Кемерово, Кемеровская область, Россия
An important strategic objective of the food industry is to meet the demands of all categories of the population in high-quality, biologically valuable, and safe food. At present, structured products based on dairy raw materials are commonly used. Food materials used to generate the necessary rheological properties or modify the existing properties for food systems that adjust or form the consistency of food products are referred to as structure-stabilizing agents. Both individual ingredients and complex mixtures thereof can be structure-stabilizing agents. The use of these agents contributes to an increase in the density and to the formation of a specific structure of the food product, which is retained even after heat treatment. In this study, the composition and properties of structure-stabilizing agents for products based on dairy raw materials have been analyzed. The following characteristics have been selected to examine: bulk density, viscosity, the fraction of undissolved residue, microvoid content, specific volume, specific surface area, and characteristic diameter. The dynamics of structural changes that occur during the interaction with the solvent have been analyzed from micrographs. The weight fraction of chemical elements (oxygen, nitrogen, carbon, sodium, chlorine) has been determined via analyzing the spectrophotometric profile.
structure-stabilizing agents, modification, structure, dairy products, spectrophotometric analysis
INTRODUCTION
At present, the production of structured products based on dairy raw materials is one of the most dynamically developing industrial sectors [6]. The quality of dairy products, along with other parameters, is determined by their structure and consistency, which depend on the proper implementation of the production process. The development of modern technological prin-ciples of food production is associated with the search for universal methods for impacting multicom-ponent aqueous systems; one of these methods is the use of food structure-stabilizing agents [7]. The role of structure-stabilizing agents is to provide a good consistency, which does not change during storage and exhibits stability during the process implementation.
The production of stabilized products based on dairy raw materials is characterized by the structure formation owing to the coagulation of casein at the isoelectric point [8]. In this case, the stabilizing agents used in food production must hinder the separation of the product and the isolation of whey; when using fillers and additives, structure-stabilizing agents must provide the uniformity of their distribution over the volume during packing and subsequent storage. The use of structure-stabilizing agents can provide the for-mation of a gel structure at pH values other than the isoelectric point [1]. Moreover, using structure-stabilizing agents, it is possible to targetedly adjust the structural-mechanical and physicochemical properties, organo-leptic parameters, and quality of the end product [3].
Stabilizing systems are commonly used in the dairy industry [9]. Among the currently known structure-stabilizing agents, anionic polysaccharides—both natural (pectin, agar, agaroid, pyrophosphate) and artificial (oxidized starch)—are extensively employed. Alginates, cellulose derivatives, carboxymethyl cellulose (CMC), and various gums enjoy wide application abroad [4]. Stabilizing agents are promising because their composition and properties are constantly being improved. The use of stabilizing agents improves the quality of products (particularly consistency) and increases the yield and the shelf life [2].
Examination of the structure formation laws in dairy systems is of significant theoretical and practical importance because it provides the formation of disperse systems with desired structural-mechanical properties.
The described studies were conducted in conjunction with A.N. Arkhipov and A.V. Pozdnyakova.
OBJECTS AND METHODS OF RESEARCH
To examine the composition of the structure-stabilizing agents, a JEOL JED-2300 analysis station was used; the electron probe microanalysis conducted with this instrument yielded spectrometric profiles that can be used to determine the chemical composition of the structure-stabilizing agents [5].
1. Arkhipov, A.N., Masunov, N.A., and Pozdnyakova, A.V., Issledovanie mikrostruktury i komponentnogo sostava pishchevykh stabilizatorov (A study of the microstructure and component composition of food stabilizers), Vestn. Krasnoyarsk. Gos. Agrarn. Univ. (Bull. Krasnoyarks State Agrar. Univ.), 2012. № 1. P. 178.
2. Arkhipov, A.N. and Pozdnyakova, A.V., Issledovanie vliyanya massovoi doli stabilizatora KMC AKUTSEL´ 3265 na prodolzhitel´nost´ skvashivaniya molochnokislymi mikroorganizmami serii "DELVO-YOG" (A study of the effect of the weight fraction of the CMC Akucell 3265 stabilizer on the duration of ripening with lactic microorganisms of the DELVO-YOG series), Materialy Mezhdunarodnoi konferentsii "Innovatsionnoe razvitie malykh gorodov Rossii: nauchnyi i tekhnologicheskii potentsial" (Proc. Int. Conf. on Innovative Development of Small Towns in Russia: The Scientific and Technological Potential), Meleuz, 2011, P. 65.
3. Prosekov, A. Yu., Sovremennye aspekty proizvodstva produktov pitaniya: Monografiya (Modern Aspects of Food Production: A Monograph) (Kemerov. Tekhnol. Inst. Pishch. Prom-st., Kemerovo, 2005).
4. Arkhipov, A.N., Pozdnyakova, A.V., Krupin, A.V., and Vakanova, M.V., Sravnitel´noe issledovanie mikrostruktury i sostava stabilizatorov rastitel´nogo proiskhozhdeniya (A comparative study of the microstructure and composition of stabilizers of vegetable origin), Tekh. Tekhnol. Pishch. Proizvod. (Tech. Technol. Food Prod.), 2011. № 4. P. 14.
5. Prosekov, A. Yu., Babich, O.O., and Sukhikh, S.A., Sovremennye metody issledovaniya syr´ya i biotekhnolo-gicheskoi produktsii (Modern Methods for Analyzing Raw Materials and Biotechnology Products) (Kemerov. Tekhnol. Inst. Pishch. Prom-st., Kemerovo, 2013).
6. Monaci, L., Tregoat, V., van Hengel, A.J., et al., Milk allergens, their characteristics and their detection in food: A review, Eur. Food Res. Technol., 2006. V. 223. P. 149.
7. Poonnov, P., Tansakul, A., and Chinnan, M., Artificial neural network modeling for temperature and moisture content prediction in tomato slices undergoing microwave-vacuum drying, Journ. Food Sci., 2007, V. 72. 2007. № 1. P. E42.
8. Pozdnyakova, A.V., Arkhipov, A.N., Kozlova, O.V., and Ostroumov, L.A., Composition and microstructure investigation for the modeling and classification of dietary fiber derived from plants, Foods Raw Mater., 2014. V. 1. № 2. P. 40. doihttps://doi.org/10.12737/4129.
9. Wal, J.M., Cow´s milk proteins/allergens, Ann. Allergy Asthma lmmunol., 2002. V. 89. P. 3.
