CHANGES IN PHYSICO-CHEMICAL PROPERTIES OF MILK UNDER ULTRAVIOLET RADIATION
Abstract and keywords
Abstract (English):
The use of ultraviolet radiation in the treatment of milk and other liquid foods is a very promising field of study since it reduces their bacterial load. It is rarely used to increase the vitamin D content and modify the protein and fatty acid composition of milk. The paper describes how different parameters of ultraviolet radiation influence such characteristics of raw and pasteurized milk as the mass fraction of total protein, nonprotein nitrogen content, active and titratable acidity, general bacterial load (QMA&OAMO), fatty acid composition, and vitamin D content. Low-pressure gas-discharge lamps were used to treat a 400 µm moving layer of milk with ultraviolet radiation. The radiation time, its doses, and the milk flow rate changed in the ranges of 5–25 min, 5.1–102 mJ/cm2, and 0.04453- 0.13359 m3/s, respectively. We identified optimal radiation ranges that lead to both a lower microorganism content and a higher vitamin D content. Our study also determined specific correlations in the mutual changes of the given parameters. The treatment ranges did not produce any significant changes in other physico-chemical properties of milk. We also found that vitamin D was synthesized in raw and pasteurized milk in a similar way. Moreover, there was an insignificant decrease in the vitamin D content in milk treated with ultraviolet radiation during storage for up to 48 hours. On the whole, the results indicate that the treatment of milk with ultraviolet radiation in the dosage range from 5.1 to 102 mJ/cm2 has a complex effect on the total bacterial load (QMA&OAMO) and vitamin D content, whereas it has almost no effect on the protein and fatty acid composition.

Keywords:
Ultraviolet radiation, milk, protein, fatty acids, vitamin D , (QMA&OAMO) CFU/cm3
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INTRODUCTION

The assessment of the ultraviolet radiation (UVR) effect on  the  physico-chemical  and  vitamin  composi- tion, as well as the bacterial load of dairy and other food products, is a promising field of research as it permits di- rectional regulation of their properties.

Numerous studies are currently conducted in this area. However, the data are still insufficient to accurately assess all the aspects and mechanisms of the ultraviolet radiation effect on food and dairy products during their processing. There is therefore a need for further research in this area.

Milk is an important source of nutrition. It contains proteins, milk fat, minerals, and different vitamins. The main components of milk vary according to the breed of cows, feeding, and livestock management. These changes

 

mostly affect the content of fat-soluble vitamins, in particu- lar vitamin D . In European countries, such as Denmark, the consumption of milk, cheese, and other dairy products accounts for about 12% of the total intake of vitamin D [1, 2]. Dairy products with a low content of vitamin D cannot serve as its natural source. Insufficient intake of vitamin D increases the risk of developing hypertension, autoimmune diseases, diabetes, rickets, and cancer [1].

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Lactating cows have two primary sources of in- creased vitamin D content in milk. This vitamin can come with food, including vitamin-enriched supple- ments, or be produced endogenously under the impact of ultraviolet radiation on the cow’s skin [3, 4]. Under ultra- violet light radiation, 7-dehydrocholesterol turns into pre- calciferols as a result of the prototropic rearrangement. Precalciferols serve to form the D vitamins (Fig. 1).

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The vitamin D

content in milk and dairy products

 

derivatives, and juices [12–17].

 

can be increased by its introduction at a particular stage of the technological process. This can also be achieved by ultraviolet treatment due to its directional effect on 7-dehydrocholesterol.

Various gas-discharge radiators are currently the most common sources of ultraviolet radiation. Mercury lamps are used because mercury in a gaseous state is ac- tivated at relatively low temperatures. Furthermore, the discharge in mercury vapor provides the largest number of intense lines in the ultraviolet spectrum. High- and low-pressure mercury lamps are used to ensure effec- tive ultraviolet treatment of the material. They differ in their intensity depending on mercury vapor  pressure. The advantage of low-pressure mercury lamps is that the largest share of radiation falls on the wavelength of λ = 253.7 nm, which has a maximum bactericidal effect. Therefore, lamps of this type are mostly used to reduce the bacterial load of the product. In high-pressure mer- cury lamps, the spectral area of impact has a higher wavelength range, which makes them less suitable for the bacterial treatment.

Flash xenon or argon high-pressure lamps became quite widespread, along with mercury gas-discharge lamps. Compared to argon lamps, flash xenon  lamps have better bactericidal activity, shorter exposure time, and higher safety. Their disadvantages include a shorter period of guaranteed action, as well as increased opera- ting costs.

We should note a shortage of comparative studies into the use of ultraviolet radiators in the field of food biotechnology.

Depending on the modes, the UV treatment can have a different effect on the composition and properties of milk. The most important components of milkpro- teins, fats, and vitaminscan absorb UVR throughout its range. The energy absorbed by them can change the physico-chemical properties of these organic molecules. Furthermore, UVR produces active forms of oxygen that can change the chemical composition and properties of the main components of milk as a result of free radical reactions. The active forms of oxygen cause the DNA damage in microorganisms and oxidation of specific pro- tein groups. Therefore, UVR is successfully used to re-

 

Numerous studies of  UVR influence on  milk and dairy products showed that the treatment is complicated by their low transparency due to the screening ability of protein and fat. Furthermore, dairy products have a com- plex composition, and their components are closely rela- ted to each other [18–23].

Nevertheless, those studies served as a basis for in- dustrial facilities designed to reduce the quantitative content of bacteria in milk [6, 10, 24, 25].

Ultraviolet treatment has no direct effect on milk proteins in a certain range of parameters [26–28]. At the same time, we can use ultraviolet light to change the structure of proteins and give them new properties by changing treatment modes. This is  confirmed  by Cho et al. which showed that UV treatment could affect the molecular structure of β-lactoglobulin, the main al- lergen in milk [29]. Similar results were obtained in another study that recorded shifts in the molecular struc- ture of β-lactoglobulin. These results also indicate a pos- sibility of regulating the peptide profile of milk proteins and using UVR to reduce milk allergenicity [8].

Biotechnological methods used in the dairy indus- try can affect the secondary and tertiary structure of milk proteins [2, 9]. At the same time, the influence of physico-chemical factors can lead to the unfolding of the protein globule and increased proteolysis of denatured proteins.

This was confirmed by studying the proteolysis of milk proteins with pepsin and trypsin after UV treat- ment. The analysis of pepsin and trypsin hydrolysates showed that the number of cleaved protein substrates and peptide fractions was similar for all the milk samples subjected to ultraviolet radiation [13, 30]. Thus, the UV treatment of milk usually has no influence on the prote- olysis of milk proteins with pepsin and trypsin and on its digestibility.

The UV treatment of milk can intensify the forma- tion of vitamin D3 [13, 24, 25]. However, this technology is not in wide industrial use yet due to a more common

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method of directly introducing vitamin supplements in dairy products. At the same time, a combination of the latter method with the benefits of UR remains highly relevant. Thus, the UV treatment of milk can be used to reduce its bacterial load, increase the vitamin D content,

 

duce the bacterial load of dairy raw materials [5, 6].

 

and change certain components of milk.

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Despite extensive studies in this area, the results are quite controversial. Moreover, most authors are main- ly interested in studying the effectiveness of ultraviolet treatment in reducing the bacterial load or increasing the vitamin D content.

This paper attempts to fully investigate the effect of certain ultraviolet radiation parameters on the above in- dicators and, at the same time, evaluate the changes in the protein and fatty acid composition of milk.

Our main objective was to find an optimal range of UVR which could reduce the bacterial load of milk and increase the vitamin D3  content without having any sig-

nificant effect on the protein and fatty acid composition

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of the treated product. Furthermore, our hypothesis was that the changes in the bacterial load and vitamin D growth might be interrelated.

 

STUDY OBJECTS AND METHODS

Our objects of study were raw milk with a 3.8% mass fraction of fat and pasteurized milk with a 3.2% mass frac- tion of fat. The temperature of the product was 4 ± 2°C.

To conduct the experiment, we used a unit for treating milk in a 400 µm circular layer. Three sym- metrically  arranged  Philips  gas-discharge  lamps (TUV 55W PL-L) were a source of UVR, with a wave- length of 253.7 nm. A thin layer of milk was passed through a gap between two cylinders. The outer cylinder was made of stainless steel, and the inner cylinder was made of quartz glass with gas-discharge lamps placed inside it. The outer diameter and the height of the cylin- der were 120 and 600 mm, respectively.

The lamps were cooled with an electric fan that pumped air through the internal quartz glass cylinder.

Milk was supplied to the unit by a pump with adju- stable capacity. Sampling for the study was carried out under aseptic conditions.

The study aimed to assess the UVR effect on the

content of proteins, nonprotein nitrogen,  fatty  acids, and vitamin D3, as well as the bacterial background of processed milk. The unit parameters included produc-

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tivity (Q) 100–420 l/h; treatment time (τ) 5–25 minutes; the volumetric milk flow rate in the irradiated layer (V) 0.04453–0.13359 m3/s; the surface bactericidal irradi- ation dose, i.e. the relation between the bactericidal ir- radiation energy and the irradiated surface area, )

min D3 content. The analysis was conducted in triplicate. State Standard 26754-85 was used to regulate the milk temperature after the ultraviolet treatment.

The following equipment was used to measure the mass fraction of protein and nonprotein nitrogen:

  • a SH220F digester (Hanon, China) with the maximum heating temperature of 450°C;
  • a WD03 sulfuric acid vapour suction system; and
  • a K9840 distillation system (Hanon, China) with an au- tomatic supply of alkali, receiving solution, and distillate. A  4000M  Crystallux  gas  chromatograph  (Russia) was used to separate and identify fatty acids in the sam- ples. It was equipped with a Supelco-SP2560 capillary column (100 m×0.25 mm, df = 0.20 µm, Sigma-Aldrich,

USA) and a flame ionization detector.

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The following equipment was used to measure the vitamin D content:
  • a liquid chromatograph equipped with a spectropho- tometer (Gilson, France);
  • a Luna C18(2) column (5 µm, 250×4.6 mm, Phenome- nex, USA); and
  • a vacuum unit for Strata C18-E SPE with replaceable cartridges (Phenomenex, USA).

The analysis was performed in the following condi- tions:

  • gradient mode of separation;
  • mobile phase: acetonitrile (eluent A) – dichlorome- thane (eluent B);
  • gradient elution programme: A/B = 100/0 at the beginning  of  the  analysis;  gradient  A/B  =  90/10  in 8 min; gradient A/B = 70/30 in 2 min; isocratic elution A/B = 70/30 in 10 min; gradient A/B = 100/0 in 3 min; isocratic elution A/B to 100/0;

flow rate: 1.0 cm3/ min;

  • loop dispenser volume: 20 mcl;
  • room temperature; and
  • spectrophotometric detection with changing the wave- length of the light source during analysis: 0 min with а wavelength of 436 nm, 10 min with а wavelength of 280 nm, and 27 min with а wavelength of 436 nm.

 

RESULTS AND DISCUSSION

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The experiments involved the evaluation of active (pH) and titratable (Т°) acidity. We found that these indica- tors did not undergo any significant changes in the follo-

 

5.1–102 mJ/cm2.

 

wing range of treatment parameters: Н

 

= 5.1–102 mJ/сm2,

 

Some samples were used to assess their protein and

 

V = 0.04453–0.13359 m3/s.

 

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fatty acid composition, as well as vitamin D

content,

 

As can be seen in Table 1, the mass fraction of total

 

both directly after the UV treatment and during storage, namely after 24, 36, and 48 hours, respectively. The as- sessment was carried out under standard conditions. We used the following State Standards to determine speci- fic parameters, namely: State Standard 38892-2014 for active acidity (pH); State Standard R 54669-2011 for titratable acidity; State Standard 32901-2014 for the to- tal number of microorganisms (QMA&OAMO); State Standard 23327-98 for the mass fraction of total protein; State Standard R 55246-2012 for nonprotein nitrogen content; State Standard 32915-2014 for the fatty acid composition; and State Standard R 54637-2011 for vita-

 

protein remained unchanged, regardless of the irradia- tion time or type of milk.

Fatty acids, especially unsaturated, are an important component of the fat phase of milk. Tables 2 and 3 show the fatty acid composition of raw and pasteurized milk after different periods of the UV treatment.

The main fatty acids amounted to 95.78% in the con- trol. Their composition and content hardly changed un- der the influence of UVR. Furthermore, the fat phase contained 23 minor fatty acids (4.22%). The UV treat- ment caused a slight increase in some of them and a

slight decrease in others, with their total content remai-

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The study revealed a correlation between the changes in the vitamin D content and the microbial load (CFU/cm3)

 

Thus, the ultraviolet treatment of milk in the given

 

of milk (Figs. 2 and 3).

The  data  for  both  raw  and  pasteurized  milk  con-

 

range of exposure did not affect the physico-chemical

 

firmed the interrelation between the vitamin D

 

content

 

properties of fatty acids and their composition.

 

and QMA&OAMO and also indicated that an i

 

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ncrease in

 

 

 

y = 0.64ln(x) + 10.313 = 0.9354

the initial bacterial load negatively affected the vitamin

 

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vitamin D3,  µg/100 g raw milk

Подпись: vitamin D3,  µg/100 g raw milk6                                                                                                    D growth.

 

 

 

 

-0.

 

64ln(x) + 10.313

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2

 

 

 

0

1×105   2×105   3×105  4×105  5×105  6×105  7×105  8×105

QMA&OAMO, CFU/cm3 raw milk


Studying the influence of the volumetric milk flow rate (V = 0.04453–0.13359 m3/s) and treatment duration = 5–25 min) at different irradiation doses revealed a significant effect of UVR on the bacterial load in the given ranges (Table 4).

The feedstock in the experiments included raw milk with a bacterial load of 2.1×105 CFU/cm3 and pasteurized milk with a bacterial load of 1×105 CFU/cm3.

We found that the irradiation doses of over 30 mJ/cm2 and the treatment duration of over 15 min allowed for a more intensive reduction of the bacterial load in raw milk, compared to pasteurized milk.

The experiments also showed an increase in the vi-

 

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tamin D

content within the UV treatment parameters

 

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Fig. 2. Changes in vitamin D content in raw milk depending on treatment time.

specified in Table 4. This was confirmed by the results

shown in Figs. 4 and 5.The analysis showed that the irradiation doses below 5 mJ/cm2 had an insignificant effect on the microbio- logical load and the vitamin D content (Table 4; Figs. 4 and 5). Higher doses of irradiation, however, led to a rather intensive growth in vitamin D and a decrease in the bacterial load.

On the whole, we found low-pressure gas-discharge irradiation sources effective in producing a considerable

simultaneous effect on the vitamin D3 content and the microbiological load of both raw and pasteurized milk within the treatment modes. At the same time, low irra-

 

 4                48           0.566          0.926     1.18     0.902   1.60  

5

0

0.357

0.562

2.01

1.93

3.15

6

24

0.313

0.525

1.83

1.84

2.95

7

36

0.310

0.526

1.82

1.81

2.90

8

48

0.286

0.480

1.82

1.55

2.40

 

 
Pasteurized milk

 

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diation doses up to H

= 102 mJ/cm2  did not have a sig-

 

nificant effect on the protein and fatty acid composition

of milk.

 

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To assess changes in the vitamin D

content during

 

(Table 5).

 

storage, we treated raw and pasteurized milk with UVR at different durations in the range of 20–102 mJ/cm2. After the treatment, the milk samples were stored at

 

 

CONCLUSION

 

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4 ± 2°C. We found that the vitamin D

content in both

 

Thus, we found that the ultraviolet treatment of a

 

raw and pasteurized milk remained almost unchangedlamps at a wavelength of 253.7 nm in the dose range from 5 to 102 mJ/cm2   makes it possible to simultane- ously reduce the bacterial load and increase the vitamin

content. The study proved that these processes are interrelated; furthermore, they do not cause any signi-

 

ficant changes in the protein and fatty acid composi- tion of milk, both after production and during storage. The patterns established are identical for both raw and pasteurized milk with slight changes during storage for 48 hours.

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