USE OF BAR PROCESSING TO INCREASE THE SHELF LIFE OF VITAMINIZED SAUSAGES AND THEIR USE FOR THE CORRECTION OF STUDENTS' HEALTH
Аннотация и ключевые слова
Аннотация (русский):
One of the priority directions of state policy in the field of healthy food is the development and integration of enriched foodstuffs with an increased expiration date into production. The purpose of researches is the study of effect of bar processing on the periods of storage of boiled sausages enriched with vitamin premix. The test samples of boiled sausages were processed under the pressure of 800 MPa within 3 minutes at a temperature of 0 … +4°C by means of a hydrostat after the end of the technological process. The control samples of boiled sausages were not processed under pressure. The safety of boiled sausages was estimated by organoleptic and microbiological indicators and рН, the content of vitamins in the product was researched in 8 and 16 days of storage. It has been established that in 16 days of storage the control samples of sausages did not conform to the requirements of regulating documentation; the shift of рН to the alkaline side, the increase in the quantity of mesophilic aerobic and facultative and anaerobic microorganisms has been noted. After 16 days of storage the content of PP and C vitamins in the control samples of sausages authentically decreased by 17.6% and 93.4% while the decrease in the test samples was 4.1% and 12.0%. The antioxidant activity of test samples of sausages is authentically 71.3% higher than that of the control samples (0.12 ± 0.04 mol equiv/dm3). Against a background of use of vitaminized sausages an authentic increase in the antioxidant activity of catalase and ceruloplasmin is noted in the blood of students of the test group. Thus, it is established that the processing of boiled sausages enriched with vitamins, under high pressure has a bactericidal effect on microbic cells, prevents proteolysis, saves vitamins and, respectively, increases the expiration date of a foodstuff. The calculations for design of a high pressure hydrostat for foodstuff processing have been performed.

Ключевые слова:
processing under high pressure, meat raw materials, meat products, technical regulations, hydrostat, antioxidants, indicators of quality and safety
Текст
Текст произведения (PDF): Читать Скачать

INTRODUCTION 75% of the population of the Russian Federation feel lack of irreplaceable micronutrients in their diet which provides the deterioration of health, a decrease in working capacity, an increase in fatigue and the development of various diseases. One of the etiological factors of hypovitaminoses is a decrease in the quantity of vitamins in foodstuffs due to the use of thermal technologies of processing of food raw materials providing a decrease in a share of biologically active agents in foodstuffs. In this regard, the development of enriched foodstuffs and the provision of stability of micro-nutrients in the course of storage is one of the priority directions of the modern food industry. In this case, foodstuff processing under high pressure deserves special attention. The main scope of the method of high pressures in the world today is athermic preservation (“cold pasteurization”, pascalization) of foodstuffs aimed at the inactivation of microorganisms and enzymes of the processed environment. In the 90-ies of the last century in Japan the first wave of popularity of jams of strawberry, kiwi and apples received by the use of high hydrostatic pressure began, in 1997 barotechnology was first used by the company Fresherized Foods - a world leader in the production of Guakamole (a traditional Mexican snack of avocado pulp), in 2007 approximately 120 barometric plants were put into operation for production of "new" products commercially [1] worldwide. More than 80% of the equipment functioning today were collected and produced after 2000 which testifies that this trend tends to the accelerated development and expansion of its scope [2]. Today the following countries dominate in this trend of production: - North America (USA, Canada, Mexico); - Europe (Spain, Italy, Portugal, France, Great Britain, Germany); - Asia (Japan, China, North Korea); - Australia. The total of the products processed under pressure is steadily increasing in the world. According to the data [1] approximately 200,000 tons of this type of products (approximately 450 million pounds/year) were manufactured and delivered in sale during 2008. The expansion of bar processing of food products is related to the fact that using the method of cold preservation the prevention of microbiological damage is possible. It has been proved during the repeated researches that the barometric effect of the pressure of 600 MPa at 20°C during 180 sec is capable to liquidate causative agents of listeriosis (Listeria monocytogenes) in meat and meat products, and also to inactivate other life-threatening microorganisms - colibacillus (E. coli), salmonellas (Salmonella), cholera vibrio (Vibrio), the most of species of mold mushrooms and pathogenic bacteria [3]. Today the considered technology is applicable only for inhibition of processes of growth and reproduction of vegetative forms of bacteria, however the combination of pressure and temperature is capable to provide the inactivation of spores of microorganisms as well. Thus, for example, the spores of Clostridium botulinum and some representatives of the sorts Bacillus and Clostridia can be destroyed as a result of synergic effect of the temperature and barometric factor. Such an effect provides to reduce a thermal effect by means of the pressure additionally imparted to the system [4-6]. The resistance of sporous forms is much higher than vegetative ones because of the presence of a serious protective mechanism in the first ones. Thus, it is known it is necessary to put a product under the pressure of 300-400 MPa at 25°C for several minutes to deactivate yeast, however, to destroy yeast ascospores a higher pressure and a longer effect is required. Spores of Clostridium botulinum are considered the steadiest among bacterial pathogenic spores, and Bacillus amyloliquefaciens disputes - among nonpathogenic ones [5]. It has also been proved that the pressure over 200 MPa in the temperature condition not above 45°C is capable to inactivate effectively the vegetative forms of practically all pathogenic microorganisms and those which spoil the food with no effect on flavor characteristics [7]. However, it is important to note that the efficiency of process depends, to a greater degree, on the type and complexity of the organization of microorganisms, the chemical composition and pH of the processed environment, and also on water activity. Gram-negative bacteria are more sensitive to the effect of high pressure, than gram-positive ones are. The barometric effect causes the destruction of cellular membranes and intracellular proteins playing the major role in the activity of microorganisms, this all provides the degradation of cellular structures and final destruction of a cage in general. The shift toward the acidic pH and the increase in pressure have a synergy effect during the elimination of microorganisms. Due to the increase in acidity of the environment, the inhibition of activity of water molecules occurs which provides a considerable delay of processes of inactivation induced by extra-high pressure [4]. Today the technology of high hydrostatic pressure includes two main methods - a batch and a semicontinuous one. Of practical use is, mainly, the batch technology that presumes that the packed lot of goods is placed into the chamber, then is hermetized and filled with a transfer medium (water or other low-molecular liquids). The targeted pressure imparted to the environment is transferred to the elastic walls of packing and thereof the compression of product [8, 9] occurs. The semicontinuous methods are not at all perfect today, both in the power and economic aspects. They have been created for the purpose of implementation of direct compression of liquid foodstuffs. Fig. 1 presents the ratio between various classes of foodstuffs (%) the technology of high pressures can be applied to today. Fig. 1. Industrial use of high hydrostatic pressure for processing of different groups of foodstuffs [10]. It is established that during the processing under the pressure of 130 MPa there is inhibition of growth of microorganisms in beef for a week, the color of meat improves, the gained effect remains for 3 days at a storage temperature +4°C [9]. As a result of the researches, Han J.M. and Ledward D.A. found out that the rigidity of muscular tissue of beef increases with the increase in pressure from 200 to 800 MPa (at a constant temperature from 20 to 40°C), but considerably decreases during the use of pressure at a level of 200 MPa (at a temperature of 60 and 70°C) [10]. A Bai Y. and coauthors noted that after processing under high pressure (300-700 MPa) within 20 min. considerable changes of organoleptic properties of meat can be observed. They also recorded some modifications in the microscopic structure of myofibrils of the muscular tissue of cattle and mutton [11]. Qin H. and others proved that the activity of calpains in the course of bar processing decreases, but the activity of acid and alkaline phosphatases does not significantly differ from the values of control samples. The pressure of about 100-200 MPa is capable to inactivate calpastatin (an inhibitor of activity of calpain) more rapidly than calpain itself is [12]. L.G. Vinnikova obtained some quite interesting results. She chose the processing under the pressure in the interval from 500 to 700 MPa during 30-60 sec as an optimum technological mode, which provided to inhibit the activity of acid phosphatases when imparting the maximum pressure (700 MPa) to the samples and thus to reach full culinary readiness with the organoleptic indicators corresponding to a boiled meat product. The mass losses of the target product in the course of processing were also reduced by 35% in comparison with the thermal effect. Thus, almost a hundred percent outcome of the finished product was stated [13]. As for the cost of modern equipment for processing, it varies from 500 000 to 2.5 million dollars depending on the power and extent of automation. The internal volume of a vessel varies from 30 to more than 600 liters [14]. The use of high hydrostatic pressure in food industry becomes more and more demanded every year. The interest of use of this particular technology is that it is capable to inactivate the action of microorganisms and fermental complexes without the inhibition of the energy and biological value. Today one of the priority directions of state policy in the field of healthy nutrition and replacement of foreign food technologies is the development and integration of the foodstuffs enriched with irreplaceable micronutrients and also of new domestic processing equipment for food industry into production. The provision of safety of the biologically active agents put into the formulation throughout the entire period of storage deserves special attention. The aim of work is the research of effect of bar processing on the periods of storage of boiled sausages enriched with vitamins, the assessment of efficiency of their use for correction of the state of health of students and the development of equipment alternative to import equipment capable to produce the pressure not less than 1200 MPa providing to use it in food industry. OBJECTS AND METHODS OF STUDY The objects of researches were boiled sausages in a nylon cover "Amilyuks" with a period of storage of 4 days at a temperature from 2 to 6°C, enriched with the vitamin premix 730/4 produced by ValetekProimpeks, CJSC in the amount of 150 g per 100 kg of the basic raw materials. The control samples of boiled sausages enriched with vitamin premix were not processed under high pressure. The test samples of boiled sausages enriched with vitamins were processed after the end of the technological process under the pressure of 800 MPa within 3 minutes at a temperature of 0 … +4°С by means of an experimental plant - a hydrostat (Fig. 2) with the following technical characteristics: the process pressure is 800-1000 MPa; the maximum pressure is 1200 MPa, the time of process stabilization is 2 to 3 min, the process liquid is a mix of industrial oil and glycerin. Fig. 2. High pressure plant (hydrostat). The safety of boiled sausages was estimated according to the organoleptic and microbiological indicators and рН, the content of vitamins in the product was researched in 8 and 16 days of storage. The microbiological indicators are in accordance with GOST R 54354-2011 “Meat and meat products. General requirements and methods of microbiological testing”, GOST 31747-2012 (ISO 4831:2006, ISO 4832:2006) “Food products. Methods for detection and quantity determination of coliforms”.Using the pH-potentiometric method, vitamins - using the fluorimetric method.The antioxidant activity - using the potentiometric method. The shift of potential Pt electrode made using screen-printing technique in the mediator system K3[Fe(CN)6]/K4[Fe(CN)6], observed during the administration of antioxidants (a sample) into the solution was the source of information of antioxidant activity. This shift occurs due to the change of ratio of the oxidized and reduced forms of components of mediator system as a result of the following reaction: . The researches were performed using a lab-scale plant in Institute of Metal Physics, Ural Department of the RAS (Yekaterinburg) and at the Department of Food Engineering of Ural State Economic University (Yekaterinburg). The statistical processing of results was carried out with the use of the standard computer programs Microsoft Excel XP, Statistica 8.0. RESULTS AND DISCUSSION Table 1 presents the organoleptic indicators of boiled sausages in 8 and 16 days of refrigerating storage at a temperature of +4°C. It follows from the data of Table 1 that after 8 days of storage the control and test samples of sausages conformed to the requirements of the Technical regulation of the Customs union “About safety of meat and meat products” (TR TS 034/2013). In 16 days of storage the control samples of sausages had a slippery and damp surface, lost their elasticity, differed in an ammoniac smell while the test samples conformed to the requirements of the regulating documentation. Table 1. Organoleptic indicators of control and test samples of boiled sausages in 8 and 16 days of refrigerating storage at a temperature of +4 °C Parameter Group Group 1 (control) Group 2 (test) After 8 days of storage Appearance Bars with a clean and dry surface Bars with a clean and dry surface Consistence Delicate and juicy Delicate and juicy Color and look in the cut Pink, uniform mincemeat, evenly mixed Pink, uniform mincemeat, evenly mixed Smell and taste Peculiar to this type of product, without foreign flavor and smell, with the aroma of spices, moderately salty Peculiar to this type of product, without foreign flavor and smell, with the aroma of spices, moderately salty After 16 days of storage Appearance Bars with a clean and slippery surface Bars with a clean and dry surface Consistence Delicate, juicy and less elastic Delicate and juicy Color and look in the cut Pink, uniform mincemeat, evenly mixed Pink, uniform mincemeat, evenly mixed Smell and taste Ammoniacal Peculiar to this type of product, without foreign flavor and smell, with the aroma of spices, moderately salty Researches of рН of sausages in the course of their storage (Fig. 3) have been performed. Fig. 3 shows that the shift of pH to the alkaline side in the course of storage of control samples of boiled sausages is noted; the most significant changes are in the control samples which testifies an active activity of the residual microflora in a foodstuff providing proteolysis and, respectively, the accumulation of nitrogenous bases. The obtained data are coordinated with the results of organoleptic (Table 1) and microbiological researches. An authentic increase in рН has not been noted in the test samples. 7.4 7.2 7.0 6.8 6.6 6.4 6.0 5.8 5.6 Fig. 3. Dynamics of рН of boiled sausages during their storage. A significant increase in the content of mesophilic aerobic and facultative and anaerobic microorganisms has been noted in the control samples of boiled sausages. The quantity of bacteria was 1.6х103 in 8 days of storage and 2.7х103 in 16 days which exceeds the requirements of TRTS 034/2013. The processing of boiled sausages under high pressure provided to receive a sterile foodstuff. Mesophilic aerobic and facultative and anaerobic microorganisms in the test samples of sausages have not been found during the entire period of storage. Table 2 presents the content of B1, B2, PP and C vitamins in the course of their storage. It follows from the data of Table 2 that in the course of storage of boiled sausages enriched with vitamin premix a decrease in the quantity of vitamins both in the control and test samples is noted, in particular, after 8 days of storage the quantity of B1, B2, PP and C vitamins decreased by 5.3%; 1.3%; 2.7% and 13.6% in the control samples. After 16 days of storage the content of PP and C vitamin in the control samples of sausages authentically decreased by 17.6% and 93.4% while in the test samples it decreased by 4.1% and 12%. It follows from the obtained data that the processing of boiled sausages, enriched with vitamin premix, under the high pressure of 800 MPa does not only destroy the vitamins of mincemeat and premix, but also provides to keep them safe for the entire period of storage. Table 2. Content of B1, B2, PP and C vitamins in the course of production and storage of boiled sausages enriched with vitamin premix, mg/100g Boiled sausages Content of vitamins After the end of technological process After 8 days of storage After 16 days of storage В1 В2 РР С В1 В2 РР С В1 В2 РР С control 0.57 ± 0.05 0.75 ± 0.08 7.4 ± 0.9 30.1 ± 0.7 0.54 ± 0.05 0.74 ± 0.07 7.2 ± 0.9 28.0 ± 1.1 0.53 ± 0.05 0.73 ± 0.05 6.1 ± 0.8 2.0 ± 0.9* test 0.58 ± 0.04 0.75 ± 0.07 7.4 ± 0.5 30.0 ± 0.7 0.56 ± 0.05 0.75 ± 0.08 7.2 ± 0.8 28.2 ± 1.0 0.55 ± 0.05 0.73 ± 0.07 7.1 ± 0.9 26.4 ± 1.0* The microbiological decay of boiled sausages begins even prior to lipide oxidation, however the information of the resistance of boiled sausages to oxidation is absent in this case. In the course of oxidation of lipide components there is a rancidish taste, the color and consistence worsen and the nutrition value decreases. The process of autooxidation of lipids, during which unsaturated fatty acids react with oxygen with the formation of acylhydroperoxides or peroxides of fatty acids, proceeds according to a free radical mechanism. The substances that block or slow down the process of oxidation of lipids are called antioxidants. In this regard, we investigated the antioxidatic activity of boiled sausages (AO). As a result of researches, it has been established that the test samples of sausages had a higher AOA (0.42 ± 0.03 mol equiv / dm3), which is authentically 71.3% higher (** P ≤ 0.01) than the AOA of the control samples (0.12 ± 0.04 mol equiv/dm3). The obtained data are explained by the presence of vitamins C and E, which have an antioxidatic action, in the vitamin premix 730/4 and by the high stability of vitamins in the test samples of boiled sausages. The research of assessment of efficiency of use of enriched sausages in student nutrition was performed in South Ural State Agricultural University at the department of physical training and sport in the academic year 2015-2016. Two groups of students (young men) of the first course at the age of 18-19 were formed. The criterion for including in the research was the voluntary written consent to the participation in the experiment, the provision of necessary personal health information about themselves, the accommodation in the dorm, the meals in the university canteen and attending classes of physical culture. The criterion for dismissal was the incidence of acute infectious diseases at the time of the research or within 30 days prior to the experiment, the use of vitamins and mineral substances. Table 3 presents the scheme of researches. The assessment of nutritional level of students was performed according to the methodical recommendations (MR) of 2.3.1.2432-08 “Norms of physiological needs for energy and feedstuffs for various groups of the population of the Russian Federation”. The statistical processing of experimental data was performed by means of the computer program Statistica-6. The assessment of state of health of students was performed with the use of method of questioning and research of the antioxidant activity of blood and the indicators of a cellular link of immunity according to the standard techniques. The questioning of students regarding the assessment of their food is performed according to a five-mark grading system. It is established that only 8% of the students estimate their food as excellent, 35% - as good, 45% - as adequate and 12% - as inadequate. It should be noted that 27% of respondents complained about the state of their health. They complained about frequent headaches, rapid fatigability, weakness, drowsiness, a decrease in working capacity, frequent acute respiratory diseases (ARD), stomach pains, the lability of arterial pressure and others. The obtained data are coordinated with the assessment of actual diet where there is lack of the vital micronutrients. The criterion of the state of health of students are some indicators of antioxidant activity: antioxidant activity (AOA), the content of enzyme catalase (C) and protein ceruloplasmin (CP) in the blood of students. An authentic increase in antioxidant activity by 26.7% in the blood of students of the test group is noted against a background of the use of vitaminized sausages. Similar changes are noted in the content of catalase and ceruloplasmin. Thus, the amount of catalase and ceruloplasmin increased by 19.2% and 16.1%. The authentic changes of indicators of antioxidant protection of the organism of students of the control group are not noted. An increase in working capacity and decrease in fatigue at a background of application of vitaminized sausages is noted in the questionnaires of 61% of students of the test group. In view of the fact that the foreign equipment for processing under high pressure in the conditions of all-round compression is expensive, it is reasonable to manufacture a domestically produced hydrostat that would not yield to foreign analogs in technological parameters. Schematically a high pressure hydrostat is presented in Fig. 4. To manufacture the hydrostat strength calculations of the hydraulic cylinder of the compression chamber have been performed. 1 2 3 4 5 6 7 8 Fig. 4. Schematical design of a high pressure hydrostat for processing of objects with a liquid in the conditions of all-round compression: 1 - punch; 2 - flange; 3 - sealing; 4 - working chamber; 5 - washer; 6 - process liquid; 7 - cover; 8 - object of the research (product). Table 3. Scheme of researches Group Number of students in the group, persons Age of students, years Correction of a diet by vitaminized boiled sausages Dose and frequency of use of hematogen Control 20 18 - 19 - - Test 20 18 - 19 Inclusion of vitaminized boiled sausages in the diet 100 g daily within 20 days Strength calculations of the compression hydraulic cylinder of the high pressure hydrostat.Calculation of pressures in the compression hydraulic cylinder of the hydrostat. Design pressure according to the condition of strength Pdes1, MPa (1) Where P1max is the maximum excessive pressure in the hydraulic cylinder of the hydrostat, MPa; Patm is the atmospheric pressure, MPa. For calculation we take P1max = 1200 MPa; Patm = 0.1 MPa. Then the design pressure according to the condition of strength as per (1) As the pressures less that the atmospheric pressure are not supposed to be in the hydraulic cylinder of the hydrostat, the calculation for the chamber is performed only under the terms of strength. Calculation of thickness of the wall of the hydraulic cylinder according to the strength theory. The cylinder is made of autofretted high-tensile steel of the brand “О-АБ”. Design thickness of the wall of the hydraulic cylinder of the compression chamber , mm: (2) where Sdes1 is a design thickness of the wall of the hydraulic cylinder, mm; C1 is an addition to the design thickness considering the process of material corrosion, mm; Addition to the design thickness considering the process of material corrosion , mm (3) where A is the design rate of corrosion of the material of construction, mm/year; t is the planned service life of the hydrostat, year. For calculation we take t = 10 years and A = 0.005 mm/year according to the standard for vessels and devices under pressure. mm/year. Design thickness of the wall of the hydraulic cylinder of the compression chamber Sdes1, mm (4) As the design thickness of the wall of the hydraulic cylinder the greatest of the received values under the terms of strength Sn1, mm, and stability Sstab1, mm, is chosen. As the calculation under the terms of stability is not performed, then Sdes1 = Sn1. Design radius of the hydraulic cylinder of the compression chamber under the terms of strength Rc, cm (5) where R0 is the internal radius of the body of the hydraulic cylinder sufficient for the placement of samples of foodstuffs and semifinished products in it. We take R0 = 100 mm; σtens is the admissible tension of material of the body, for autofretted high-tensile steel “О-АБ” σtens ≥ 50 MPa; Pstab is the design pressure of process liquid (Pstab = 1.2 Pdes). MPa, cm. Design thickness of the wall of the hydraulic cylinder Sn1, cm , (6) Sn1 = 14-10 = 4 cm = 40 mm. Design thickness of the wall of the hydraulic cylinder of the compression chamber, mm mm. Round the received value to the nearest standard value S1 = 42 mm. The performed calculations provide to start designing a high pressure hydrostat for processing of products in the conditions of all-round compression. As a result of the performed complex researches of indicators of freshness and safety of vitamins in boiled sausages it has been established that the samples processed with a high pressure of 800 MPas within 3 min. after 16 days of storage conformed to the requirements of the Technical regulation of the Customs union “About safety of food products” (TR TS 021/2011). The high pressure processing of the boiled sausages enriched with vitamin premix makes the foodstuff sterile as a result of a high pressure bactericidal effect on the microbic cells, prevents proteolysis, saves the vitamins, having an antioxidant effect which provides the weakening of processes of oxidation of lipidic components. The received results show that the use of high pressure in technology of storage of boiled sausages provides an increase in the periods of their storage. Against a background of daily use of boiled vitaminized sausages within 20 days the improvement of the state of health of students is noted, in particular, the antioxidant activity of blood and catalase enzyme authentically increases and the amount of ceruloplasmin protein increases. The obtained data are coordinated with the results of questioning. 61% of students note an increase in working capacity and improvement of the general condition of their organism.
Список литературы

1. Hernando-Sáiz A., Tárrago-Mingo S., Purroy-Balda F., and Samson-Tonello C. Advances in design for successful commercial high pressure food processing. Food Australia, 2008, no. 60 (4), pp. 154-156.

2. Hewson G. Personal communication. Avure Technologies, Kent, WA, 2008, no. 5, pp. 182-189.

3. Hayman M.M., Baxter I., O'Riordan P.J., and Stewart C.M. Effects of High-Pressure Processing on the Safety, Quality, and Shelf Life of Ready-to-Eat Meats. Journal of food protection, 2004, vol. 67, no. 8, pp. 1709-1718.

4. Margosch D., Ehrmann M.A., Buckow R., et al. High-Pressure-Mediated Survival of Clostridium botulinum and Bacillus amyloliquefaciens Endospores at High Temperature. Applied and Environmental Microbiology, 2006, vol. 72, no. 5, pp. 3476-3481. DOI:https://doi.org/10.1128/AEM.72.5.3476-3481.2006.

5. Ahn J., Balasubramaniam V.M., and Yousef A.E. Inactivation kinetics of selected aerobic and anaerobic bacterial spores by pressure-assisted thermal processing. International Journal of Food Microbiology, 2007, vol. 113, iss. 3, pp. 321-329. DOI: http://dx.doi.org/10.1016/j.ijfoodmicro.2006.08.012.

6. Matser A.M., Krebbers B., Berg R.W., and Bartels P.V. Advantages of high pressure sterilisation on quality of food products. Trends in Food Science and Technology, 2004, vol. 15, iss. 2, pp. 79-85. DOI: http://dx.doi.org/https://doi.org/10.1016/j.tifs.2003.08.005.

7. Patterson M.F. Microbiology of pressure-treated foods - A review. Journal of Applied Microbiology, 2005, vol. 98, iss. 6, pp. 1400-1409. DOI:https://doi.org/10.1111/j.1365-2672.2005.02564.x.

8. Rastogi N.K., Raghavarao K.S., Balasubramaniam V.M., et al. Opportunities and challenges in high pressure processing of foods. Critical Reviews in Food Science and Nutrition, 2007, vol. 47, no. 1, pp. 69-112.

9. (Bala) Balasubramaniam V.M., Farkas Daniel, and Turek Evan J. Preserving Foods through by destroying pathogenic and spoilage organisms while keeping food chemistry basically intact, high-pressure technology enables pasteurization of foods with minimal effects on taste, texture, appearance, or nutritional value. Food Technology, 2008, pp. 32-38.

10. Jung S., Ghoul M., and de Lamballerie-Anton M. Influence of high pressure on the color and microbial quality of beef meat. LWT-Food Science and Technology, 2003, vol. 36, iss. 6, pp. 625-631. DOI: http://dx.doi.org/https://doi.org/10.1016/S0023-6438(03)00082-3.

11. Ma Han-Jun and Ledward D.A. High pressure/thermal treatment effects on the texture of beef muscle. Meat Science, 2004, vol. 68, iss. 3, pp. 347-355. DOI: http://dx.doi.org/10.1016/j.meatsci.2004.04.001.

12. Bai Y., Zhao D., Deligersong, and Yang G. Changes of microscopic structure and shear force value of bovine and mutton skeletal muscle under hydrostatic high-pressure (HHP) treatment. Food Science China, 2004, vol. 25, iss. 9, pp. 27-31.

13. Qin H., Nan Q.X., and Che R.Z. Effects of high pressure on the activity of major enzymes in beef. Meat Res., 2001, no. 3, pp. 13-16.

14. Vinnikova L.G. and Prokopenko I.A. The application of high pressure as an alternative to thermal processing of poultry meat. Eastern-European Journal of Enterprise Technologies, 2015, vol. 3, no. 10(75), pp. 31-36.


Войти или Создать
* Забыли пароль?