nervous system of aged rats by grape seed extract // Neurosci Lett 2005. V. 383(3). Р. 295-300.

14. N.G. Baydar, O. Sagdic, G. Ozkan, S. Cetin. Determination of antibacterial effects and total phenolic contents of grape (Vitis vinifera) seed extracts // Int J Food Sci 2006. V. 41(7). Р. 799.

15. H.J. Jung, I.A. Hwang, W.S. Sung, H. Kang, B.S. Kang, Y.B. Seu, et al. Fungicidal effect of resveratrol on human infectious fungi // Arch Pharm Res 2005. V. 28(5). Р. 557-60.

16. T. de Bruyne, L. Pieters, M. Witvrouw, E. de Clercq, D.V. Berghe, A.J. Vlietinck. Biological evaluation of proanthocyanidin dimers and related polyphenols // J Nat Prod 1999. V. 62(7). Р. 954-8.

17. J.H. Chávez, P.C. Leal, R.A. Yunes, R.J. Nunes, C.R.M.Barardi, A.R.Pinto, et al. Evaluation of antiviral activity of phenolic compounds and derivatives against rabies virus. Vet Microbiol 2006. V. 116(1-3). Р. 53-9.

18. T.S. Hudson, D.K. Hartle, S.D. Hursting, N.P. Nunez, T.T.Y. Wang, H.A. Young, et al. Inhibition of prostate cancer growth by muscadine grape skin extract and resveratrol through distinct mechanisms // Cancer Res 2007. V. 67(17). Р. 8396-405.

19. M.C. Lazzè , R. Pizzala, F.J.G. Pecharromán, P.G. Garnica, J.M.A. Rodriguez, N. Fabris, et al. Grape waste extract obtained by supercritical fluid extraction contains bioactive antioxidant molecules and induces antiproliferative effects in human colon adenocarcinoma cells // J Med Food 2009. V. 12(3). Р. 561-8.

20. L. Gamet-Payrastre, S. Manenti, M.P. Gratacap, J. Tulliez, H. Chap, B Payrastre. Flavonoids and the inhibition of PKC and PI 3-kinase // Gen Pharmacol 1999. V. 32(3). Р. 279-86.

21. T. Richard, D. Lefeuvre, A. Descendit, S. Quideau, J.P. Monti. Recognition characters in peptide-polyphenol complex formation // Biochim Biophys Acta 2006. V. 1760(6). Р. 951-8.

22. E-Q. Xia, G-F. Deng, Y-J.Guo, H-B. Li. Biological activities of polyphenols from grapes // Int J Mol Sci 2010. V. 11(2). Р. 622-46.

23. R.R. Watson, V.R. Preedy, Sh. Zibadi. Polyphenols in Human Health and Disease, 1st Edition. Academic Press-Elsevier, 2013, 1427.

24. K.G.H. Desai, H.J. Park. Recent developments in microencapsulation of food ingredients // Dry Technol 2005. V. 23(7). P. 1361-94.

25. Picot, C. Lacroix. Production of multiphase water-insoluble microcapsules for cell microencapsulation using an emulsification/ spray-drying technology // J Food Sci 2003. V. 68(9). P. 2693-700.

26. А. Munin, F. Edwards-Lévy. Encapsulation of natural polyphenolic compounds; a review // Pharmaceutics 2011. V. 3(4). P. 793-829.

27. А. Gharsallaoui, G. Roudaut, O. Chambin, A. Voilley, R Saurel. Applications of spraydrying in microencapsulation of food ingredients: an overview // Food Res Int. 2007. V. 40(9). P. 1107-21.

28. B.F. Gibbs, S. Kermash, I. Alli, C.N. Mulligan. Encapsulation in the food industry: a review // Int J Food Sci Nutr. 1999. V. 50(3). P. 213-24.

29. M.B. Roberfroid, N.M. Delzenne. Dietary fructans // Annu. Rev. Nut.r. 1998. V. 18 P. 117-43.

30. D. Sun-Waterhouse, S.S. Wadhwa, G.I.N. Waterhouse. Spray-drying microencapsulation of polyphenol bioactives: a comparative study using different natural fibre polymers as encapsulants // Food Bioprocess Technol 2012. Available from: http://dx.doi.org/10.1007/s11947-012-0946-y (дата обращения 31.10.2016).

31. D.P. Makris, G. Boskou, N.K. Andrikopoulos. Recovery of antioxidant phenolics from white vinification solid by-products employing // water/ethanol mixtures. Bioresource Technol. 2007. V. 98(15). P. 2963-7.

32. А. Munin, F. Edwards-Levy. Encapsulation of Natural Polyphenolic Compounds: a Review // Pharmaceutics. 2011. V. 3. P. 793-829.

33. P. York, U.B. Kompella, B.Y. Shekunov, [ed.]. Supercritical fluid technology for drug product development // New York, Basel: Marcel Dekker, Inc., 2004. PP. 44-53, 504.

34. P.M. Gallagher, M.P. Coffey, V.J. Krukonis, W.W. Hillstrom. Gas Anti-Solvent Recrystallization of RDX; Formation of Ultra-fine Particles of a Difficult-to-Comminute Explosive // J. of Supercritical Fluids. 1992. Т. 5. P. 130.

35. А. Visentin, S. Rodriguez-Rojo, A. Navarrete, D. Maestri, M.J. Cocero. Precipitation and encapsulation of rosemary antioxidants by supercritical antisolvent process // J Food Eng. 2012. V. 109(1). P. 9-15.

36. J.J. Escobar-Chavez, M. Lopez-Cervantes, A. Naik, Y.N. Kalia, D. Quintanar-Guerrero, A. Ganem-Quintanar. Applications of thermoreversible Pluronic F-127 gels in pharmaceutical formulations // J Pharm Pharmaceut Sci. 2006. V. 9(3). P. 339-58.

37. S. Gouin. Microencapsulation: industrial appraisal of existing technologies and trends // Trends Food Sci Tech. 2004. V. 15(7-8). P. 330-347.

38. S. Xiong, L.D. Melton, A.J. Easteal, D. Siew. Stability and antioxidant activity of black currant anthocyanins in solution and encapsulated in glucan gel // J Agric Food Chem. 2006. V. 54(17). P. 6201-8.

39. L. Deladino, P.S. Anbinder, A.S. Navarro, M.N. Martino. Encapsulation of natural antioxidants extracted from Ilex paraguariensis // Carbohydr Polym. 2008. V. 71(1). P. 126-34.

40. T.F. Vandamme, D. Poncelet, P. Subra-Paternault. Microencapsulation: des Sciences aux Technologies. - Paris,: Lavoisier Tec & Doc, 2007.

41. J. Liang, F. Li, Y. Fang, W. Yang, X. An, L. Zhao, et al. Synthesis, characterization and cytotoxicity studies of chitosan-coated tea polyphenols nanoparticles // Coll Surf B Biointerf. 2011. V. 82 (2). P. 297-301.

42. S. Friberg, K. Larsson, J. Sjoblom. Food Emulsions. 4th ed. - New York: Marcel Dekker, 2004.

43. M. Sessa, A.A. Casazza, P. Perego, R. Tsao, G. Ferrari, F. Donsi. Exploitation of polyphenolic extracts from grape marc as natural antioxidants by encapsulation in lipid-based nanodelivery systems // Food Bioprocess Technol 2012. Available from: http://dx.doi.org/10.1007/s11947-012-0911-9 (дата обращения 31.10.2016).

44. E. Cabane, X. Zhang, K. Langowska, CG. Palivan, W. Meier. Stimuli-responsive polymers and their applications in nanomedicine // Biointerphases. 2012. V. 7(1-4). P. 1-27.

45. I.C. Chis, M.I. Ungureanu, A. Marton, R. Simedrea, A. Muresan, I.D. Postescu, et al. Antioxidant effects of a grape seed extract in a rat model of diabetes mellitus // Diab Vasc Dis Res. 2009. V. 6 (3). P. 200-2-004.

46. T.F. Vandamme, D. Poncelet, P. Subra-Paternault. Microencapsulation: des Sciences aux Technologies.- Paris: Lavoisier Tec & Doc, 2007.

47. М.С. Сокуренко, Н.Л. Соловьёва, С.П. Кречетов, С.А. Бруновленский-Богоявленский. Использование циклодекстринов с целью повышения биодоступности полифенольных соединений // Евразийский союз учёных. 2016. № 3(24), С. 155-156.

48. S. Bisht, M.A. Khan, M. Bekhit, H. Bai, T. Cornish, M.Mizuma, et al. A polymeric nanoparticle formulation of curcumin (NanoCurct) ameliorates CCl4-induced hepatic injury and fibrosis through reduction of pro-inflammatory cytokines and stellate cell activation // Lab Invest. 2011. V. 91(9). P. 1383-95.