Food Science and Technology

ISSN-print: 2073-8684
ISSN-online: 2409-7004
ISO: 26324:2012
Архiви

PLASMA-CHEMICALLY ACTIVATED WATER INFLUENCE ON STALING AND SAFETY OF SPROUTED BREAD

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Опубліковано лип 2, 2018
DOI https://doi.org/10.15673/fst.v12i2.940

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A. Pivovarov
Одеська національна академія харчових технологій
S. Mykolenko
Y. Hez’
S. Shcherbakov

Анотація

The article reveals the research results of freshness and safety of sprouted wheat bread made with the use of water additionally treated with nonequilibrium low-temperature contact plasma. Prospects of the use of dispersion of wheat grain for the wholegrain bread production are shown which allow decreasing the grain raw materials loss along the food chain. The ways of prolongation of bread freshness during storage and slowdown of bread staling are analyzed. It is shown that in case of usage of plasma-chemically activated water in the technology wheat grain soaking duration decreases by 30%. The additional water treatment also promotes bread freshness prolongation up to two days. It is determined that water gets the characteristics relevant for the technology after 30–40 minutes of treatment with nonequilibrium low-temperature contact plasma. According to our findings, usage of plasma-chemically activated water provides slowdown of water migration and moisture loss by the crumb. It is determined that the usage of additional water treatment in the technology results in 17–60% increase in hydrophilic properties of the crumb and slows down their reduction during storage of sprouted wheat bread. Results of differential thermal analysis showed changes in various forms of moisture binding in the product during storage and increase in the part of adsorptionally bound moisture by 6–8%, when additional water treatment is used for grain soaking and dough making in sprouted wheat bread making technology. The rate of moisture removal from crumb of sprouted wheat bread made with the use of water subjected to nonequilibrium low-temperature contact plasma was determined through mathematical processing of data and construction of piecewise linear model. It is proved that safety level of usage of plasma-chemically activated water in sprouted wheat bread technology meets the requirements to the content of heavy metals such as mercury, arsenic, copper, lead, cadmium, zinc, and mycotoxins (aflatoxin B1, deoxynivalenol, zearalenone).

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Як цитувати
Pivovarov, A., Mykolenko, S., Hez’, Y., & Shcherbakov, S. (2018). PLASMA-CHEMICALLY ACTIVATED WATER INFLUENCE ON STALING AND SAFETY OF SPROUTED BREAD. Food Science and Technology, 12(2). https://doi.org/10.15673/fst.v12i2.940
Номер
Том 12 № 2 (2018)
Розділ
Технологія і безпека продуктів харчування
Біографія автора

A. Pivovarov, Одеська національна академія харчових технологій

Кафедра харчової хімії, доцент

Посилання

1. Mykolenko SYu ta in. Innovatsiini metody obrobky prodovolchoi syrovyny: monohrafiia. Dnipro: Zhurfond, 2017; 224.

2. Alexande P et al. Losses, inefficiencies and waste in the global food system. Agricultural Systems. 2017; 153: 190–200. doi.org/10.1016/j.agsy.2017.01.014

3. Llipinski V et al. Reducing food loss and waste. World Resources Institute Working Paper. 2013; 1–40.

4. Pshenyshniuk HF, Makarova OV, Ivanova HS. Innovatsiini zakhody pidvyshchennia yakosti zernovoho khliba. Kharchova nauka i tekhnolohiia. 2010; 1 (10): 75‒77. doi.org/10.21691/fst.v10i1.76

5. Alekhyna NN, Ponomareva EY, Uryvskaia NV. Zernovoi khleb s produktamy pererabotky khmelia. Khranenye y pererabotka selkhozsyria. 2016; 12: 31–33.

6. Mykolenko SYu, Sokolov VYu, Penkova VV. Doslidzhennia tekhnolohichnykh aspektiv vyrobnytstva khliba iz dysperhovanoi zernovoi masy z vykorystanniam dodatkovoi pidhotovky syrovyny. Zernovi produkty i kombikormy. 2016; 4(64): 10–15. doi.org/10.15673/gpmf.v64i4.260

7. Makarova OV, Pshenyshniuk HF, Yvanova AS. Povyshenye kachestva khleba na zernovoi osnove. Zernovi produkty i kombikormy. 2015; 4 (60): 38–44. doi.org/10.15673/2313-478x.60/2015.57230

8. Marti A et al. Sprouted wheat as an alternative to conventional flour improvers in bread-making. LWT-Food Science and Technology. 2017; 80: 230–236. doi.org/10.1016/j.lwt.2017.02.028

9. Kwaśniewska-Karolak I, Rosicka-Kaczmarek J, Krala L. Factors influencing quality and shelf life of baking products. Journal on Processing and Energy in Agriculture. 2014; 18(1): 1–7.

10. Rekhvyashvyly ЕY і dr. Byotekhnolohycheskye aspekty proyzvodstva khleba s dobavlenyem poroshka kalenduly lekarstvennoi (caléndula officinális). Ahrarnыi vestnyk Urala. 2014; 1: 63–65.

11. Mardar MR, Kordzaia NR. Zminy spozhyvnykh vlastyvostei khliba z tsilnoho zerna pshenytsi z vkliuchenniam koreneplidnykh ovochiv u protsesi zberihannia. Kharchova nauka i tekhnolohiia. 2011; 1: 85–87.

12. Tkhazeplov FKh, Yvanova ZA. Vlyianye vnesenyia spyrulyny na protsess cherstvenyia khlebobulochnykh yzdelyi yz pshenychno-yachmennoi muky. Uspekhy sovremennoi nauky y obrazovanyia. 2016; 10: 41–43.

13. Falendysh N. Podovzhennia svizhosti khliba iz prorosloho zerna pshenytsi. Khranenye y pererabotka zerna. 2014; 3 (180): 34–36.

14. Andreev AN, Dmytryeva YuV. Vlyianye kamedy rozhkovoho dereva na svoistva y kachestvo pshenychnoho khleba. Nauchnыi zhurnal NYU YTMO: Protsessy і apparaty pіshchevykh proіzvodstv. 2016; 1: 107–117.

15. Davidou S et al. A contribution to the study of staling of white bread: Effect of water and hydrocolloid. Food Hydrocolloids. 1996; 10: 375–383. doi.org/10.1016/S0268-005X(96)80016-6

16. Gray JA, Bemiller JN. Bread Staling: Molecular Basis and Control. Comprehensive Reviews in Food Science and Food Safety. 2003; 2 (1): 1–21. https://doi.org/10.1111/j.1541-4337.2003.tb00011.x

17. Monteau JY et al. Water transfer in bread during staling: Physical phenomena and modelling. Journal of Food Engineering. 2017; 211: 95–103. doi.org/10.1016/j.jfoodeng.2017.04.016

18. Najafabadi L et al. Impact of baking conditions and storage temperature on staling of fully and part-baked Sangak bread. Journal of Cereal Science. 2014; 1: 151–156. doi.org/10.1016/j.jcs.2014.02.004

19. Huang L et al. Use of fermented glutinous rice as a natural enzyme cocktail for improving dough quality and bread staling. RSC Advances. 2017; 7 (19): 11394–11402.

20. Torrieri E et al. Effect of sourdough at different concentrations on quality and shelf life of bread. LWT-Food Science and Technology. 2014; 56: 508–516. doi.org/10.1016/j.lwt.2013.12.005

21. Marti A et al. Flour from sprouted wheat as a new ingredient in bread-making. LWT-Food Science and Technology. 2018; 89: 237–243. doi.org/10.1016/j.lwt.2017.10.052

22. Pivovarov OA, Mykolenko SYu. Deryvatohrafichni doslidzhennia tista, pryhotovanoho z vykorystanniam plazmokhimichno aktyvovanykh vodnykh rozchyniv. Kharchova nauka i tekhnolohiia. 2011; 3; 69–72.

23. Fadda S et al. Bread staling: updating the view. Comprehensive Reviews in Food Science and Food Safety. 2014; 13: 473–492. doi.org/10.1111/1541-4337.12064

24. Naumenko NV. Yssledovanye vlyianyia ultrazvukovoho vozdeistvyia na skorost protekanyia protsessov cherstvenyia khleba. Materyalы konferentsyi «Nauka YuUrHU». 2015; 608–610.

25. Naumenko NV. Vlyianye faktorov fyzycheskoi pryrody na skorost protekanyia protsessov cherstvenyia khleba. Vestnyk Yuzhno-Uralskoho hosudarstvennoho unyversyteta. Seryia: Pyshchevуe і byotekhnolohyy. 2015; 3(3): 38–43.

26. Aibara S, Esaki K. Effects of high-voltage electric field treatment on bread starch. Bioscience, Вiotechnology, and Вiochemistry. 1998; 11: 2194–2198. doi.org/10.1271/bbb.62.2194

27. Pivovarov OA, Mykolenko SYu. Aktyvovana plazmoiu voda v khlibopekarskomu vyrobnytstvi: monohrafiia. Dnipropetrovsk: PP Aktsent. 2015; 203.

28. Pivovarov A, Mykolenko S, Honcharova O. Biotesting of plasma-chemically activated water with use of hydrobi-onts. Eastern-European Journal of Enterprise Technologies. 2017; 4: 44–55. doi.org/10.15587/1729-4061.2017.107201

29. Mykolenko SYu ta in.Vplyv plazmokhimichno aktyvovanoi vody na vuhlevodno-amilaznyi kompleks zerna pshenytsi. Zernovi produkty i kombikormy. 2016; 1(61): 11–16. dx.doi.org/10.21691/gpmf.v61i1.97

30. Pivovarov A. A. et al. Contact nonequilibrium plasma as a tool for treatment of water and aqueous solutions: Theory and practice. Russian Journal of General Chemistry. 2015; 85: 1339–1350. doi.org/10.1134/S1070363215050497

31. Mykolenko SYu, Hez YaV. Doslidzhennia vplyvu speltovoho i harbuzovoho boroshna na zminu spozhyvchykh kharakterystyk khliba. Prodovolchi resursy. Zbirnyk naukovykh prats. 2017; 9: 228–234.

32. Holovkova TA. Deiaki aspekty hihiienichnoi diahnostyky navkolyshnoho seredovyshcha. Aktualni problemy transportnoi medytsyny: navkolyshnie seredovyshche; profesiine zdorovia; patolohiia. 2015; 2: 23–27.