with the collaboration of Iranian Food Science and Technology Association (IFSTA)

Document Type : Research Article

Authors

Department of Food Science and Technology, Tarbiat Modares University, Tehran, Iran.

Abstract

Introduction: Ohmic heating or direct resistance heating is one of the several electromagnetic based methods, occurs when alternating electrical current is passed through a conductive material, with the primary purpose of heating it due to the electrical resistance of the foods. There are many applications that can use ohmic treatment technology, such as blanching, evaporation, dehydration, fermentation, extraction, sterilization and pasteurization of foods (Saberian et al. 2015; Assiry et al. 2010). Pectins are complex heteropolysaccharides, consisting of α-1, 4-linked D-galacturonic acid units and interrupted by L-rhamnose residues with side chains of neutral sugars, mainly L-rhamnose, L-arabinose and D-galactose. In the industrial extraction process, pectin is usually extracted from waste plant material such as citrus peels, apple pomace, sugar beet pulp and sunflower head using hot water (60–100°C) acidified with a mineral acid (such as sulfuric, phosphoric, nitric, hydrochloric) or organic acid (especially citric acid) within the pH of 1.5–3 for 0.5–6 h. The aim of this study was to explore the effect of enzymatic extraction on the yield and quality properties (degree of esterification, Galacturonic acid, emulsifying properties and viscosity) of the pectin, and to compare this pectin with the pectins extracted by ohmic and conventional methods. Finally, the best extraction method was selected.

Materials and Methods: Extraction of pectin was done with the assistance of an ohmic heating system at working frequency of 50 Hz under different parameters including voltage gradient (7-15 V/cm), temperature (50-90°C), and time (5-30 min). Then, the effect of enzyme dose (0-20% v/w) of Celluclast and Rohament CL, solid/liquid ratio (S/L ratio) (1:10 to 1:50 g/ml) and extraction time (1-18 h) on the yield of the extracted pectin from orange waste was investigated.
After the time of extraction (enzymatically, ohmically or conventionally), the sample was cooled to room temperature and centrifuged (10000 rpm, 15 min), and the supernatant was precipitated with two volumes of 96% (v/v) ethanol at 4 °C for 1 h. The precipitated pectin mass was washed twice with 96% ethanol in order to remove impurities. The pectin was dried in a forced circulation oven at 55°C until a constant weight (14 h).
Galacturonic acid content was determined according to Scott (1979) with some modifications. The degree of esterification (DE) of pectin samples was determined by titrimetric method according to Santos et al. (2013).
Emulsifying activity and emulsion stability were measured according to the method described by Yapo et al. (2007).
The viscosity and the flow behavior of the selected pectin solutions (2%, w/v) extracted conventionally and ohmically at 90°C for 30 min (the optimum extraction condition) and the highest pectins extracted enzymatically, were measured at 25°C.
Pectin powder samples were mixed with KBr and pressed into KBr pellets before FTIR analysis. PerkinElmer FTIR spectra (PerkinElmer, Frontier model, USA) was applied at the transmission mode in the frequency range of 4000–400 cm-1 at a resolution of 1 cm-1.
Results were analyzed by analysis of variance (ANOVA) using SPSS 19 statistical software and the Duncan’s test with 95% confidence interval was used to compare the means of the tests. The results which were presented in this research, have been obtained from the average values of the minimal two replicate experiments.

Results and Discussion: first, the effect of enzyme dose, solid/liquid ratio (S/L ratio) and time of extraction on the yield of the extracted pectin from orange waste by using Celluclast and Rohament CL enzymes was studied. Then, the yield, of esterification, galacturonic acid, emulsifying properties and viscosity behavior of the pectins extracted in the optimum condition by enzymes were compared to the extracted pectins by ohmic and conventional methods. Results indicated that the highest yield of pectin was obtained by using Celluclast and Rohament CL enzymes at enzyme doses of 15 and 17.5%, S/L ratio of 1:20 and 1:40 (g/ml) and time of 3 h for both, which were 5.92 and 10.70 %, respectively. The highest yield of pectin by ohmic heating was obtained at the voltage gradient of 15 v/cm, the temperature of 90°C during 30 min (14.33%), which was higher than the amount obtained by conventional method (13.53%) may be due to the electroporation (disruptive pores which were made on the cell membrane by the electric field) (Cho et al., 1996). de Oliveira et al. (2015) reported that the moderate electric field (at 45°C, 50 and 100 V) extracted the pectin significantly (p < 0.05) more than the conventional extraction. The emulsifying activity of the extracted pectins by ohmic and conventional methods were 65.47 and 67.18%, respectively, although the pectins extracted by enzymatic method had not any emulsifying activity. It seems that during the pectin extraction, enzymes hydrolyzate the pectins. The viscosity of the pectins extracted by ohmic and conventional methods at the concentration of 2% was higher than those obtained from the enzymatic method. Therefore, pectin extracted by ohmic and conventional methods had the highest yield, emulsifying properties, and viscosity.

Keywords

Chen, Y., Zhang, J. G., Sun, H. J., & Wei, Z. J. (2014). Pectin from Abelmoschusesculentus: Optimization of extraction and rheological properties. International Journal of Biological Macromolecules, 70, 498–505.
Cho, H.Y., Yousef, A.E., & Sastry, S.K. (1996). Growth kinetics of lactobacillus acidophilus under ohmic heating. Biotechnology and Bioengineering, 49, 334–340.
de Oliveira, C. F., Giordani, D., Gurak, P. D., Cladera-Olivera, F., & Marczak, L. D. F. (2015). Extraction of pectin from passion fruit peel using moderate electric field and conventional heating extraction methods. Innovative Food Science & Emerging Technologies, 29, 201-208.
Dominiak, M., Søndergaard, K. M., Wichmann, J., Vidal-Melgosa, S., Willats, W. G. T., Meyer, A. S. & Mikkelsen, J. D. (2014). Application of enzymes for efficient extraction, modification, and development of functional properties of lime pectin. Food Hydrocolloids, 40: 273-282.
Ebrahimzadeh, M. A., Azadbakht, M. 2006, Pectin extraction and comparison the yield, DE and galacturonic acid from some citruce peel, Medical Science Journal of Mazandaran, 16 (54): 52-59.
Fathi, B., Maghsoudloo, Y., Ghorbani, M., Khomeiri, M. 2012, The effect of pH, temperature, and time of acidic extraction on the yield and quality properties of pectin from Nutty Pumpkin, IFSTRJ, 22: 465-475.
Guo, X., Han, D., Xi, H., Rao, L., Liao, X., Hu, X., & Wu, J. (2012). Extraction of pectin from navel orange peel assisted by ultra-high pressure, microwave or traditional heating: a comparison. Carbohydrate polymers, 88(2), 441-448.
Hosseini, S. S., Khodaiyan, F., & Yarmand, M. S. (2016). Aqueous extraction of pectin from sour orange peel and itspreliminary physicochemical properties. International Journal of Biological Macromolecules, 82, 920-926.
Huang, X., Kakuda, Y., & Cui, W. (2001). Hydrocolloids in emulsions: particle size distribution and interfacial activity. Food Hydrocolloids, 15, 533–542.
Keramat, J., Kabir, Gh., Ghenaati, B. 2002. Investigating the quality and quantity of the pectin extracted from the orange juice concentrate, Science and Technology of Agriculture and Natural Resources, 6 (4): 141-150.
Koubala, B.B., Kansci, G., Mbome, L.I., C, Crepeau, M.J., Thibault, J.F., & Ralet, M.C. (2008). Effect of extraction conditions on some physicochemical characteristics of pectins from ‘‘Amelioree’’ and‘Mango’ mango peels. Food Hydrocolloids 22 (7), 1345–1351.
Loypimai, P., Moongngarm, A., Chottanom, P., & Moontree, T. (2015). Ohmic heating-assisted extraction of anthocyanins from black rice bran to prepare a natural food colourant. Innovative Food Science & Emerging Technologies, 27, 102-110.
McClements, D. J. (2004). Food emulsions: Principles, practices, and techniques (2nded.). Boca Raton: CRC Press.
Maran, J. P., Swathi, K., Jeevitha, P., Jayalakshmi, J., & Ashvini, G. (2015). Microwave-assisted extraction of pectic polysaccharide from waste mango peel. Carbohydrate polymers, 123, 67-71.
Mesbahi, Gh., Jamalian, J. 2002, Extraction of the pectin from the root beet waste and investigating its application in the food products, Science and Technology of Agriculture and Natural Resources, 6 (125): 2-13.
Mohnen, D. (2008). Pectin structure and biosynthesis. Current opinion in plant biology, 11(3), 266-277.
Ptichkina, N., Markina, O., & Rumyantseva, G. (2008). Pectin extraction from pumpkin with the aid of microbial enzymes. Food hydrocolloids, 22(1): 192-195.
Santos, J. D. G., Espeleta, A. F., Branco, A., & de Assis, S. A. (2013). Aqueous extraction of pectin from sisal waste. Carbohydrate polymers, 92(2), 1997-2001.
Sato, M. d. F., Rigoni, D. C., Canteri, M. H. G., Petkowicz, C. L. d. O., Nogueira, A., & Wosiacki, G. (2011). Chemical and instrumental characterization of pectin from dried pomace of eleven apple cultivars. Acta Scientiarum Agronomy, 33(3): 383-389.
Scott, R. W. (1979). Colorimetric determination of hexuronic acids in plant materials. Analytical chemistry, 51(7), 936-941.
Vosoughi, M. 1996. Production and purification of the pectin from apple waste, Research report No. 164, Research Institute of Agricultural Engineering, Iran.
Wai, W. W., Alkarkhi, A. F., & Easa, A. M. (2010). Effect of extraction conditions on yield and degree of esterification of durian rind pectin: An experimental design. Food and Bioproducts Processing, 88(2), 209-214.
Wang, W., Ma, X., Xu, Y., Cao, Y., Jiang, Z., Ding, T., Ye, X., & Liu, D. (2015). Ultrasound-assisted heating extraction of pectin from grapefruit peel: Optimization and comparison with the conventional method. Food chemistry, 178, 106-114.
Wang, M., Fan, C., Zhao, K., Huang, B., Hu, H., Xu, X., Pan, S., & Liu, F. (2016). Characterization and functional properties of mango peel pectin extracted by ultrasound assisted citric acid. International Journal of Biological Macromolecules, 91, 794- 803.
Wikiera, A., Mika, M., & Grabacka, M. (2015). Multicatalytic enzyme preparations as effective alternative to acid in pectin extraction. Food Hydrocolloids, 44, 156-161.
Yapo, B. M. (2011). ectic substances: From simple pectic polysaccharides to complex pectins—A new hypothetical model, Carbohydrate Polymers, 86 (2), 373-385.
Yapo, B.M., Robert, C., Etienne, I., Wathelet, B., & Paquot, M., (2007). Effect of extraction conditions on the yield, purity and surface properties of sugar beet pulp pectin extracts. Food Chemistry, 100, 1356–1364.
Yin, Y. g., Fan, X. d., Liu, F. x., Yu, Q. y., & He, G. d. (2009). Fast extraction of pectin from apple pomace by high intensity pulsed electric field. Journal of Jilin University (Engineering and Technology Edition), 5, 021.
CAPTCHA Image