сельскохозяйственные науки
PRELIMINARY STUDIES OF PHYSICOCHEMICAL AND FATTY ACIDS COMPOSITION IN COLOSTRUM FROM "BULGARIAN MURA" BUFFALOES _BREED_
Ivanova Silviya Atanasova
Candidate of Science, Assistant professor of Institute of Cryobiology and Food Technology, 1407 Sofia,
Bulgaria E-mail: sylvia_iv@abv. bg Ananoshtev Nikola Haralambev Doctor of medical science, academician, "New Revival" Ltd, 4000 Plovdiv, Bulgaria
ABSTRACT
The study was conducted on physicochemical and fatty acid composition of raw and freeze-dried colostrum from "Bulgarian Mura" buffalo breed.
The content in raw colostrum of total solids is 17, 61%, fat- 4.42%, protein- 6.62%, which was maintained after lyophilization and therefore preconcentrate is respectively 25.11% fat, 37.69% protein and 69.3% non-fat solids.
Biologically active substances in the raw colostrum were CLA-0,05 g / 100g fat, oleic acid- 29,62 g / 100g fat, trans vaccenic acid - 1,81 g / 100g fat, alpha linolenic acid - 0,31 g / 100g fat and gamma linolenic acid -0,09 g / 100g fat, while in the lyophilized as follows CLA-0,19 g / 100g fat, oleic acid- 22,55 g / 100g fat, trans vaccenic acid- 1,79 g / 100g fat, alpha linolenic acid - 0.56 and gamma linolenic acid -0,10 g / 100g fat. Variation in fatty acid composition between raw and freeze-dried colostrum are insignificant.
АНОТАЦИЯ
Исследование было проведено по физико-химическим и жирнокислотного состава молозива из буйволиного породы "болгарку ель" сырой и подвергают сублимационной сушке.
Содержание сухого вещества составляет 17,61% жиров 4,42%, белка 6,62%, который сохранялся после лиофилизациии, следовательно, предконцентрат составляет соответственно 25,11% жира, 37,69% белка и 69,3% обезжиренные твердые вещества.
Биологических активные вещества в сыром молозива являются CLA -0,05 г /100 г жира, олеиновой кислото- 29,62 г/100 г жира, транс ваксеновой кислото - 1,81 г /100 г жира, альфа линоленовой кислото - 0,31 г/100 г жира и гамма-линоленовой кислото -0,09 г /100 в то время как в лиофилизированной следующие CLA- 0,19 г /100 г жира, олеиновой кислото- 22,55 г /100 г жиров, транс ваксеновой кислото -1,79 г /100 г жира, альфа линоленовой кислото - 0,56 и гамма-линоленовой кислото- 0,10 г /100 г жира. Изменение в составе жирных кислот между сырым и подвергают сублимационной сушке молозива незначительны.
Key words: colostrum; physicochemical composition; fatty acids; freeze-drying
Ключевые слова: молозиво; физико-химический состав; жирных кислот; сублимационной сушки
In recent years, colostrum represents scientific interest because of the content of biological active components. It is functional products with significant health benefits, improve health status and apply to immune deficiency. It finds application in influenza, candidiasis, diarrhea, gastrointestinal diseases of bacterial, viral and parasitic character, as well as in autoimmune diseases such as arthritis, asthma, allergies, lupus eritematosus, multiple sclerosis, fibromyalgia [1, 4, 8]. Colostrum is rich of nutritional components-protein, minerals, vitamins and others, and biologically active substances- immunoglobulin's, enzymes, hormones, growth factors, etc. [9].
The application of different diets (high and low energy intake) during the dry period of cows led to minor changes in physicochemical composition of colostrum, but the concentration of IgA in the colostrum has significantly higher in cows with low-energy diet. The content of total immunoglobulin's, G and M classes of immunoglobulin in colostrum are not influenced by the feeding of ruminants during the dry period [3]. The fat in milk from "Bulgarian buffalo" range
from 7.5 to 7.7% and milk of animal from breed "Mura" -7.96 to 8.00%, while cross of the two breed "Bulgarian Mura" from 7.9 to 7.92%. Milk fat is low during the first 15 days and increased to 225-300 lactating day. Colostrum period is seven days, the amount of colostrum represents 1/10 of the live weight of young buffalo [15].
Colostrum of buffalo can be an important source of fatty acids in the human diet is therefore important to know the fatty acids composition especially the content of polyunsaturated fatty acids, which have proven health benefits in the prevention of many diseases, such as diabetes, cardiovascular disease, hyper-lipidaemia, nerve disorders and various cancers [2, 7]. Buffalo's milk is a good source of oleic acid [5]. Fat, protein and total solids in colostrum reduce with increasing colostrum period as compared with lactose, ash and pH. Fatty acids have a higher concentration during the summer period [6]. Varga-Visi et al. [8] found in six breeds that no significant changes in the fat content of colostrum from different breeds of cows, but found a higher content of saturated fatty acids
from Jersey's to Holstein Friesian, Brown Swiss and Norwegian red, higher content of monounsaturated fatty acids in Brown Swiss compared with Jersey and Ayrshire. The amount of omega-6 fatty acids is high in Holstein-Friesian breed compared to other omega-3 fatty acids and CLA in colostrum does not depend on breed differences, the ratio of omega-6 / omega-3 fatty acids is the highest in colostrum from Holstein-Friesian breed cows [8]. Paszczyk et al.,[1], were determining the content of CLA in colostrum 0.34%, which is lower than the analysed milk by the same cows- 0.42%.
The purpose of the study was to determine the physicochemical and fatty acid composition of raw and freeze-dried colostrum obtained from "Bulgarian Mura" buffalo breed. The studies were conducted with bulk tank samples of colostrum. Physical and chemical composition of colostrum is performed with ekomilk, dry colostrum were analysed by standard methods. The extraction of the total lipids was per-
Table 1.
Physicochemical composition of raw and freeze-drying colastrum
formed by the method of Bligh&Dyer (1959) [10] by chloroform and methanol in ratio of 1:2. The methyl esters of the fatty acids were analyzed using gas chromatograph Shimadzu-2010 (Kyoto, Japan). The analysis was carried out on a capillary column CP7420 (100 m x 0.25 mm i.d., 0.2 m, Varian Inc., Palo Alto, CA), with carrier gas- hydrogen and makeup gas- nitrogen. Is programmed furnace regime of five steps.
The study was carried out with buffalo from "Bulgarian Mura" breed on the second lactation to establish the physicochemical and fatty acid composition of raw and freeze-dried colostrum. Physical and chemical composition is presented in Table 1. The content of total solids is 17, 61%, fat- 4.42%, protein-6.62%, which in turn determines the highest density in the colostrum-1,04 g / cm3 in compared with milk from buffaloes determined by BSS 15: 2010, Annex B[11].
Humidity, % Total solids, % Fat, % Protein, % SNF, % Density, 20°С, g/cm3 Humidi fication, % FP,°C
raw colastrum X 82,40 17,61 4,42 6,64 12,20 1,04 0,00 0,67
Sd 0,06 0,06 0,18 0,13 0,14 0,42 0,00 0,01
lyoph. colastrum X 0,08 99,93 25,11 37,69 69,30 - - -
Sd 0,01 0,01 1,04 0,76 0,80 - - -
The lyophilized colostrum has a low content of saturated fatty acids in the analysed raw colostrum is
residual moisture- 0.08%, which, in turn, purport of a well conducted process of freeze drying.
Fatty acid composition of colostrum before and after lyophilisation is presented in Table 2. The Table 2.
Fatty acids (g / 100g fat) in raw and freeze drying colastrum
60,33 g / 100g fat, while in the lyophilised increased by 9%. This is due to the reduction of the total content of monounsaturated fatty acids in colostrum after freeze drying from 34.73 to 28,49 g / 100g fat.
FATTY ACIDS Raw colastrum FD colastrum FATY ACIDS Raw colastrum FD colastrum
SFA SX SD SX SD PUFA SX SD SX SD
C-8:0 0,09 0,02 0,02 0,01 C-8:2c9,12/19:0 2,23 0,79 2,21 0,79
C-10:0 0,57 0,21 0,75 0,25 gC-18:3n6 0,09 0,01 0,10 0,01
C-12:0 1,16 0,69 1,63 0,61 aC-18:3n3 0,31 0,01 0,56 0,01
C-14:0 8,08 0,95 9,66 0,85 CLA9c, 11t 0,05 0,04 0,19 0,04
C-15:0 0,55 0,01 0,80 0,01 C-20:2n6 0,03 0,00 0,03 0,00
C-16:0 40,20 1,05 38,56 1,25 C-20:3n6 0,25 0,01 0,10 0,01
C-17:0 0,84 0,04 0,97 0,04 C-20:4n6 0,28 0,01 0,18 0,01
C-18.0 8,67 0,31 13,21 0,21 C-22:2n6 0,02 0,02 0,01 0,00
C-20:0 0,11 0,00 0,23 0,00 C-22:5n3 0,06 0,02 0,05 0,02
C-22:0 0,04 0,00 0,06 0,00 BFA
MUFA C-13iso 0,01 0,00 0,01 0,00
C-10:1 0,02 0,01 0,02 0,01 C-13aiso 0,01 0,00 0,01 0,00
C-15:1n5 0,13 0,00 0,26 0,00 C-14iso 0,03 0,00 0,12 0,00
C-16:19tr 0,02 0,00 0,02 0,00 C-15iso 0,74 0,15 0,71 0,15
C-16:1n7 2,02 0,02 1,32 0,02 C-15aiso 0,12 0,00 0,37 0,00
C-16:2n4 0,01 0,00 0,01 0,00 C:16iso 0,02 0,00 0,02 0,00
C-17:1n7 0,41 0,02 0,35 0,02 C-17iso 0,33 0,01 0,39 0,01
C-18:1t5/6/7 0,15 0,00 0,35 0,00 C-17aiso 0,36 0,01 0,49 0,01
C-18:1t9 0,18 0,02 0,37 0,02 C-18iso 0,10 0,00 0,11 0,00
C-18:1t10 0,10 0,00 0,19 0,00 Group FA
C-16:4n1 0,59 0,04 0,00 0,00 SCLA 0,05 0,04 0,19 0,04
C-18:1t11 1,81 0,08 1,79 0,08 E C-18:1TFA 1,26 0,00 3,43 0,00
C-18:1c9/C-18:1t12/13/ 29,62 1,56 22,55 1,56 E C-18:1CFA 30,11 1,75 22,87 1,75
C-18:1t15/C-18:1c11 0,74 0,05 0,56 0,05 SFA 60,33 0,98 65,94 0,98
C-18:1c12 0,26 0,04 0,07 0,02 MUFA 34,73 1,81 28,49 1,81
C-18:1c13 0,10 0,04 0,07 0,04 PUFA 3,33 0,83 3,47 0,83
C-18:1t16 0,08 0,04 0,16 0,06 E n-3 0,38 0,00 0,63 0,00
C-18:1c14 0,01 0,00 0,05 0,01 E n-6 3,16 0,55 2,71 0,55
C-18:1c15 0,13 0,01 0,13 0,01 E n-6/En-3 8,25 1,44 4,28 1,44
C-20:1n9 0,05 0,01 0,04 0,01 BFA 1,73 0,14 2,23 0,14
C-22:1n9 0,08 0,01 0,16 0,01 CLA 0,05 0,04 0,19 0,04
The main representatives of saturated fatty acids, which are relevant to human nutrition and health status are lauric (C12: 0), myristic (C14: 0) acid, palmitic (C16: 0) and stearic acid (C18: 0). The raw and freeze-dried colostrum with the highest concentration of palmitic acid, respectively 40,2 and 38,56 g / 100g fat, followed by stearic- 8,67 and 13,21 g / 100g fat, myristic- 8.08 and 9,66 g / 100g fat and the lowest amount is lauric- 1,16 and 1,63 g / 100g fat. Oleic acid in the analysed samples has a higher concentration in the crude colostrum- 29,62 g / 100g fat. Trans vac-cenic, alpha and gamma linolenic acid are relatively equal amounts in raw and lyophilized colostrum. CLA is at a concentration from 0.05 at the raw and 0,19 g / 100g fat in the freeze-dried colostrum. The total amount of trans fatty acids in the raw colostrum is 1,26 g / 100g of fat, and in the freeze-dried was 3,43 g / 100g fat. The cis- isomers are in a higher concentration in the raw colostrum, which could be due to oxidation and destructive processes. Omega-3 fatty acids in larger quantities in the lyophilized colostrum, ome-ga-6 in the crude colostrum and therefore there is also a high ratio between omega-6 and omega-3 in the raw colostrum- 8.25. Lyophilized colostrum were characterized by a ratio of omega-6 and omega-3 fatty acid 4.28, which allows us to define it as a low-risk factor for human health, since factor is below 5. The results of fatty acid profile in colostrum from "Bulgarian Mura" buffaloes breed have a lower content of saturated, polyunsaturated, omega-3 fatty acids and CLA, and higher in monounsaturated fatty acids compared to those obtained for large and small ruminants and humans in literature [7, 8, 9, 12, 13, 14]. The lyophilized product keeps starting the physicochemical parameters and fatty acid composition due to the low moisture content and well organized process.
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