RU2754459C1 - Method for increasing stress resistance of young chicken egg cross - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to the field of agriculture, namely poultry farming. The method of increasing the stress resistance of young hens of the egg cross involves the use of biologically active substances before incubation. An aqueous solution of metabolites of colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations of 0.1%, 0.1%, 0.2% and 0.1%, respectively, is applied to the surface of the shell before laying in the incubator for 3-4 hours from a spray bottle, previously diluted in distilled water.EFFECT: method for increasing the stress resistance of young hens of the egg cross ensures increased embryonic viability, increased hatching of chickens, increased safety of the brood and has a positive effect on hematological parameters.1 cl, 5 tbl, 2 ex

Description

This invention relates to the field of agriculture, namely, to poultry (pre-incubation application of a solution containing colamine, serine, succinic acid and pyridoxine hydrochloride).

Poultry farming is the most stressful branch of animal husbandry, including due to artificial incubation in industrial conditions. The emergence of new highly productive breeds and crosses, often not stress-trained, only aggravate the urgency of the problem of increasing the level of stress resistance of agricultural poultry (Ageechkin A.P., 2010). Scientists are actively studying and detailing the aspects of its components, looking for possible ways to increase it, since this is the only way to ensure an increase in the profitability of production, creating conditions for obtaining high indicators of resistance of individuals to the action of biotic and abiotic factors, and, as a consequence, the safety of poultry. In this regard, the use of a composition of natural metabolites is an urgent way to solve this problem (Azarnova T.O., 2020).

Known processing of hatching eggs with solutions of colamine, succinic acid, serine and pyridoxine hydrochloride in order to stimulate the embryonic development of chickens, beef cross (T.O. Azarnova, 2020). Succinic acid and its salts have an adaptogenic ability and have antihypoxic, anti-stress, antioxidant and neurotropic effects, normalize energy and plastic metabolism and the general physiological state of the body (Evlevsky A.A., 2013). Colamine inhibits the oxidation of fats, vitamin A and other compounds with unsaturated carbon bonds, takes an active part in redox processes in the body of animals, optimizes phosphorus and protein metabolism and, therefore, is a growth stimulant (Shipunova N.N., 2014). In turn, serine is a glycogenic amino acid, which is part of the phospholipids of cell membranes and active centers of many enzymes (Garaeva S.N., 2009). Vitamin B6 (pyridoxine hydrochloride) is a water-soluble vitamin, the active form of which is phosphorylated derivatives - pyridoxal phosphate and pyridoxamine phosphate. Pyridoxal phosphate is part of many enzymes that are involved in various metabolic processes. So, for example, it is a coenzyme of decarboxylases, transaminases, kenureninase, tryptophan synthase, cysteinonase. With the participation of vitamin B6, the reaction of the formation of δ-aminolevulinic acid (heme synthesis) and the synthesis of arachidonic acid occur, and it also contributes to a more efficient use of glucose. In medicine and veterinary medicine, vitamin B6 is used in the form of pyridoxine hydrochloride. In the process of metabolism, it is absorbed in the small intestine and turns into active forms. The products of its metabolism are excreted by the kidneys and are not toxic (Loginova N.Yu., 2017). It should be noted that pyridoxine affects the exchange of amino acids by participating in transamination, decarboxylation, and oversulfurization. So, enzymes, which include phosphopyridoxal, promote the transfer of sulfur from methionine to serine and the formation of cysteine. Together with serine, it also participates in the synthesis of sphingolipids. Along with this, it influences the formation of biogenic amines vital for the body, in particular colamine. Pyridoxine is able to interact with succinic acid, with the formation of oxypyridines, the spectrum of antioxidant and antihypoxant action of which is quite wide (Loginova N.Yu., 2017).

This method, which we took as a prototype, consists in the fact that colamine, succinic acid, serine and pyridoxine chloride were used to process the eggs of beef cross hens. The hatch rate of chickens was 2.47% higher and amounted to 91.67% (versus 89.20% in the control). At the same time, the components of this composition have never been used for the treatment of incubation eggs of hens of the egg production direction.

The purpose of the invention is to increase the stress resistance of egg chickens by pre-incubation treatment of eggs before laying them for incubation with an aqueous solution of the composition: pyridoxine hydrochloride, serine, succinic acid and colamine, taken in optimal concentrations.

The method is carried out as follows.

An aqueous solution of biologically active substances - colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations: 0.1% 0.1%, 0.2%, 0.1%, respectively, is applied to the surface of the shell 3-4 hours before incubation from a spray bottle. They are preliminarily dissolved and mixed in distilled water at 18-22 ° C.

The stated concentrations were found in the serine of previous experiments and are optimal.

Example 1. Eggs of hens of the cross "Hisex white" were obtained from one parent flock, sorted by 189 pieces in each batch, while observing the same weight, laying time and shelf life. A solution of the studied BAS was applied to the surface of the shell from a spray bottle according to the above scheme. As a control, eggs of the same batch were selected according to the principle of analogues, which were processed according to the technology adopted in the farm.

According to I.M. Donnik. (2015), a higher level of stress resistance of individuals is associated with a higher viability of an individual in ontogenesis, which was confirmed in our work (Table 1).

It follows from the table that the hatching of chickens in the pilot batch exceeds the control by 2.65%, and the hatchability of eggs by 1.85%, which is due to a decrease in all presented incubation waste, in particular such as: "infertile" by 13%, this is possible only by reducing the "false infertility"; “Blood rings” by 3 times, “frozen” by 14%, “suffocated” by 1.75 times, respectively. The slight difference in the indices of embryonic viability between the experiment and the control is a significant achievement, due to the fact that their values were higher than the standards even in the group of individuals that were not exposed to the composition of the studied biologically active substances. In turn, the work of N.V. Tikhonova (2014) ,, Nefedova S.A. (2018, Shikhaleva S.V. (2015) indicate that in this case it is hardly possible to obtain a positive result.

Research Donnik I.M. (2015), Saifutdinova L.V. (2019), Tsareva P.Yu. (2018) indicate that there is a close relationship between the optimizations of the hematological background, the level of long-term adaptation, and at the same time the resistance to stress and the viability of an individual. In this regard, it becomes obvious that the recorded higher embryonic viability was largely due to positive hematological changes.

Example 2. A general clinical blood test was taken from the obtained chickens. The data are presented in Table 2.

As can be seen from the table, the content of erythrocytes in chickens from the experimental group significantly increased by 2.35 times (p <0.01), apparently due to the optimization of hematopoiesis processes by the composition of the studied BAS (Yartseva I.S., 2014).

Literature data concerning the interpretation of the content of leukocytes indicate that under stress, their content can both increase (Sayfutdinova L.V., 2019) and decrease (Tsarev P.Yu., 2018), depending on the type of stress. Such studies have been widely carried out only on young chickens or adult birds, while on embryos and chickens of one day old, they are presented scattered and fragmentary.

At the same time, regardless of the age of the bird, leukocyte indices are generally accepted, which can largely predetermine the rate of transition to "long-term adaptation", i.e. increased stress resistance. The Krebs index (IC), which is the ratio of segmented neutrophils to lymphocytes, shows that its large value under conditions of any stress characterizes a faster transition to long-term adaptation. Similar dynamics also applies to the leukocyte intoxication index (LII), which is the ratio of neutrophils to the sum of lymphocytes, monocytes, eosinophils and basophils. This index will help to determine the presence of intoxication processes in the body of birds, as a marker of the intensity of the stress reaction (Donnik I.M., 2015).

The lymphocyte-granulocyte index (IPH) is the ratio of the number of lymphocytes to the total number of granulocytes, and the leukocyte index (LI) is the ratio of lymphocytes to neutrophils. In the case of IPH and LI, the dynamics of their decrease characterizes a higher level of stress resistance due to a faster transition to long-term adaptation (Donnik I.M., 2015).

The data in Table 2 confirm the greater stress resistance of the chickens in the experimental group than in the control group, which is consistent with the above literature data.

Thus, in individuals of the experimental group, IC was significantly higher by 1.74 times (p <0.01), LII by 5.53%, LI was lower by 1.67% (p <0.05), and ILH by 1 , 75 times (p <0.05) relative to control. At the same time, the percentage of leukocytes in the leukoformula in the representatives of the experimental and control groups did not differ significantly and was within the physiological norm (Table 3).

It should be noted that the rapid transition to long-term adaptation in the chickens of the experimental group is confirmed by the indicator of the body length, which, according to L.V. (2014) tends to be shortened with an increase in stress resistance in replacement chicks and adult birds, which is confirmed by the data presented (Table 4).

As can be seen from the table, at the age of 60 days, there is a tendency to shorten the trunk by 2.12% relative to the control. Considering that chickens up to 60 days of age pass through the main critical periods of development and stages of adaptation to external environmental factors, we considered it appropriate to determine the above indicator at this age (Ageechkin A.P., 2010).

Optimization of the hematological background, causing a higher stress resistance of individuals, determined the long-term effect of the aftereffect of the studied composition of biologically active substances, expressed in an increase in safety during the main critical periods of postembryonic development of chickens (Table 5).

As can be seen from Table 5, during the study period, the death rate in the experimental group was halved relative to the control.

Thus, the use of the specified composition before incubation of eggs contributed to the optimization of the hematological background, and at the same time the rapid transition of the experimental individuals to long-term adaptation, which led to a greater stress resistance of chickens in ontogenesis, determining an increase in the safety of the livestock.

Literature:

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Claims (1)

A method of increasing the stress resistance of young chicken crossbreeds using biologically active substances before incubation, characterized in that the processing of incubation eggs is carried out once, namely 3-4 hours before laying in the incubator, an aqueous solution of metabolites is applied from a spray bottle to the surface of the shell from a spray bottle: colamine, succinic acid , serine and pyridoxine hydrochloride, in concentrations of 0.1%, 0.1%, 0.2%, 0.1%, respectively, and the preparations are preliminarily dissolved in distilled water at 18-22 ° C.