RU2765123C1 - Method for increasing the number of conditioned young guinea fowls - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture, namely to poultry farming, in particular to guinea fowl farming. The method for increasing the number of certified young guinea fowl is that the processing of incubation eggs is carried out once. At the same time, an aqueous solution of biostimulants: colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations is sprayed onto the surface of the shell 6-8 hours before being placed in the incubator: 0,1%, 0,1%, 0,2%, 0,01% accordingly. Moreover, the preparations are pre-dissolved in distilled water at a temperature of 18-22°C.

EFFECT: invention provides an increase in guinea fowls hatching rate and the hatchability of eggs, an increase in the number of certified growing birds.

1 cl, 5 tbl, 3 ex

Description

The invention relates to agriculture - poultry farming, and in particular - guinea fowl breeding (pre-incubation application of a solution containing colamine, series, succinic acid and pyridoxine hydrochloride).

Guinea fowl breeding is a relatively new, intensively developing poultry sub-sector, the task of which is to produce dietary meat and eggs. As is known, the products of this sub-sector have a rather high cost relative to other poultry products, which is associated with a long growing period, lower meat and egg productivity compared to other types, as well as the initially high cost of hatching eggs imported from abroad, and, consequently, caesar (Ageechkin A.P., 2010). At the same time, in the process of incubation of guinea fowl eggs, there are the same technological stresses as during the incubation of eggs of other bird species. In this regard, the use of biostimulants that increase the embryonic viability of caesarlings will contribute to a more significant profitability of production. In general, caesar farms, relative to other poultry farms, have much lower production volumes, however, an increase in the profitability of this industry, even in small farms, will increase the profits of caesar farms.

At the same time, it has been scientifically proven that the caesar shell is quite thick, and also has a mesh structure full of various channels, which significantly reduces the shrinkage of eggs during incubation and increases their shelf life (Spiridonov I.P., 2017). In connection with this feature, scientists did not conduct experiments related to the treatment of caesar eggs with solutions of biostimulants due to the prevailing opinion about poor permeability and small pore size of the shell. However, studies have shown that the treatment of hatching eggs of guinea fowl with solutions of biostimulants is not only possible, but also effective, given that these substances have a molecular size of several nanometers, and the pore size can be several micrometers, which is hundreds of times larger, so the possibility of substances " reach" to the embryo is available, despite the fact that it is lower than in other bird species with a simpler structure of the egg shell (Spiridonov I.P., 2017). At the same time, the processing of hatching eggs should be carried out not 3-4 hours before incubation, as in other types of poultry, but 6-8 hours before, due to the greater thickness of the shell and the longer passage of biostimulants through the shell.

It is known that hatching eggs are treated with solutions of colamine, succinic acid, serine and pyridoxine hydrochloride in order to stimulate the embryonic development of chickens of meat crosses (Azarnova T.O., 2020). Succinic acid and its salts have adaptogenic properties and have antihypoxic, antioxidant and neurotropic effects, normalize energy, plastic metabolism and the general physiological state of the body (Evglevsky 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 animal body, improves phosphorus and protein metabolism and, therefore, is a growth stimulator (Shipunova N.N., 2014). In turn, the series is a glycogenic amino acid, which is part of the phospholipids of cell membranes and the active centers of many enzymes (Garaeva S.N., 2009). Vitamin B6 (pyridoxine hydrochloride) is a water-soluble vitamin whose active form is phosphorylated derivatives: pyridoxal phosphate and pyridoxamino 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, and cysteinonase. With the participation of vitamin B6, the reaction of the formation of 5-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, vitamin B6 is used in the form of pyridoxine hydrochloride. In the process of metabolism, it is absorbed in the small intestine and converted 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 is able to influence the metabolism of amino acids containing sulfur, taking part in oversulfonation, i.e. transfer of sulfhydryl groups from one compound to another. So, enzymes, which include phosphopyridoxal, promote the transfer of sulfur from methionine to series and the formation of cysteine. Together with serine, it is involved in the synthesis of sphingolipids. It also takes part in the formation of biogenic amines, such as 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). Thus, the addition of a previously studied composition consisting of colamine, succinic acid and serine with vitamin B6 expands the spectrum of antioxidant, hematoprotective, metabolism-stimulating antihypoxic action of previously proposed biostimulants, causing prerequisites for a better formation of tissues, organs, and the whole organism.

The use of vitamin B6 to stimulate the embryonic development of birds has not been studied. It should be noted that this composition of biostimulants has never been used to stimulate the embryogenesis of guinea fowl, as well as any other biostimulants. This processing of hatching eggs of guinea fowl is the first and only one of its kind.

This method, taken by us as a prototype, consists in the fact that colamine, succinic acid, serine and pyridoxine hydrochloride were used to process meat cross chicken eggs. The output of chickens was higher by 2.47% and amounted to 91.67% (against 89.20% in the control).

A distinctive feature of this invention is the first treatment of guinea fowl hatching eggs with solutions of biostimulants, carried out by an aerosol method, which is associated with better penetration of small aerosol particles through the shell, in contrast to the spray method. This processing method was chosen due to the fact that the pores of guinea fowl eggs are the smallest among all bird species. Also, the processing is carried out in 6-8 hours, and not in 3-4 hours, because. In the course of experiments, it was found that solutions of biostimulants need more time to pass through the small pores of guinea fowl eggs. The concentration of pyridoxine hydrochloride, in contrast to the prototype, is also different and it is several times less, despite the approximately the same mass of eggs of guinea fowls and chickens of the meat direction of productivity. This is due, in our opinion, to the species peculiarity of guinea fowls, which we revealed during the experiments, since initially the content of vitamin B6 in the eggs of guinea fowls and chickens is approximately the same (Ageechkin A.P., 2010).

The purpose of the invention is to increase the indicators of hatching of cesarean chicks and hatchability of eggs, increase the number of conditioned young animals, as well as the economic efficiency of production by pre-incubation treatment of eggs before laying for incubation with an aqueous solution of pyridoxine hydrochloride, serine, succinic acid and colamine.

EFFECT: increase in hatching of caesarlings by 1.29%, hatchability - by 1.14% relative to control, increase in live weight of young animals by 11.2%, and safety - by 2.44%. This is achieved by processing hatching eggs, before laying in the incubator by a single application of an aqueous solution of biostimulants: colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations: 0.1%, 0.1%, 0.2%, 0.01%, respectively. The preparations are pre-dissolved in distilled water at a temperature of 18-22°C.

The method is carried out as follows.

An aqueous solution of preparations - colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations of 0.1% 0.1%, 0.2%, 0.01%, respectively, is aerosolly applied to the surface of the shell 6-8 hours before incubation. These concentrations of biostimulants have been determined in previous experiments. Pre-biostimulants are dissolved and mixed in distilled water at a temperature of 18-22°C.

Example 1. When carrying out a production check, gray-speckled guinea fowl eggs were obtained from one parent herd, sorted 1008 pieces in each batch, while observing the similarity of weight, demolition time and shelf life. A solution of drugs was applied to the surface of the shell from a spray gun 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. The data obtained are presented in table 1.

Table 1 shows that for all categories of incubation waste there was a decrease in the experimental batch, while the hatching of caesarlings in the experiment was 78.97%, which exceeds the control by 1.29%, and hatchability - 79.68% - which is 1. 14% more control.

Example 2. When removing cesarean chicks from the incubator, this process in this farm is carried out in 3 stages: on the day of hatching, on the next day, and on the third day. According to the rules of biocontrol of incubation, a healthy self-hatched young is considered conditioned, the extraction of which was carried out on the first day after hatching, the rest of the individuals that hatched later are substandard and low-viable, and their death during subsequent cultivation can reach up to 70% (the survival rate of these individuals is not more than one third) (Ageechkin A.P., 2010). Given the high cost of imported hatching eggs of guinea fowl, during the hatching process, specialists try to get the maximum possible number of young and carry out the main dredging on the day of hatching, then put the remaining eggs back into the incubator and drench the guinea fowl for another two days. Thus, on a caesar farm, they are trying to increase the output rates, but subsequently, most of these individuals die. It was calculated how many heads hatch each day after hatching in the experimental and control groups. The data are presented in table 2.

As can be seen from the table, in the experimental group, most of the young animals are conditioned, since their seizure was carried out on the first day of the hatching of the cesareans. These data confirm the best quality, and therefore the viability of individuals during further cultivation, which was proved further. At the same time, almost all cesareans of the first day of harvesting hatched on their own, and the cesareans of the second and third days of harvesting required additional help during hatching (complete or partial disposal of the shell).

As can be seen from the table, the dynamics of the case in the control is much more intense than in the experiment. Obviously, the main individuals that increased the mortality statistics were substandard cesareans on the second and third days of harvest after hatching. It should be noted that during the period under consideration (60 days), 18 less animals fell in the experimental group than in the control, which is associated not only with a large number of guinea fowl in the experimental group hatched from treated eggs, but also with a large number of individuals bred in first day of withdrawal.

It should be noted that in conditional cesarean chicks on the first day of harvesting, the live weight at the daily age was determined, which in the experiment was slightly higher than in the control, which, according to Ageechkin A.P. (2010) is one of the signs of high-quality and healthy young animals (Table 4).

From table 4 it can be seen that the mass of caesarlings of the experimental group exceeds the control by 11.2%, which once again confirms the biological usefulness of the young animals of the experimental group.

Example 3. In the process of taking into account indicators of biocontrol of incubation, the economic efficiency of processing hatching eggs was calculated (table 5).

At a price for 1 head of daily guinea fowl 178 rubles. the profit was in the experimental group (minus the cost of additionally obtained chickens, the cost of biostimulant solutions) per 1000 pcs. laid eggs:

13 * 178 - (676 + 1.95) \u003d 1636.05 rubles.

Despite the relatively small increase in hatching, the economic effect obtained significantly exceeds that for other types of birds when using biostimulants, which is associated with the initially higher cost of guinea fowl even at a day old by several times compared to other types of poultry.

Based on the foregoing, it can be concluded that the use of biostimulants before incubation of guinea fowl eggs is economically feasible and will improve biocontrol indicators and the number of conditioned young.

Literature:

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

2. Spiridonov, I.P. Incubation of poultry eggs from A to Z: encyclopedic reference dictionary / I.P. Spiridonov, A.B. Maltsev, A.B. Dymkov; Sib. scientific research institute of poultry farming. - Omsk: Maksheeva E.A., 2017. - 593 p.

3. Azarnova T.O., Lugovaya I.S., Kochish I.I., Naydensky M.S., Lugovoi M.M., Antipov A.A. / A method for optimizing the histogenesis of the organs of the gastrointestinal tract in chicken embryos of the meat direction of productivity when using biologically active substances before incubation to increase and synchronize the hatching of chickens by preventing oxidative stress in chicken embryos // patent No. 2711748 of 01/21/2020

4. Evglevsky, A.A. 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.

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

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

7. Loginova N.Yu. Vitamin B6: General aspects of metabolism / N.Yu. Loginova //In the collection: Fundamental and applied scientific research: topical issues, achievements and innovations collection of articles of the winners of the V International Scientific and Practical Conference: in 4 parts. - 2017. - S. 226-229.

Claims (1)

A method for increasing the number of conditioned young guinea fowls, characterized in that the processing of hatching eggs is carried out once, namely, 6-8 hours before laying in the incubator, an aqueous solution of biostimulants is aerosolly applied to the surface of the shell: colamine, succinic acid, serine and pyridoxine hydrochloride in concentrations: 0.1%, 0.1%, 0.2%, 0.01%, respectively, and the drugs are pre-dissolved in distilled water at a temperature of 18-22°C.