RU2711748C1 - Method for optimization of histogenesis of gastrointestinal organs in embryos of hens of meat direction of productivity when using biologically active substances before incubation - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention refers to agriculture, namely to a method for optimization of histogenesis of gastrointestinal organs in embryos of chicken meat direction of productivity by single treatment of incubation eggs before incubation. According to the disclosed method, said treatment consists in fact that 3–4 hours before laying in an incubator on the surface of the shell from an atomizer, an aqueous solution of colamine is applied, succinic acid, serine and pyridoxine hydrochloride in concentrations of 0.1 %, 0.1 %, 0.2 %, 2.5 % respectively, which are pre-dissolved in distilled water at temperature of 18–22 °C.EFFECT: invention provides reduction of lipid peroxidation processes, improved thermogenesis and high output of standard chicken.1 cl, 4 tbl, 3 ex

Description

This invention relates to the field of agriculture and, in particular, to poultry farming (pre-incubation use of a solution that includes colamine, series, succinic acid and pyridoxine hydrochloride).

Known treatments for hatching eggs with solutions of colamine, succinic acid and serine in order to stimulate the embryonic development of chicken crosses of eggs (1). Succinic acid and its salts have adaptogenic ability and have antihypoxic, anti-stress, antioxidant and neurotropic effects, normalize energy and plastic metabolism and the general physiological state of the body (2). Colamine inhibits the oxidation of fats, vitamin A and other compounds with unsaturated carbon bonds, takes an active part in redox processes in animals, improves phosphorus and protein metabolism and, therefore, is a growth stimulator (3). In turn, the series are a glycogenic amino acid that is part of the phospholipids of cell membranes and the active centers of many enzymes (4). Vitamin B6 (pyridoxine hydrochloride) is a water-soluble vitamin, the active form of which is phosphorylated derivatives - pyridoxalphosphate and pyridoxamine phosphate. Pyridoxalphosphate is part of many enzymes that take a different role in metabolic processes. So, for example, it is a coenzyme of decarboxylases, transaminases, kenureninases, tryptophan synthases, cysteinonases. With the participation of vitamin B6, the formation of δ-aminolevulinic acid (heme synthesis) and the synthesis of arachidonic acid proceeds, and it also contributes to the most efficient use of glucose. In medicine and veterinary medicine use vitamin B6 in the form of pyridoxine hydrochloride. In the process of metabolism, it is absorbed in the small intestine and turns into active forms. Its metabolic products are excreted by the kidneys and are not toxic (5). It should be noted that pyridoxine has a great effect on the metabolism of amino acids containing sulfur, takes part in sulfonation, i.e. transfer of sulfhydryl groups from one compound to another. Thus, enzymes that include phosphopyridoxal contribute to the transfer of sulfur from methionine in series and the formation of cysteine. Together with serine, he is involved in the synthesis of sphingolipids. It also takes part in the formation of biogenic amines, such as, for example, colamine. Pyridoxine is able to interact with succinic acid, with the formation of oxypyridines, the spectrum of antioxidant and antihypoxic action of which is quite wide (5). Thus, the addition of the previously studied composition consisting of colamine, succinic acid and serine with vitamin B6 expands the spectrum of antioxidant, hematoprotective, metabolic-stimulating effects of previously proposed biologically active substances, causing the prerequisites for better formation of tissues, organs, tissues, the whole organism. The importance of supplementing pyridoxine in the composition is undeniable, as previously scientists have proved that it has a pronounced gastroprotective effect and also reduces inflammatory processes in the gastrointestinal tract (5). The combined use of these substances is not registered. The use of vitamin B6 to stimulate embryonic development has also not been studied. It is worth noting that this composition of natural metabolites was never used to stimulate bird embryogenesis, and was also not used on a biologically complete egg of highly productive crosses. At the same time, it is necessary to note the positive effect on the micromorphological structure of the organs of the gastrointestinal tract when using colamine, succinic acid and serine (6).

This method, which we took as a prototype, consists in the fact that colamine, succinic acid and lots were used to process eggs of chicken cross eggs. The hatching rate was 9.38% higher and amounted to 84.38% (versus 75% in the control). In addition, the declared data of the prototype indicate that the high difference between experience and control was due not only to the stimulating effect of the composition of biologically active substances (colamine, succinic acid and serine), but also to the low quality of the incubation egg, since the conclusion in the control was lower than the standard for this cross 7% (1) The above was another significant argument for the development of a biologically active substance composition that positively affects chicken embryogenesis under conditions of use of a biologically complete egg during incubation.

The purpose of the invention is the optimization of the histogenesis of muscle and glandular stomachs, the stimulation of embryogenesis of meat chickens, the increase in the output of conditioned chickens above the standards for this cross by pre-incubation processing of eggs before laying for incubation with an aqueous solution of pyridoxine hydrochloride, serine, succinic acid and colamine.

The method is as follows.

An aqueous solution of colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations of 0.1%, 0.1%, 0.2%, 2.5%, respectively, is applied to the surface of the shell 3-4 hours before incubation from the spray gun; Preliminarily, the preparations are dissolved and mixed in distilled water at 18-22 ° C.

Example 1. Eggs of chickens cross "Ross 308" were obtained from one parent herd, sorted by 324 pieces in each batch, subject to the similarity of weight, time of demolition and shelf life. A solution of the preparations was applied to the surface of the shell from the spray gun according to the above scheme. As a control, eggs of the same batch were selected on the basis of analogues, which were processed according to the technology adopted in the farm. The data obtained are presented in table 1.

From the table it follows that the conclusion in the experimental batch exceeds the control by 2.47%, and hatchability by 2.23%. This is due to a decrease in most incubation waste, in particular such as: “false neoplod” by 2 times, “freaks” by 0.31%, and “weak” by 1.5 times. According to Tagirova M.T. (2012) the highest risk of hypoxia in chicken embryos is observed at 1-7 and 19-21 days of incubation, due to the absence of formed chorioallantois at the beginning and its atrophy at the end of incubation. Thanks to the components of the composition of biologically active substances, which are antigopoxants and antioxidants, it was possible to reduce the number of false neoplod, freaks and weak ones falling under the above periods. Vitamin B6 according to Loginova N.Yu. (2017) also prevents the development of muscle cell hypoxia (5, 6) In turn, colamine and series are structural components of phospholipids, which are certainly damaged under hypoxia. It should be noted that according to Tagirova M.T. (2009) and Farhutdinova P.P. (2006) hypoxia is largely due to the abnormal intensity of free radical reactions in cells due to depletion of antioxidant reserves, as well as metabolic disturbances and increased tissue oxygen demand under the influence of internal and external factors. Meanwhile, the presented substances, possessing antioxidant properties, prevent excessive intensification of the claimed processes, and at the same time lipoperoxidation, reducing the likelihood of destruction and creating prerequisites for a more complete formation of cell membrane structures (7, 13).

It should be noted that this poultry farm is equipped with modern incubation equipment that supports incubation processes that are as close as possible to physiological conditions, which is an important factor in reducing the effects of technological stresses on the body of chicken embryos, causing the conditions for obtaining a higher hatch of chickens (8). It should be noted that the normative conclusion for this cross according to the herd passport is 83.1%, but even in the control it is 89.2%, which also indicates an initially high-quality biologically complete egg used for incubation, compliance of production technologies with standards, good breeding work . Despite this fact, the use of this composition allowed to surpass the high technological result obtained at the poultry farm with minimal labor and money.

Example 2. In the obtained chickens, the temperature status was determined in order to predict their further viability (table 2).

As can be seen from the table, in the chickens of the experimental group, the temperature was significantly higher by 0.7-1.3 ° C (p <0.05, p <0.01) compared with the control, which, according to A. Ageychkin, (2010) indicates a high biological usefulness of young animals of daily age. The optimization of the formation and implementation of thermoregulation processes is obviously associated with the conservation and, probably, intensification of energy synthesis processes, which is due to the synergistic multifaceted, including antioxidant, effect of the composition of the studied biologically active substances (8). The latter was confirmed by the study of indicators presented in table 3.

Analysis of the data in the above table indicates the high efficiency of the antioxidant effect of the studied composition of biologically active substances. It was found that the intensity of peroxidation in the experimental group is significantly lower than in the control. So, the level of OSh significantly decreased by 2.5 times (p <0.05), and the amount of the secondary product of lipid peroxidation in the form of malondialdehyde (MDA) decreased by 1.3 times (p <0.05), respectively. Considering the fact that the removal of young animals from the incubator and the distribution over the trays is a stress factor for them, it becomes clear that the need for an increase in the experimental group of peroxidase activity by 17.65%, SOD by 1.6 times (p <0.01). The above also suggests that the claimed biologically active substances have not only their own antioxidant effect, but also stimulating other components of the protective system.

Work Tagirova M.T. (2009) and Farkhutdinova P.P. (2006) indicate that the intensity of free-radical reactions and, as a consequence, lipid peroxidation have a significant impact on the full-fledged formation and implementation of the functions of various tissues and organs. Scientists' studies indicate high importance for improving the quality of development of an individual and its productivity in the future, the quality of the formation of organs of the gastrointestinal tract. According to Tsivenko A.I. (2006) any negative effect on the stomach is accompanied by the activation of free-radical processes with subsequent destruction, especially of organelles membranes, in turn, A.V. Anufrieva (2012) et al. Believes that the imbalance of pro and antioxidants is a universal basic mechanism of the pathogenesis of diseases of the digestive tract (14.15).

Example 3. From chickens hatched from treated eggs, internal organs were taken at the age of 24 for histological examination.

The decrease in the abnormal intensity of free-radical reactions and, as a result of lipoperoxidation, had a greater positive effect on the histoarchitectonics of the muscular and glandular stomachs (table 4).

It has been established that they are better developed among representatives of the experimental group, as indicated by the advantage of a number of morphometric parameters of the claimed organs, in particular, a tendency to an increase in the thickness of the mucous membrane of the muscle stomach by 16.6%, as well as its cuticle, is significantly 1.4 times glandular - 1.2 times relative to control. Research Omelchenko O.E. (2014), point to the fact that the thickness of the mucous layer of the muscle stomach and the glandular layer of the lobules of the glandular stomach has an inverse correlation with the intensity of free radical and lipoperoxidized processes (9), which was also confirmed in our studies.

The study of the histological characteristics of stomachs in chickens at one day old is an important marker of their future adaptability in postembryogenesis (10). It should be noted that a more intensive formation of the mucous membrane of the stomachs of birds according to Krivova N.A. may indicate the advantage of barrier function (against infectious agents), which will lead to higher viability of the individual and the quality of its development in the future (16). In turn, an increase in the thickness of the mucous membrane of the glandular stomach will obviously contribute to a better digestion of feed, the viability of intramural regulatory processes and other functions of the digestive system as a whole, and, therefore, higher meat productivity (10-12).

Literature:

1. Patent 2486752 of the Russian Federation, IPC A01K 45/00 A method for stimulating embryogenesis of chicken in the egg production direction and prevention of physiological stress exposure Azarnova, I.S. Yartseva, M.S. Naydensky, S.Yu. Zaitsev, L.Yu. Azarnova, I.A. Yartseva; Applicant and patent holder FGBOU VO MGAVMiB - MVA named after K.I. Scriabin. - No. 20111144760/13; declared 11/07/2011; publ. 07/10/2013, Bull. No. 11. - 7 p.

2. Evglevsky, A.A. The biological role and metabolic activity of succinic acid / A.A. Evglevsky, G.F. Ryzhkova, E.P. Evglevskaya, N.V. Vanina, I.I. Mikhailova, A.V. Denisova, N.F. Eryzhenskaya // Bulletin of the Kursk State Agricultural Academy. - 2013. - No. 9. - S. 67-69.

3. Shipunova, N. N. The effect of monoethanolamine on the main substrates of glycolysis of animals / N.N. Shipunova, N.A. Lushnikov // Chief livestock specialist. - 2014. - No. 5. - S. 56-59.

4. Garaeva, S.N. Amino acids in a living organism / S.N. Garaeva, G.V. Redkozubova, G.V. Post it. - Publishing House of the Academy of Sciences of Moldova, 2009. - 552 p.

5. Loginova, N.Yu. Vitamin B6: General Aspects of Metabolism / N.Yu. Loginova // In the collection: Fundamental and applied research: current issues, achievements and innovations collection of articles by the winners of the V International Scientific and Practical Conference: in 4 parts. - 2017 .-- S. 226-229.

6. Azarnova, T.O. Some aspects of transovarial nutrition of the embryo and stimulation of the development of their digestive tract / T.O. Azarnova, I.S. Yartseva, S.Yu. Zaitsev, M.S. Naydensky, A.A. Antipov // International Bulletin of Veterinary Medicine. - No. 4. - SPb. - 2012 .-- S. 54-57.

7. Tagirov, M.T. Nutrition and main metabolic pathways in the developing bird embryo / M.T. Tagirov, O.V. Tereshchenko // Bulletin of the Kharkov National University named after V.N. Karazin. Series: biology. Issue 10. - No. 878. - 2009 .-- S. 48-59.

8. Ageechin, A.P. Industrial poultry farming / A.P. Ageechkin, F.F. Alekseev, A.V. Aralov et al. Ed. IN AND. Fisinina. - Sergiev Posad: GNU VNITIP of the Russian Agricultural Academy, 2010 .-- 599 p.

9. Omelchenko, O.E. Pathogenetic mechanisms of the development of stresnogo virazok slunka fallow in the type of reactivation organism / O.E. Omelchenko // Bulletin of problems of biology and medicine. - 2014. - T. 2. - No. 4 (114). - S. 161-169.

10. Wahhab, S.A. Comparative evaluation of histogenesis of the stomach of chickens cross ROSS-308 and Highsex Brown / S.A. Wahhab, O.S. Bushukina // Agrarian Scientific Journal. - No. 4. - 2017 .-- S. 11-15.

11. Naletova L. A. Anatomical and histological characteristics of the glandular stomach of chickens and geese / L.A. Naletova // Bulletin of the Buryat State University. Biology. Geography. - No. 4. - 2013 .-- S. 186-188.

12. Naletova L.A. Macro and micromorphological features of the muscular stomach of chickens and geese / L.A. Naletova // Bulletin of the Buryat State University. Biology. Geography. - No. 4. - 2010 .-- S. 186-191.

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16. Krivova N.A. The state of the gastric mucosa, pro- and antioxidant activity, and biochemical blood parameters in rats after feeding nano- or microparticles of titanium dioxide / N.A. Krivova, O.B. Zaeva, M.Yu. Khodanovich, O.A. Karelina, E.V. Gul, A.E. Zelenskaya // Bulletin of Tomsk State University. Biology. - 2011. - No. 2 (14). - S. 81-95.

Claims (1)

A method for optimizing the histogenesis of the organs of the gastrointestinal tract in chicken embryos with meat productivity using biologically active substances before incubation, characterized in that the treatment of the incubation eggs is carried out once, namely, 3-4 hours before laying in the incubator, they apply to the shell surface from the spray gun an aqueous solution of metabolites: colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations: 0.1%, 0.1%, 0.2%, 2.5%, respectively, and these metabolites are pre-grown oryayut in distilled water at 18-22 ° C.