The application of osmotic dehydration in the technology of producing candied root vegetables

Authors

DOI:

https://doi.org/10.15587/1729-4061.2020.204664

Keywords:

osmotic dehydration, vacuum drying chambers, candied table beets, root vegetables, mass fraction of sucrose

Abstract

The improved technology of the production of candied table and sugar beet, carrot, parsnip, root celery, and rutabaga was offered. The technology is based on increasing the osmotic pressure in the cells of plant raw materials by increasing the concentration of solids. The advanced technology involves the use of the process of osmotic dehydration in 70 % sugar solution of the temperature of 50 °C as an alternative to the process of blanching. This ensures the reduction of drying time up to 1 hour due to the partial transition of water from root cells into the sugar solution. Inactivation of enzymes, which occurs during dehydration, positively influences the organoleptic quality indicators of candied vegetables. Candied vegetables have a good smell, characteristic natural color, and can be used as a ready-made dessert dish and fillers in the production of fermented milk products and confectionery.

The influence of the traditional methods for processing plant raw materials on its nutritional and biological value was analyzed. The methods of making candied vegetables were studied and the shortcomings of these methods were revealed. A dataset on the modes of maintenance of dehydration and drying processes was obtained. The technology which includes: crushing raw material, osmotic dehydration, drying in vacuum drying chambers was proposed. The technology involves crushing raw material into cubes with the dimensions of 5/5/5 mm. Osmotic dehydration of raw materials occurs in the oversaturated sugar solution for 2.5 hours at the temperature of 50 °C with subsequent drying in vacuum drying chambers for 1 hour at 50 °C.

The design of the apparatus for osmotic dehydration, which ensures maintenance of the assigned temperature mode, preparation, and stirring the sugar solution, constant stirring of raw materials with the purpose of mass exchange intensification was developed. 

The organoleptic (appearance, consistency, taste, smell, color) and physical and chemical quality indicators (mass fraction of sucrose, moisture, total ash) of candied table beets manufactured according to the improved technology were analyzed. Their compliance with the requirements of DSTU 6075:2009 was established.

Author Biographies

Maryna Samilyk, Sumy National Agrarian University Herasyma Kondratieva str., 160, Sumy, Ukraine, 40000

PhD

Department of Technology of Milk and Meat

Anna Helikh, Sumy National Agrarian University Herasyma Kondratieva str., 160, Sumy, Ukraine, 40000

PhD

Department of Technology of Milk and Meat

Natalia Bolgova, Sumy National Agrarian University Herasyma Kondratieva str., 160, Sumy, Ukraine, 40000

PhD, Associate Professor

Department of Technology of Milk and Meat

Vоlоdymyr Potapov, Kharkiv State University of Food Technology and Trade Klochkivska str., 333, Kharkiv, Ukraine, 61051

Doctor of Technical Sciences, Professor

Department of Power Engineering, Engineering, Physical and Mathematical Disciplines

Sergei Sabadash, Sumy National Agrarian University Herasyma Kondratieva str., 160, Sumy, Ukraine, 40000

PhD, Associate Professor

Department of Engineering Technology of Food Production

References

  1. FAO/WHO/UNU. Dietary protein quality evalution in human nutrition. Report of an FAO Expert Consultation (2013). Food and agriculture organization of the united nations Rome, 92, 57.
  2. Snezhkin, Yu. F., Husarova, O. V., Shapar, R. O. (2017). Intensification of moisture remove in drying process fruit and vegetable raw materials. Scientific Works, 81, 1, 90–93. Available at: http://nbuv.gov.ua/UJRN/Np_2017_81_1_20
  3. Mekhilef, S., Faramarzi, S. Z., Saidur, R., Salam, Z. (2013). The application of solar technologies for sustainable development of agricultural sector. Renewable and Sustainable Energy Reviews, 18, 583–594. doi: https://doi.org/10.1016/j.rser.2012.10.049
  4. Gupta, P. M., Das, A. S., Barai, R. C., Pusadkar, S. C., Pawar, V. G. (2017). Design and Construction of Solar Dryer for Drying Agricultural Products. International Research Journal of Engineering and Technology, 04 (03), 1946–1951.
  5. Kitamura, Y., Yamazaki, K. (2010). Pat. US20130126102A1. Vacuum-pressure spray-drying method and vacuum-pressure spray-drying device. No. 13/812,818; declareted: 29.07.2010; published: 23.05.2013.
  6. Ishwarya, S. P., Anandharamakrishnan, C., Stapley, A. G. F. (2015). Spray-freeze-drying: A novel process for the drying of foods and bioproducts. Trends in Food Science & Technology, 41 (2), 161–181. doi: https://doi.org/10.1016/j.tifs.2014.10.008
  7. Zhang, G., Zheng, Y., Zhang, J. (2015). Pat. No. CN105123897 (A). Cold storage method of vegetables in agricultural and sideline products. declareted: 25.08.2015; published: 09.12.2015.
  8. Cheng, S.-C. (2009). Pat. No. TW201117726 (A). Cold storage method for fruit and vegetable. declareted: 27.11.2009; published: 01.06.2011.
  9. Beyko, L. (2016). Canning vegetables cold. Prodovolcha industriya APK, 5, 18–22. Available at: http://nbuv.gov.ua/UJRN/Piapk_2016_5_6
  10. Seidel, K., Kahl, J., Paoletti, F., Birlouez, I., Busscher, N., Kretzschmar, U. et. al. (2013). Quality assessment of baby food made of different pre-processed organic raw materials under industrial processing conditions. Journal of Food Science and Technology, 52 (2), 803–812. doi: https://doi.org/10.1007/s13197-013-1109-5
  11. Moscetti, R., Haff, R. P., Ferri, S., Raponi, F., Monarca, D., Liang, P., Massantini, R. (2017). Real-Time Monitoring of Organic Carrot (var. Romance) During Hot-Air Drying Using Near-Infrared Spectroscopy. Food and Bioprocess Technology, 10 (11), 2046–2059. doi: https://doi.org/10.1007/s11947-017-1975-3
  12. Sniezhkin, Yu. F., Petrova, Zh. O., Paziuk, V. M. (2012). Hidrotermichna obrobka funktsionalnoi syrovyny. Naukovi pratsi Odeskoi natsionalnoi akademiyi kharchovykh tekhnolohiy, 41 (1), 13–18.
  13. Krapivnytska, I., Potapov, V., Gurskyi, P., Pertsevyi, F. (2015). Study of moisture structurization and binding form changes in pectin gels by differential scanning calorimetry. Eastern-European Journal of Enterprise Technologies, 1 (6 (73)), 48–52. doi: https://doi.org/10.15587/1729-4061.2015.37358
  14. Yadav, A. K., Singh, S. V. (2012). Osmotic dehydration of fruits and vegetables: a review. Journal of Food Science and Technology, 51 (9), 1654–1673. doi: https://doi.org/10.1007/s13197-012-0659-2
  15. Ahmed, I., Qazi, I. M., Jamal, S. (2016). Developments in osmotic dehydration technique for the preservation of fruits and vegetables. Innovative Food Science & Emerging Technologies, 34, 29–43. doi: https://doi.org/10.1016/j.ifset.2016.01.003
  16. Khan, M. R. (2012). Osmotic Dehydration Technique for Fruits Preservation – A Review. Pakistan Journal of Food Science, 22 (2), 71–85.
  17. Phisut, N. (2012). Factors affecting mass transfer during osmotic dehydration of fruits. International Food Research Journal, 19 (1), 7–18.
  18. Tortoe, C. (2010). A Review of Osmodehydration for Food Industry. African Journal of Food Science, 4 (6), 303–324.
  19. Slyvka, N. B., Bilyk, O. Y., Mikhailytska, O. R., Nagovska, V. O. (2019). Improvement of technology of curd products with succade from pumpkin. Scientific Messenger of LNU of Veterinary Medicine and Biotechnologies, 21 (92), 47–52. doi: https://doi.org/10.32718/nvlvet-f9209
  20. Melnyk, L. M., Matko, S. V., Bessarab, O. S., Kostiuchok, N. V., Martynova, Ya. O. (2015). Pat. No. 103612 UA. Sposib pryhotuvannia tsukativ z kartopli. No. u201505692; declareted: 09.06.2015; published: 25.12.2015, Bul. No. 4.
  21. Telezhenko, L. M., Zolovska, O. V. (2013). Pat. No. 83283. Sposib vyrobnytstva tsukativ z topinambura. No. u201305222; declareted: 23.04.2013; published: 27.08.2013, Bul. No. 4.
  22. Nepochatykh, T. A., Zakharenko, V. O. (2003). Pat. No. 57419 UA. Method for producing candied products from pumpkin and carrot. No. u2002107839; declareted: 03.10.2002; published: 16.06.2003, Bul. No. 6.
  23. Holinska, Ya. A., Bilenka, I. R. (2016). Pat. No. 108602 UA. Sposib pryhotuvannia ovochevykh tsukativ z koreneplodu. No. u201600377; declareted: 18.01.2016; published: 25.07.2016, Bul. No. 14.
  24. Samilyk, M., Helikh, A., Bolgova, N., Ryzhkova, T., Sirenko, I., Fesyun, O. (2020). Substantiation of the choice of fillers for cottage cheese masses. EUREKA: Life Sciences, 2, 38–45. doi: https://doi.org/10.21303/2504-5695.2020.001210
  25. Samilyk, М., Zarubina, M. (2019). Prospects for the use carrotin candieds in the production of cheese mass. International scientific and practical conference “Science, engineering and tehnology: global and current trends”. Prague, 90–92.
  26. GOST 28561-90. Fruit and vegetable products. Methods for determination of total solids or moisture (2011). Moscow: Standartinform.
  27. DSTU 4954:2008. Fruits and vegetables products. Methods for determination of sugars (2009). Kyiv: Derzhspozhyvstandart, 21.
  28. GOST 15113.8-77. Food concentrates. Methods for determination of ash (2003). Moscow: IPK Izdatel'stvo standartov, 6.
  29. DSTU 6075:2009. Candied fruit. Specifications (2009). Kyiv: Derzhspozhyvstandart Ukrainy, 21.
  30. Potapov, V., Yakushenko, E. (2013). Optimization of energy consumption for the drying process with pre-heating of the material. Sixth Nordic Drying Conference. Copenhagen, 56.

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Published

2020-06-30

How to Cite

Samilyk, M., Helikh, A., Bolgova, N., Potapov, V., & Sabadash, S. (2020). The application of osmotic dehydration in the technology of producing candied root vegetables. Eastern-European Journal of Enterprise Technologies, 3(11 (105), 13–20. https://doi.org/10.15587/1729-4061.2020.204664

Issue

Vol. 3 No. 11 (105) (2020): Technology and Equipment of Food Production

Section

Technology and Equipment of Food Production

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Copyright (c) 2020 Maryna Samilyk, Anna Helikh, Natalia Bolgova, Vоlоdymyr Potapov, Sergei Sabadash

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