بررسی مقایسه‌ای اثر فرآیند‌های پاستوریزاسیون و استریلیزاسیون بر زنده‌مانی باکتری های پروبیوتیک و پتانسیل اکسیداسیون و احیاء ماست قالبی پروبیوتیک

نویسندگان
فاطمه جعفری نجف آبادی 1
وجیهه فدائی نوغانی 2
1 گروه علوم و صنایع غذایی، واحد شهر قدس، دانشگاه آزاد اسلامی، تهران، ایران.
2 گروه علوم و صنایع غذایی، واحد شهر قدس، دانشگاه آزاد اسلامی، تهران، ایران
10.52547/fsct.18.112.137
چکیده
در این پژوهش، تأثیر فرآیند­های مختلف حرارتی شیر، پاستوریزاسیون (°C 63 به مدت 30 دقیقه،°C 74 به مدت 15 ثانیه، °C 95 به مدت 5 دقیقه) و استریلیزاسیون (°C 120 به مدت 15 دقیقه، اتوکلاو، و °C 140 به مدت 4-2 ثانیه، فرا­دما)، بر ویژگی های فیزیکوشیمیایی انتخابی، پذیرش کلی و زنده مانی باکتری های پروبیوتیک ماست قالبی طی 21 روز نگهداری در سرما مورد مطالعه قرار گرفت. نتایج نشان داد که طی نگهداری، آب اندازی کاهش پیدا کرد و اسیدیته و پتانسیل اکسیداسیون و احیاء افزایش یافت (05/0p<). با افزایش شدت فرآیند حرارتی شیر، کاهش در پتانسیل اکسیداسیون و احیاء و آب اندازی (05/0p<) و افزایش در اسیدیته و قابلیت زنده مانی لاکتوباسیلوس اسیدوفیلوس (05/0p<) و بیفیدوباکتریوم لاکتیس (05/0<p) مشاهده شد. در نهایت، بهترین نمونه از نظر ارزیابی حسی و زنده مانی باکتری های پروبیوتیک، نمونه ماست حاصل از شیر تیمار شده در °C 140 به مدت 4-2 ثانیه انتخاب گردید.
کلیدواژه‌ها
ماست پروبیوتیک
پاستوریزاسیون
استریلیزاسیون
پتانسیل اکسیداسیون و احیاء
قابلیت زنده مانی

موضوعات

عنوان مقاله English

Comparative investigating the effect of pasteurization and sterilization processes on survival of probiotic bacteria and redox potential of probiotic set-type yoghurt

نویسندگان English

Fatemeh Jafari-Najafabadi 1
Vajiheh Fadaei-Noghani 2
1 Department of Food Science and Technology, Shahr-e-Qods Branch, Islamic Azad University, Tehran, Iran.
2 Department of Food Science and Technology, Shahr-e-Qods Branch, Islamic Azad University, Tehran, Iran.
چکیده English

In this research, the effect of different thermal processes of milk, pasteurization) 63°C for 30 min, 74°C for 15 s, 95°C for 5 min) and sterilization (120°C for 15 min and 140°C for 2-4 s), on the selective physicochemical, sensory and microbial properties of probiotic yoghurt was investigated during cold storage for 21 days. Results showed that during storage time, syneresis decreased and acidity and redox potential increased (p<0.01). By increasing the severity of thermal processing, the decline in syneresis and redox potential (p<0.01) and the increase in acidity and viability of Lactobacillus acidophilus (p<0.05) and Bifidobacterium lactis was observed (p>0.05). Finally, regarding to the highest sensory evaluation and probiotic bacteria viability, the yoghurt sample produced from milk treated at 140°C for 2-4 s was selected as the best sample.



K

کلیدواژه‌ها English

Probiotic yogurt
Pasteurization
Sterilization
redox potential
Viability
[1] Tamime, A. Y. 2006. Probiotic Dairy Products. Tamime, A.Y., Saarela, M., Korslund, S., Mistry, V. V. and Shah, N. P. Production and Maintenance of Viability of Probiotic Micro-organisms in Dairy Product. Wiley-Blackwell Publishing, 39-63.
[2] Raikos, V. 2010. Effect of heat treatment on milk protein functionality at emulsion interfaces. Food Hydrocolloids, 24: 259-265.
[3] Temesgen, M. 2015. Effect of Application of Stabilizers on Gelation and Synersis in Yoghurt. Food Science and Quality Management, 37: 90-102.
[4] Pourahmad, R. and Fadaei, V. 2007. Milk processing: improving quality. Tehran: Marz-e-Danesh, Vol 1. 230-233; 196-206. (In Persian)
[5] Troise, A.D. 2019. Maillard Reaction and Food Safety. In: Ferranti, P., Berry, E.M. and Anderson, J.R. (Eds.). Encyclopedia of Food Security and Sustainability. Elsevier, Vol. 2. 364–369.
[6] Bertrand, E., El Boustany, P., Faulds, C.B. and Berdagué, J-L. 2018. The Maillard Reaction in Food: An Introduction. Reference Module in Food Science. Elsevier, 1–10.
[7] Nunes, L., Martins, E., Tuler Perrone, I. and Fernandes de Carvalho, A. 2019. The Maillard Reaction in Powdered Infant Formula. Journal of Food and Nutrition Research, 7 (1): 33-40.
[8] Pourahmad, R. and Fadaei V. 2009. Dairy industry 1. Varamin: Islamic Azad University, Varamin-Pishva Branch, 137-140; 88. (In Persian)
[9] Dave, R. and Shah, N. 1997. Viability of yoghurt and probiotic bacteria in yoghurts made from commerical starter cultures. International Dairy Journal, 7: 31-41.
[10] Shah, N. P. 2000. Symposiom: probiotic bacteria: Selective enumeration and survival in dairy foods. Journal of Dairy Science, 83: 894-907.
[11] Mortazavian, A. M., Ehsani, M. R., Mousavi, S. M., Reinheimer, J. A., Emamdjomeh, Z., Sohrabvandi, S. and Rezaei, K. 2006. Preliminary investigation of the combined effect of heat treatment incubation temperature on the viability if the probiotic microorganisms in freshly made yoghurt. International Journal of Dairy Technology, 59: 8-11.
[12] Mortazavian, A. M., Sohrabvandi, S., Mousavi, S. M. and Reinheimer, J. A. 2006. Combined effects of temperature-ralated variables on the viability of Probiotic microorganisms in yogurt. Australian Journal of Dairy Technology, 61 (3): 248-252.
[13] Mortazavian, A. M., Ehsani, M.R., Mosavi, S. M., Rezaei, K., Sohrabvandi, S. and Reinheimer, J. A. 2007. Effect of refrigerated storage temperature on the viability of probiotic micro-organisms in yogurt. International Journal of Dairy Technology, 2: 123-127.
[14] Mortazavian, A. M., Ghorbanipour, S., Mohammadifar, M. A. and Mohammadi, M. 2011. Biochemical Properties and Viable Probiotic Population of Yogurt at Different Bacterial Inoculation Rates and Incubation Temperatures. Philipp Agric Scientist, 2: 111-116.
[15] Masoud, R.; Fadaei, V.; Khosravi-Darani, K. and Nikbakht, H. M. 2015. Improving the viability of probiotic bacteria in yoghurt by homogenization. Journal of Food Processing and Preservation. 39(6): 1-7.
[16] ISIRI. 2006. Milk and Milk products. Determination of pH and acidity. ISIRI No 2852. Karaj, Iran. (In Persian)
[17] Al-Kadamany, E., Khattar, M., Haddad, T. andToufeili, I., 2003. Estimation of shelf life of concentrated yoghurt by monitoring selected microbiological and physiological cha racterization during storage. Journal Dairy Science, 85:1023–1030.
[18] Meilgaard, M., Civille, G. V. and Carr, B. T. 2006. Sensory Evaluation Techniques. New York: CRC Press. 453.
[19] Cho, W. Y., Kim, D. H., Lee, H. J., Yeon, S. J. and Lee, C. H. 2020. Quality characteristic and antioxidant activity of yogurt containing olive leaf hot water extract. CyTA – Journal of Food, 18 (1): 43-50.
[20] Jeong, C. H., Ryu, H., Zhang, T., Lee, C.H., Seo, H. G. and Han, S. G. 2018. Green tea powder supplementation enhances fermentation and antioxidant activity of set-type yogurt. Food Science and Biotechnology, 27 (5): 1419-1427.
[21] Tarakci, Z. 2010. Influence of Kiwi marmalade on the Rheology characteristics, color values and sensorial acceptability of fruit yogurt. Kafkas Universitesi Veteriner Fakultesi Dergisi, 16 (2): 173-178.
[22] Bakirci, I. and Kavaz, A. 2008. An investigation of some properties of banana yogurts made with commercial ABT-2 starter culture during storage. International Journal of Dairy Technology, 61(3): 270-276.
[23] Walstra, P., Wouters, J. and Geurts, T. 2006. Dairy Science and Technology. New York: CRC Press.
[24] Beheshtipour, H., Mortazavian, A. M., Mohammadi, R., Sohrabvandi, S. and Khosravi-darani, K. 2013. Supplementation of spirulina pelatensis and chlorella vulgaris algea into probiotic fermented milks comprehensive. Reviews in Food Safety, 12: 144-154.
[25] Tamime, A.Y. and Robinson, R.K. 2007. Yoghurt Science and Technology. Boca Raton: CRC Press. 791.
[26] Zamberlin, Š., Mio, Q. B. and Samaržija, D. 2011. Influence of yoghurt cultures on some chemical parameters of sheep's milk yoghurt during storage. In Proceedings. 46th Croatian and 6th International Symposium on Agriculture Opatija. Croatia, 908-911.
[27] Bano, P., Abdullah, M., Nadeem, M. and Babar, M. E. 2011. Preparation of functional yoghurt from sheep and goat milk blends. Pakistan Journal of Agriculture Science, 48 (3): 211-215.
[28] Papastoyiannidis, G., Polychroniadou, A. and Michaelidou, A. M. 2006. Alichanidis E. Fermented milks fortified with B-group vitamins: vitamin stability and effect on resulting products. Food Science and Technology International, 12: 521–529.
[29] Salwa, A. A., Galal, E. A. and Elwa, N. A. 2004. Carrot yoghurt: sensory, chemical, microbiological properties and consumer acceptance. Pakistan Journal of Nutrition, 3: 322-330.
[30] Vahedi, N. and Mazaheri-Tehrani, M. 2007. Optimazation of fruit yogurt formulation and investigating it quality during storage time. 17th National Congress of Food Industry. Orumiyeh. (In Persian)
[31] Bulut, M., Tuncturk, Y. and Alwazeer, D. 2019. The Role of Redox Potential on Aroma Components of Yoghurt. Uluslararasi Gap Trimm Ve Hayvancilik Kongresi. 25 - 27 Nisan Şanliurfa.
[32] Liu, C. G., Jin-Cheng Qin, J. C. and Lin, Y. H. 2017. Fermentation and Redox Potential. https://www.researchgate.net/publication/313542677.
[33] Dini, A., Razavi, SH. and Mousavi, SM. 2013. Effect of incubation and storage temperatures and final pH on the viability of probiotic bacteria and sensory characteristics in probiotic Doogh. Journal of Food Industry Researches. 23 (3): 367-380. (In Persian)
[34] Barrantes, E., Tamime, A. Y., Sword, A. M., Muir, D. D. and Kalab, M. 1996. The manufacture of set-type natural yoghurt containing different oils. Rheological properties and microstructure. Dairy Journal, 6: 827-837.
[35] La Torre, L., Tamime, A. Y. and Muir, D. D. 2003. Rheology and sensory profiling of set-type fermented milks made with different commercial probiotic and yogurt starter culture. International Journal of Dairy Technology, 56: 163-170.
[36] Guler-Akin, M. B. and Serdar Akin, M. 2005. Effect of cysteine and different incubation temperatures on the microflora, chemical composition and sensory characteristics of bio-yoghurt made from goat’s milk. Food Chemistry, 100: 788-793.
[37] Kailasapathy, K. 2006. Survival of free and encapsulated probiotic bacteria and their effect on the sensory properties of yoghurt. LWT- Food Science and Technology, 39: 1221-1227.
[38] Mumtaz, S., Rehman, S. U., Huma, N., Jamil, A. and Nawaz, H. 2008. Xylooligosaccharide enriched yoghurt: physicochemical and sensory evaluation. Pakistan Journal of Nutrition, 7(4): 566-569.
[39] Souza, C. H. B. and Saad, S. M. I. 2009. Viability of Lactobacillus acidophilus La-5 added solely or in co-culture with a yoghurt starter culture and implications on physic-chemical and related properties on minas fresh cheese during storage. LWT- Food Science and Technology, 42: 633-640.
[40] Izadi, Z., Garoosi, G., Nasirpour, A., Ahmadi, J. and Bahrami, B. 2011. Optimization of producing enriched yogurt with phytosterols in order to reducing cholesterol content. Iranian Food Science and Technology Research Journal. 7 (2), 156-163. (In Persian)
[41] Ghorbani, A., Pourahmad, R., Fallahpour, M. and Mazaheri-asadi, M. 2014. Investigating Phisyco-chemical, reological and microbial properties of probiotic soy yogurt during 21-day storage. Foods Technology and Nutrition. 11 (1): 43-49. (In Persian)
[42] Jozve-Zargarabadi, E., Fadaei, V. and Fallah Huseini., H. 2020. Viability of Starter Bacteria and Anti-Oxidative Activity of a Functional Yogurt Containing Silybum marianum Seed Extract. Applied Food Biotechnology, 7 (3):135-142.
[43] Mortazavian, A. and Sohrabvandi, S. 2004. Probiotic and probiotic food products. Tehran: Ata, 486. (In Persian)
[44] Martensson, O., Oste, R. and Holst, O. 2002. The effect of yoghurt culture on the survival of probiotic bacteria in oat-based non-dairy products. Food Research International, 35:775-784.
[45] Vinderola, C. G., Bailo, N. and Reinheimer, J. A. 2000. Survival of probiotic microfflora in Argentinian yoghurt during refrigerated storage. Food Research International, 33: 97-102.
[46] Medina, L. M. and Jorjdano, R. 1994. Survival of constitutive microflora in commercially fermented milk containing bifidobacteria during refrigerated storage. Journal of Food Protection, 56(8), 731-733.
[47] Kashket, E. R. 1987. Bio-energetics of lactic acid bacteria: cyto-plasmic pH and osmotolerance. FEMS Microbiology Reviews, 46-233.
[48] Hamilton-miller, J. M. T., Shah, S. and Winkler, J. T. 1999. Public health issues arising from microbiological and labeling quality of foods and supplements containing probiotic microorganisms. Public Health and Nutrition, 2(2): 223-229.
[49] Klaver, F. A. M., Kingma, F. and weerkamp, A.H. 1993. Growth and survival of bifidobacterianin milk. Netherland Milk Dairy Journal, 47: 151-164.
[50] Modler, H. W. and Villa-Garcia, L. 1993. The growth of bifidobacterium longom in whey-based medium and viability of this organism in frozen yogurt with low and high levels of developed acidity. Cultured Dairy products Journal, 4-8.
[51] Samona, A. and Robinson, R. K. 1994. Effect of yoghurt cultures on the survival of bifidobacteria in fermented milks. Journal of the Society of Dairy Technology, 47: 58-60.
[52] Smaczn, T. and Reinartz, M. T. 1982. Yoghurt, bioghurt, and biogarde producte, a comparison from microbiological and nutritional points of view. Verbraucherdienst, 27(11): 255-258.
[53] Voosogh, A. S., Khomeiri, M., Kashani Nejad, M. and Jafari, S. M. 2009. Survival of Bifidobacterium lactis and Lactobacillus acidophilus in Iranian doogh flavored by ziziphora extract. JFST. 6 (4): 77-85. (In Persian)
[54] Donkor, O. N., Henriksson, A., Vasiljevic, T. and Shah, N.P. 2006. Effect of acidification on the activity of probiotic in yogurt during cold storage. International Dairy Journal, 16: 1181-1189.
[55] Dave, R. I. and Shah, N. P. 1996. Evaluation of media for selective enumeration of Streptococcus, Lactobacillus delbrueckii spp. Bulgaricus, Lactobacillus acidophilus, and Bifidobacteria. Journal of Dairy Science, 79: 1529-1536.
[56] Kailasapathy, K. and Rybka, S. 1997. Lactobacillus acidophilus and Bifidobacterium spp.: their therapeutic potential and survival in yoghurt. Journal Dairy Technol, 52: 28-35.
[57] Kailasapathy, K. 2006. Survival of free and encapsulated probiotic bacteria and their effect on the sensory properties of yoghurt. LWT- Food Science and Technology, 39: 1221-1227.
[58] Dave, R. I. and Shah, N. P., 1997. Effect of cysteine on the viability of yoghurt and probiotic bacteria in yoghurts made from commercial produced by Lactobacillus acidophilus LA-5. International Dairy Journal, 10: 213-220.
[59] Mortazavian, A. M., Ehsani, M. R., Mousavi, S. M., Reinheimer, J. A., Emamdjomeh, Z., Sohrabvandi, S. and Rezaei, K. 2006. Preliminary investigation of the combined effect of heat treatment incubation temperature on the viability if the probiotic microorganisms in freshly made yoghurt. International Journal of Dairy Technology, 59: 8-11.
[60] Dini, A., Razavi, SH. and Mousavi, SM. 2013. Effect of incubation and storage temperatures and final pH on the viability of probiotic bacteria and sensory characteristics in probiotic Doog. Food Technology Research Journal, 3: 367-379. (In Persian)
[61] Law, J. and Haandrikman, A. 1997. Proteolytic enzymes of lactic acid bacteria. Review article. International Dairy Journal, 7: 1-11.
[62] Shihata, A. and Shah, N. P. 2000. Proteolytic profiles of yogurt and probiotic bacteria. International Dairy Journal, 10: 401-408.
[63] Cinbas, A. and Yazici F. 2008. Effect of addition of blueberries on selected physicochemical and sensory properties of yoghurts. Food Technology and Biotechnology, 46(4): 434-441.