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

Document Type : Research Article

Authors

Department of Food Science and Technology, Islamic Azad University, Branch of Kazerun, Kazerun.

Abstract

Introduction: Pectin is a complex mixture of polysaccharides in the primary cell wall of plants which is a polymer of α-galacturonic acid, to which neutral sugar is connected to form aside chain. Pectin is a natural food additive used extensively in the food industry as thickener, texturizer, emulsifier, stabilizer and gelling agent. In 2018, the world market demand for pectin was in excess of 60,000 tons and Europe was estimated to have the largest market with 31,000 tons (valued about US$420). In Iran, about one hundred tons of pectin is consumed annually in the food and pharmaceutical industries, all of which are supplied from abroad, and due to its price in the world market is of considerable magnitude. Therefore, the study of its production within the country could be of great importance. During processing and canning of eggplant, its cap and skin are discarded as waste which can be considered as a valuable ingredient in the food industry. The main objective of this study was to develop an MAE (Microwave assisted extraction) of pectin from eggplant peel and investigate the effect of process variables (microwave power, irradiation time and pH) and the response (extraction yield, degree of esterification, galacturonic acid content and emulsifying activity); and to obtain optimum conditions for maximum extraction yield of pectin from eggplant peel. The response surface methodology (RSM) using Box-Behnken design was employed in this study.
 
Material and methods: Eggplant peels were provided by Yek-o-Yek factory as an unwanted by-product. Then, the peels were divided into small pieces and dried in hot air oven at 65 °C until it attains constant weight. The peels were then grinded and passed through a 40-mesh sieve to obtain powdered sample. The independent variables examined were microwave power (360–450–540 W), irradiation time (1–2.5–4 min) and solution pH (1–2–3). MAE of pectin was performed in an ordinary household microwave oven with a total of 17 treatments according to RSM. About 5 g of dried eggplant peel powder was weighed and placed into a 250 ml beaker, 75 ml distilled water (the liquid-solid ratio 15:1 v/w) containing different pH values was added and exposed to microwave radiation at different powers for the selected irradiation times. After microwave heating, the mixture in the beaker was allowed to be cooled down and filtered using filter paper (Whatman no-1). The filtered extract was centrifuged and the supernatant was precipitated with an equal volume of 98% (v/v) ethanol. The coagulated pectin mass was washed with 98% (v/v) ethanol for two times and dried in oven at 60 ° C until it attains constant weight. The pectin extraction yield was calculated by dividing the weight of dried pectin to the weight of dried eggplant peel powder. Galactoronic acid content of pectins was determined using the meta-hydroxydiphenyl method. The esterification degree of the pectins was determined by the titrimetric method with minor modifications. The emulsifying activity (EA) of the eggplant peel pectins were analyzed according to the method by Dalev & Simeonova (1995). Optimum extraction conditions to achieve maximum extraction efficiency, degree of esterification, galacturonic acid content and emulsifying activity were determined. Then, the stability of the oil-based emulsion prepared by mixing 0.5% w/w solution of pectin extracted in optimal conditions and corn oil, were examined at 4 and 23 ° C. In addition, the behavior of pectin extracted under optimal conditions (at concentrations of 0.1, 0.2, 1 and 2%) and its spectra using a Fourier transform infrared spectrometer (FTIR) were investigated.
 
Results and discussion: The results indicated that the extraction efficiency, esterification degree, the amount of galacturonic acid, and the emulsifying activity of the pectins extracted were 2.20- 17.16%, 20.20- 36.13%, 51.3- 74.7%, and 1.87- 21.64%, respectively. With increasing microwave power, irradiation time and decrease of solution pH the extraction efficiency of pectin extracted increased, while esterification degree decreased. The amount of galacturonic acid and emulsifying activity showed an upward trend up to microwave power of 450 watts and the irradiation time of 3 minutes after which demonstrated a downward trend. The optimum conditions for reach to the maximum extraction yield, galacturonic acid content and emulsifying activity were in microwave power of 360 W, irradiation time of 4 min and pH of 1 that at these conditions, the extraction yield of 16.17, galacturonic acid content of 70.81 and emulsifying activity of 2.68 were predicted. Also, these observations indicated that with increase in concentration, the flow behavior of pectin solutions was changed from Newtonian to pseudo-plastic. In addition the stability of pectin-stabilized emulsion at 4°C was more than 23°C. In general, this study showed that the microwave method could be used as a novel and high-performance method for extracting pectin from eggplant peel.

Keywords

ابراهیم‌پور، ن.، پیغمبردوست، س. ه. و آزاد مرد دمیرچی، ص.، 1389، تاثیر افزودن پکتین، گوار و کاراگینان بر روی ویژگی‌های کیفی نان حجیم بدون گلوتن، مجله پژوهش های صنایع غذایی، جلد 3، شماره 2، ص 98-86..
انتشارات مرکز گمرک ایران، 1373، آمارنامه‌ی واردات و صادرات ایران، مرکز گمرک ایران، تهران.
ناطقی، ل. و انصاری، س.، 1396، استخراج و بررسی خصوصیات فیزیکوشیمیایی پکتین استخراجی از ضایعات کلاهک بادنجان، فصلنامه فناوری های نوین غذایی، دوره 5، شماره2.
Anonymous. 19 February 2019. Pectin – A global market overview [press release]. Available at: http://www.industry-experts.com/verticals/food-and-beverage/pectin-a-global-market-overview.
Bagherian, H., Zokaee Ashtiani, F., Fouladitajar, A., & Mohtashamy, M., 2011, Comparisons between conventional, microwave-and ultrasound-assisted methods for extraction of pectin from grapefruit. Chemical Engineering and Processing: Process Intensification, 50(11), 1237–1243.
Dalev, P. G., & Simeonova, L. S., 1995, Emulsifying properties of protein–pectin complexes and their use in oil‐containing foodstuffs. Journal of the Science of Food and Agriculture, 68(2), 203-206.
FAO, 2017. Statistical Database. Available from: <http://www.fao.org>. Retrieved 2019-04-03
Hosseini, S. S., Khodaiyan, F., & Yarmand, M. S., 2016b, Optimization of microwave assisted extraction of pectin from sour orange peel and its physicochemical properties. Carbohydrate Polymers, 140, 59–65.
Jafari, F., Khodaiyan, F., Kiani, H., & Hosseini, S. S., 2017, Pectin from carrot pomace: Optimization of extraction and physicochemical properties. Carbohydrate Polymers, 157, 1315–1322.
Kazemi, M., Khodaiyan, F., Labbafi, M., Hosseini, S. S., & Hojjati, M., 2019, Pistachio green hull pectin: Optimization of microwave-assisted extraction and evaluation of its physicochemical, structural and functional properties. Food Chemistry, 271, 663-672.
Kazemi, M., Khodaiyan, F., & Hosseini, S.S., 2019, Eggplant peel as a high potential source of high methylated pectin: Ultrasonic extraction optimization and characterization, LWT - Food Science and Technology (in press).
Li, D., Jia, X., Wei, Z., & Liu, Z., 2012, Box–Behnken experimental design for investigation of microwave-assisted extracted sugar beet pulp pectin. Carbohydrate Polymers, 88(1), 342–346.
Ma, S., Yu, S., Zheng, X., Wang, X., Bao, Q.D., & Guo, X., 2013, Extraction, characterization and spontaneous emulsifying properties of pectin from sugar beet pulp. Carbohydrate Polymers, 98(1), 750–3.
Maran, J.P., Sivakumar, V., Thirugnanasambandham, K., & Sridhar, R., 2013, Optimization of microwave assisted extraction of pectin from orange peel. Carbohydrate Polymers, 97(2), 703–709.
Mesbahi, G.; Jamalian, J., & Farahnaky, A., 2005, A comparative study on functional properties of beet and citrus pectins in food systems. Food Hydrocolloids, 19(4), 731–738.
Mort, A.J., Qiu, F., & Maness, N.O., 1993, Determination of the pattern of methyl esterification in pectin: distribution of contiguous non esterified residues. Carbohydrate Research, 247, 21–35.
Panouille, M., Thibault, J. F., & Bonnin, E., 2006, Cellulase and protease preparations can extract pectins from various plant byproducts. Journal of Agricultural and Food Chemistry, 54(23), 8926-8935.
Samavati, V., 2013, Polysaccharide extraction from Abelmoschus esculentus: Optimization by response surface methodology. Carbohydrate Polymers, 95(1), 588–597.
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.
Wai, W.W., Alkarkhi, A.F.M., & Easa, A.M., 2009, Optimization of pectin extraction from durian rind (Durio zibethinus) using response surface methodology. Journal of Food Science, 74(8), C637–C641.
Wang, S., Chen, F., Wu, J., Wang, Z., Liao, X., & Hu, X., 2007, Optimization of pectin extraction assisted by microwave from apple pomace using response surface methodology. Journal of Food Engineering, 78(2), 693-700.
Yan, M.M., Liu, W., Fu, Y.J., Zu, Y.G., Chen, C.Y., & Luo, M., 2010, Optimisation of the microwave-assisted extraction process for four main astragalosides in Radix Astragali. Food Chemistry, 119(4), 1663–1670.
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(4), 1356-1364.
Yeoh , S., Zhang , S., Shi, J., Langrish, T. A. G., 2008, A comparison of different techniques for water-based extraction of pectin from orange peels. Chemical Engineering Communications, 195:5, 511-520,
CAPTCHA Image