Affiliation
a M.M. Dzhambulatov Dagestan State Agricultural University, Makhachkala, Russia
b Caspian Institute of Biological Resources – a separate division of the Dagestan Federal Research Center of the Russian Academy of Sciences, Makhachkala, Russia
Copyright ©Guseynova et al. This is an open access article distributed under the terms of the Creative Commons Attribution 4.0. (
http://creativecommons.org/licenses/by/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material for any purpose, even commercially, provided the original work is properly cited and states its license.
Received 05 February, 2021 |
Accepted in revised form 01 March, 2021 |
Published 25 March, 2021
Abstract
Introduction. Low-temperature freezing technology extends the shelf life of perishable fruits as it causes a sharp slowdown in the biochemical and microbiological processes in frozen products. However, it cannot provide complete destruction of microorganisms.
The present research featured the reaction of apricot microbiota to the technological techniques of shock freezing. The research objective was to study the effect of low-temperature freezing modes (t = –25, –30, and –35°C), storage time (3 and 9 months), methods, and defrosting modes (in air at t = 5 and 22°C; in water at t = 5, 16, and 22°C; under the effect of microwave irradiation) on the surface microflora of apricots.
Study objects and methods. The experiment featured apricots of the varieties Uzden, Untsukulskiy Pozdniy, Honobah, Krasnoshchyokiy, and Shalakh. The microbiological profile of defrosted apricots was based on the State Standard.
Results and discussion. Fast freezing at t = –25°C provided a better inhibition of epiphytic microflora than at t = –30 and –35°C: aerobic-mesophilic and optionally anaerobic microorganisms – by 65.2–68.6%, yeast – by 61.5–69.0%, and mold – by 59.3–68.4%,
compared to their initial content on fresh apricots. During the initial period of refrigeration storage, the number of microorganisms decreased, while the subsequent nine-month storage (t = –18°C) led to a slight increase in microbiota. After nine months of storage, the number of microorganisms on defrosted fruits, depending on the variety, was the following: aerobic-mesophilic and optionally anaerobic microorganisms – 1.2×103–2.0×103 CFU/g, yeast – 14–26 CFU/g, and molds – 75–108 CFU/g. Defrosting of apricots by microwave irradiation resulted in a greater destruction of microorganisms than after traditional thawing in air and water.
Conclusion. The results of microbiological studies indicate that the shock freezing technology ensures the production of quick-frozen apricots that meet the requirements of Technical Regulations of the Customs Union No. 021/2011.
Keywords
Apricots,
microbiological insemination,
low-temperature freezing,
refrigeration storage,
defrosting
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How to quote?
Guseynova BM, Asabutaev IH, Daudova TI. Effect of Freezing Modes, Storage Time, and Defrosting Methods on
Microbiological Quality Parameters of Apricots. Food Processing: Techniques and Technology. 2021;51(1):29–38. (In Russ.).
https://doi.org/10.21603/2074-9414-2021-1-29-38.