Fouling evaluation on membrane distillation used for reducing solvent in polyphenol rich propolis extract

doi:10.1016/j.cjche.2017.03.041

Abstract

Abstract: Membrane distillation (MD) has not been widely studied in the concentrate of phenolic rich solution in comparison to osmotic distillation. In this work, the potential of MD to reduce solvent in the polyphenol rich propolis extract was further investigated. Polyvinylidene fluoride (PVDF) membranes were engineered with the smaller pore size for the less hydrophobic surface in order to avoid wetting, allowing only the solvent vapor to be transferred from the warm feed into the cold permeate. All the membranes exhibited more than 95% rejection of phenolic and flavonoid compounds. Although the hydrophilic membranes exhibited less fouling, they displayed a lower flux than the hydrophobic membrane due to the hindrance in the wetted pores. The hydrophobic membrane was seriously fouled by the phenolic acid as shown in the Fourier transform infrared spectroscopy spectrum. Pore plugging occurred on these hydrophobic membranes as confirmed in the scanning electron microscope images.

Key words: Membrane distillation, Propolis, Fouling

摘要： Membrane distillation (MD) has not been widely studied in the concentrate of phenolic rich solution in comparison to osmotic distillation. In this work, the potential of MD to reduce solvent in the polyphenol rich propolis extract was further investigated. Polyvinylidene fluoride (PVDF) membranes were engineered with the smaller pore size for the less hydrophobic surface in order to avoid wetting, allowing only the solvent vapor to be transferred from the warm feed into the cold permeate. All the membranes exhibited more than 95% rejection of phenolic and flavonoid compounds. Although the hydrophilic membranes exhibited less fouling, they displayed a lower flux than the hydrophobic membrane due to the hindrance in the wetted pores. The hydrophobic membrane was seriously fouled by the phenolic acid as shown in the Fourier transform infrared spectroscopy spectrum. Pore plugging occurred on these hydrophobic membranes as confirmed in the scanning electron microscope images.

关键词: Membrane distillation, Propolis, Fouling

Norhaziyana Hamzah, Choe Peng Leo. Fouling evaluation on membrane distillation used for reducing solvent in polyphenol rich propolis extract[J]. Chin.J.Chem.Eng., 2018, 26(3): 477-483.

Norhaziyana Hamzah, Choe Peng Leo. Fouling evaluation on membrane distillation used for reducing solvent in polyphenol rich propolis extract[J]. Chinese Journal of Chemical Engineering, 2018, 26(3): 477-483.

References

[1] J. Bonvehi, A. Gutierrez, Antioxidant activity and total phenolics of propolis from the Basque Country (Northeastern Spain), J. Am. Oil Chem. Soc. 88(2011) 1387-1395.

[2] L.G. Dias, A.P. Pereira, L.M. Estevinho, Comparative study of different Portuguese samples of propolis:Pollinic, sensorial, physicochemical, microbiological characterization and antibacterial activity, Food Chem. Toxicol. 50(12) (2012) 4246-4253.

[3] T. Kimoto, M. Aga, K. Hino, S. Koya-Miyata, Y. Yamamoto, M.J. Micallef, et al., Apoptosis of human leukemia cells induced by Artepillin C, an active ingredient of Brazilian propolis, Anticancer Res. 21(1A) (2001) 221-228.

[4] A.N. Koc, S. Silici, D. Ayangil, A. Ferahbas, S. Cankaya, Comparison of in vitro activities of antifungal drugs and ethanolic extract of propolis against Trichophyton rubrum and T. mentagrophytes by using a microdilution assay, Mycoses 48(3) (2005) 205-210.

[5] B. Bueno-Silva, S.M. Alencar, H. Koo, M. Ikegaki, G.V. Silva, M.H. Napimoga, et al., Anti-inflammatory and antimicrobial evaluation of neovestitol and vestitol isolated from Brazilian red propolis, J. Agric. Food Chem. 61(19) (2013) 4546-4550.

[6] N. El-Deen, M. AI, S. Zaki, S.I. Shalaby, S. Nasr, Propolis, with reference of Chemical composition, antiparasitic, antimycotic, antibacterial and antiviral activities:A review, Life Sci. J. 10(2) (2013) 1778-1782.

[7] B. Trusheva, D. Trunkova, V. Bankova, Different extraction methods of biologically active components from propolis:A preliminary study, Chem. Cent. J. 1(1) (2007) 13.

[8] K.L. Yeo, C.P. Leo, D.J.C. Chan, Ultrasonic enhancement on propolis extraction at varied pH and alcohol content, J. Food Process Eng. 38(2015) 562-570.

[9] F. Pellati, F. Prencipe, D. Bertelli, S. Benvenuti, An efficient chemical analysis of phenolic acids and flavonoids in raw propolis by microwave-assisted extraction combined with high-performance liquid chromatography using the fused-core technology, J. Pharm. Biomed. Anal. 81-82(2013) 126-132.

[10] N. Hamzah, C.P. Leo, Microwave assisted extraction of Trigona propolis:The effect of processing parameters, Int. J. Food Eng. 11(2015) 861-870.

[11] R. Krell, Value-added products from beekeeping, FAO Agric. Serv. Bull. (124) (1996).

[12] B.C.B.S. Mello, J.C.C. Petrus, M.D. Hubinger, Nanofiltration of aqueous propolis extracts and the effects of temperature, pressure and pH in the concentrated product, Stud. Chem. Process Technol. 1(4) (2013) 55-65.

[13] B.C.B.S. Mello, J.C.C. Petrus, M.D. Hubinger, Concentration of flavonoids and phenolic compounds in aqueous and ethanolic propolis extracts through nanofiltration, J. Food Eng. 96(4) (2010) 533-539.

[14] A. Alkhudhiri, N. Darwish, N. Hilal, Membrane distillation:A comprehensive review, Desalination 287(2012) 2-18.

[15] K.S. Bahceci, H.G. Akillioglu, V. Gökmen, Osmotic and membrane distillation for the concentration of tomato juice:Effects on quality and safety characteristics, Innovative Food Sci. Emerg. Technol. 31(2015) 131-138.

[16] S.K. Dershmukh, V.S. Sapkal, R.S. Sapkal, Dehydration of aloe vera juice by membrane distillation, J. Chem. Pharm. Sci. 6(2013) 66-71.

[17] A. Kozak, E. Bekassy-Molnar, G. Vatai, Production of black-currant juice concentrate by using membrane distillation, Desalination 241(2009) 309-314.

[18] L.F. Sotoft, K.V. Christensen, R. Andresen, B. Norddahl, Full scale plant with membrane based concentration of blackcurrant juice on the basis of laboratory and pilot scale tests, Chem. Eng. Process. 54(2012) 12-21.

[19] V.D. Alves, I.M. Coelhoso, Orange juice concentration by osmotic evaporation and membrane distillation:A comparative study, J. Food Eng. 74(2006) 123-133.

[20] A. El-Abbassi, H. Kiai, A. Hafidi, M.C. Garcia-Payo, M. Khayet, Treatment of olive mill wastewater by membrane distillation using polytetrafluoroethylene membranes, Sep. Purif. Technol. 98(2012) 55-61.

[21] H. Kiai, M.C. Garcia-Payo, A. Hafidi, M. Khayet, Application of membrane distillation technology in the treatment of table olive wastewaters for phenolic compounds concentration and high quality water production, Chem. Eng. Process. 86(2014) 153-161.

[22] A. El-Abbassi, A. Hafidi, M. Khayet, M.C. Garcia-Payo, Integrated direct contact membrane distillation for olive mill wastewater treatment, Desalination 323(2013) 31-38.

[23] D. Hou, H. Fan, Q. Jiang, J. Wang, X. Zhang, Preparation and characterization of PVDF flat-sheet membranes for direct contact membrane distillation, Sep. Purif. Technol. 135(2014) 211-222.

[24] K.C. Chong, S.O. Lai, K.M. Lee, W.J. Lau, A.F. Ismail, B.S. Ooi, Characteristic and performance of polyvinylidene fluoride membranes blended with different additives in direct contact membrane distillation, Desalin. Water Treat. 54(12) (2015) 3218-3226.

[25] A. Hausmann, P. Sanciolo, T. Vasiljevic, M. Weeks, K. Schroen, S. Gray, M. Duke, Fouling of dairy components on hydrophobic polytetrafluoroethylene (PTFE) membranes for membrane distillation, J. Membr. Sci. 442(2013) 149-159.

[26] Y.H. Choi, H.S. Kim, J.H. Kweon, Role of hydrophobic natural organic matter flocs on the fouling in coagulation-membrane processes, Sep. Purif. Technol. 62(2008) 529-534.

[27] J. Cao, H. Zhang, W. Xu, X. Li, Poly(vinylidene fluoride) porous membranes precipitated in water/ethanol dual-coagulation bath:The relationship between morphology and performance in vanadium flow battery, J. Power Sources 249(2014) 84-91.

[28] G. Vhquez, E. Alvarez, J.M. Navaza, Surface tension of alcohol + water from 20 to 50℃, J. Chem. Eng. Data 40(1995) 611-614.

[29] M. Gryta, Fouling in direct contact membrane distillation process, J. Membr. Sci. 325(2008) 383-394.

[30] M. Gryta, Concentration of NaCl solution by membrane distillation integrated with crystallization, Sep. Sci. Technol. 37(2002) 3535-3558.

[31] M. Mulder, Membrane processes, Basic Principles of Membrane Technology, Kluwer Academic Publishers, Dordrecht 2000, p. 308.

[32] O.M. Farid, Investigating Membrane Selectivity Based on Polymer Swelling, The University of Nottingham, Nottingham, 2010.