RU2844156C1 - Fodder additive for increasing productivity of fattening piglets and hens - Google Patents

Abstract

FIELD: animal husbandry.

SUBSTANCE: invention relates to animal breeding, particularly to growth-stimulating, immunostimulating agents for animals. Feed additive includes cobalt (II), synthesized with compound of 2-amino-4-(S-methylsulphonimidolyl)butanoic acid with following ratio of ingredients, wt. %: cobalt (II) 23.7, 2-amino-4-(S-methylsulphonimidolyl)butanoic acid compound is the balance.

EFFECT: invention usage allows to enhance animals productiveness.

1 cl, 10 tbl, 4 ex

Description

The invention relates to animal husbandry, in particular to growth-stimulating and immunostimulating agents for animals.

It is known to obtain a preparation containing the compound 2-amino-4-(S-methylsulfonimidolyl)butanoic acid by synthesis (Strunin B.P. Biologically active functionalized amino acids: amino acids: synthesis, structure, technology / Abstract of a dissertation for the degree of Doctor of Technical Sciences. - Kazan. - 2005. - 37 p.), used in poultry farming and livestock breeding.

The disadvantage of the well-known drug is its weak growth-stimulating and immunostimulating effect.

The closest in technical essence is the invention (RU patent No. 2154951, class A23K 1/16, 2006), which includes the compound 2-amino-4-(S-methylsulfonimidolyl)butanoic acid.

The disadvantage of the prototype is its weak growth-stimulating and immunostimulating effect.

The technical result is increased productivity due to improved metabolism and enhanced immune response.

The technical result is achieved in that the feed additive for increasing the productivity of fattening piglets and chickens, including the compound 2-amino-4-(S-methylsulfonimidolyl)butanoic acid, according to the invention, contains cobalt (II) synthesized with the compound 2-amino-4-(S-methylsulfonimidolyl)butanoic acid in the following ratio of ingredients, mass %: cobalt (II) - 23.7, the compound 2-amino-4-(S-methylsulfonimidolyl)butanoic acid - the rest.

The novelty of the claimed technical solution is that a new compound of 2-amino-4-(S-methylsulfonimidolyl)butanoic acid with cobalt (II) has been synthesized. The technical result is achieved, namely, increased productivity due to increased immune response.

The feed additive is a purple powder. It has no smell. The working name is "Cobametin".

The median lethal dose of the compound 2-amino-4-(S-methylsulfonimidolyl)butanoic acid (prototype) for rats is 1454.17 mg/kg. The median lethal dose of cobamethamine for rats is 1533.4 mg/kg of body weight. According to GOST 12.1.007-76, the feed additive belongs to hazard class III (moderately hazardous substances).

The preparation is stored in the manufacturer's packaging in a dry, dark place at a temperature from minus 20°C to 40°C. The shelf life of the feed additive is 5 years from the date of manufacture.

The feed additive is obtained as follows.

Obtaining a complex of 2-amino-4-(S-methylsulfonimidolyl)butanoic acid with cobalt (II). In a three-necked flask equipped with a stirrer, thermometer and heater, load cobalt (II) chloride and 2-amino-4-(S-methylsulfonimidolyl)butanoic acid in a molar ratio of 1:1, add the required amount of distilled water, calculated to form a lightly mobile suspension, stir at room temperature for 10 minutes. Then bring to pH = 8 with an inorganic base (sodium bicarbonate) and stir for another 10 minutes. The resulting violet precipitate is filtered through a paper filter. Next, the precipitate is washed with a small amount of distilled water and dried at a temperature of 50-60°C, obtaining a complex of 2-amino-4-(S-methylsulfonimidolyl)butanoic acid with cobalt (II), the complex is in the form of a hydrate with 2 water molecules.

Analysis: cobalt content 23.1 wt.% (theoretical 23.7%).

IR spectroscopy data: the band at 3400 cm ^-1 corresponds to vibrations of (V _OH ) and the bands at 570-600 cm ^-1 correspond to vibrations of VC _O O and C _ON .

Example 1

To confirm the effectiveness of the claimed feed additive cobametin, production tests were conducted in poultry farming, namely for laying hens and broiler chickens.

The experiment involved 20-week-old laying hens of the Hisex Brown cross. The birds involved in the experiment were divided into three groups. The distribution of the birds into groups was carried out taking into account their preliminary weighing and clinical condition. The experiment was carried out for 30 days.

The structure of the experiment on feeding the feed additive cobametin in the diet of laying hens is presented in Table 1.

The results of determining some zootechnical indicators are presented in Table 2.

Analyzing the obtained data, it is clear that the use of the feed additive cobametin in the diet of laying hens increased the survivability of the livestock in the 1st experimental group by 2.0%, in the 2nd experimental group by 2.8% relative to the control. The number of laying hens subject to culling was the largest and amounted to 3.4% of the total. In the second experimental group, the lowest percentage of culling was recorded, it was at the level of 0.6%, which is 2.8% less than the control group and 0.9% relative to the first experimental group.

Changes in the live weight of poultry during the growing process are an important zootechnical indicator indicating the correct course of metabolic processes, growth and development of tissues and organs and the bird's body as a whole.

The dynamics of live weight were monitored by groups; the indicators we took into account and the data obtained are reflected in Table 3.

Compared to the control group, the overall increase in body weight of laying hens in the 1st experimental group was 7.3% higher, and in the 2nd experimental group it also exceeded the control by 15.8%.

The average daily live weight gain during the rearing period by group was as follows: in the 1st experimental group it was 11.0 g, which is 8.9% higher than the control value; in the 2nd experimental group this value was 12.1 g, which is 19.8% higher than the control value.

One of the main indicators of the productivity of laying hens is their egg production. In the process of egg formation, the bird spends a large amount of biologically active macronutrients, such as proteins, fats and carbohydrates. Internal stress occurs due to the constant mobilization of substrates not only to maintain the vital activity of the bird's body, but also for formation. Mineral compounds support enzymatic processes at all stages of the formation of egg and meat products. During the egg production period, the bird is most sensitive to the effects of pathogenic microorganisms on its body. More than 70% of the immune system in the bird's body is in the intestine, so additional introduction of feed additives into the diet that have a beneficial effect on the intestinal microbiome is necessary to increase the quantity and quality of the resulting egg products. Due to the stabilization of the amount of beneficial microflora, which takes an active part in the processes of digestion of the main nutrients, their more complete absorption and involvement in metabolic processes occurs, which subsequently leads to a decrease in the cost of the resulting products.

The authors investigated the effect of the feed additive cobametin on egg production of laying hens over a 30-day period. The results are shown in Table 4.

According to this table, it can be stated that in the 1st experimental group, the total number of eggs laid per group exceeded the control group by 15.2%, and in relation to the 2nd experimental group, this value was 12.6% less.

If we analyze this indicator (the total number of eggs per group, pcs.) in the second experimental group, it was 23% higher than the control values, and 11.2% higher than the 1st experimental group.

The average number of eggs per laying hen in the second experimental group was 18.1% higher than in the control group, and 9.0% higher in the first experimental group.

The egg production intensity was calculated taking into account the average number of eggs per bird, multiplying by 100 and dividing by 30 (the number of days of feeding the feed additive). The egg production intensity of laying hens in the 2nd experimental group exceeded the control indicator by 13.3%, and was higher than the indicator of the 1st experimental group by 7.3%.

During the experiment, we determined the total consumption of compound feed per group during the experimental period, the consumption of compound feed per laying hen, and calculated the feed conversion for the production of ten eggs.

The effect of the feed additive cobametin on feed consumption during the experimental period in the diet of laying hens is reflected in Table 5.

The results of the zootechnical indicators presented in the table allow the authors to make the following conclusion that the total consumption of compound feed in the 2nd experimental group was 7.0% less than in the control group, and in relation to the 1st experimental group, compound feed was also consumed 2.0% less. The lowest consumption of compound feed per laying hen was noted in the 2nd experimental group and in relation to the control it was 13.6% less, in the 1st experimental group this indicator was 8.0% lower than the control.

The feed conversion rate calculated by the authors for the production of 10 eggs showed that the lowest feed conversion rate was in the 2nd experimental group, relative to the control indicator it was 33.0% lower, relative to the 1st experimental group it was also 13.0% lower.

To assess the quality indicators of laying hens' eggs, the authors selected eggs from each group and weighed them at the beginning and end of the experiment. The thickness of the shell was determined. The results obtained are reflected in Table 6.

Having examined the obtained data, the authors came to the conclusion that the average egg weight in the second experimental group at the end of the experiment was 4.5% greater than in the control group and exceeded the value of this indicator in the first experimental group by 1.5%.

The surface of the eggs in all experimental groups was without visible defects and deformations. In relation to the thickness of the eggshell in laying hens in the second experimental group, relative to the control, during the experimental period it increased by 6%, relative to the first experimental group it was thicker by 4.2%.

Conclusion

Introduction of the feed additive cobametin into the diet of laying hens at the rate of 2.0 mg/kg of body weight (2nd experimental group) resulted in a reliable increase in the weight of the bird relative to the control group by 15.8%, relative to the 1st experimental group (commercial analogue) there was also an increase of 9.0%. The percentage of egg production intensity in the 2nd experimental group exceeded the control indicators by 13.0%, relative to the 1st experimental group the increase was by 7.0%. The qualitative indicators of the produced eggs were tracked by their weight and shell thickness at the end of the experiment. In the 2nd experimental group, the egg weight was 3.2% greater than the control indicator, and 1.2% greater than the indicator in the 1st control group. The shell thickness in the 2nd experimental group was 11.0% greater than the control indicator, and 4.8% greater than the 1st experimental group.

Example 3

Study of the immune response of broiler chickens to vaccination against Newcastle disease

The aim of our study was to investigate the effect of cobametin feed additive on the immune response of broiler chickens when vaccinated against Newcastle disease (ND).

To conduct the experiment, we took three-day-old broiler chickens. A control group (n=30) and an experimental group (n=30) were formed. The diet of the control broiler chickens consisted of compound feed without the additive. The experimental group included the feed additive cobametin in the main diet, starting from the age of 10 days and up to the 42nd day in the optimal concentration, which the authors determined in the previous sections of the work, it is 2.0 kg/t.

To immunize chickens, a live vaccine against Newcastle disease from the Bor-74 VGNKI strain was used, using the intranasal vaccination method.

The instructions for use of the vaccine indicate that one commercial dose of the vaccine for nasal use is 6.0 lg EID ₅₀ /cm ³ of the NB virus strain "Bor-74 VGNKI". Before using the vaccine, in order to preserve the integrity of the antigen, it was diluted with a 0.85% sodium chloride solution (isotonic solution). The active acidity of the isotonic solution was within the pH range of 7.2-7.4. The volume of the isotonic solution with which one dose of the vaccine was diluted was 0.1 cm. One drop of the diluted vaccine contained a volume of 0.05 ml.

Nasal administration of the vaccine to broiler chickens using a pipette was performed with 2 drops in one nostril, the second nostril was closed with fingers in order to ensure deeper penetration of the vaccine into the bird’s nasal cavity [4].

The first vaccination was carried out at the age of 4-5 days, then the chickens were revaccinated twice at the age of 17-18 and 31-33 days in accordance with the vaccination schedule adopted on the farm. Before vaccination, the birds were subjected to a clinical examination with selective thermometry.

Blood was taken from broiler chickens of all groups involved in the experiment 14 days after vaccination and each revaccination for testing in the hemagglutination inhibition reaction (HIR) in order to establish the effectiveness of the vaccination and the intensity of antibody formation in response to the administration of the vaccine.

The vaccination carried out is considered effective if after 14 days the antibody titer in the hemagglutination inhibition reaction in at least 80% of the blood serum samples of the experimental birds is at least 1:8 or higher. The authors showed the data we obtained on determining the antibody titers in the blood serum of broiler chickens in the table and in the drawing.

As a result of determining the antibody titer in the blood serum of broiler chickens, it was established that 2 weeks after the first vaccination, the immune response was weakest in both the control and experimental groups.

At the same time, in the experimental group of chickens, the level of antibodies was 1.16 times higher than in the control group.

Two weeks after the first revaccination (study 2), the antibody titers to Newcastle disease virus in broiler chickens were more than ten times higher than after the first vaccination in both groups, but in the experimental group chickens this indicator was 1.3 times higher relative to the control. Fourteen days after the second revaccination (study 3), the average amount of antibodies in broiler chickens of the experimental group exceeded the control indicator and amounted to 231.9 log ₂ . The results obtained are presented in Table 7.

A somewhat different picture of the antibody content in the blood serum was observed in broiler chickens of the control group. After the first revaccination, there was a significant drop in the antibody titer, compared to the antibody titer indicators of the experimental group, more than four times.

The authors tend to associate the higher level of antibodies in the experimental group chickens with the positive effect on the immune system and the process of antibody formation of the feed additive cobamethin, which they received in addition to the main diet.

Determination of antibody titers in the blood serum of chickens after immunization is of great practical importance, since their value is not only decisive for making a decision on revaccination, but is also an indicator that determines the degree of protection of the livestock from the ND pathogen. If 20% or more of the vaccinated livestock have an antibody titer below 4 log ₂ , the level of immune protection is insufficient and revaccination should be carried out immediately. The results of determining the intensity of immunity in chickens of the experimental group and in the control are reflected in Table 8.

The results obtained by the authors indicate that after the first vaccination, in the control group and in the experimental group, the immunized chickens had a level of immunity intensity lower than required, since 23.3 and 30% of the livestock, respectively, had an antibody titer lower than 4 log ₂ . The first revaccination made it possible to achieve a higher level of immunity intensity in vaccinated chickens.

The immunity intensity studied by us in chickens after the second revaccination showed the following picture. In the control group, this indicator was at the level of 76.7% and did not even reach the threshold value, while in the experimental group, the immunity intensity was significantly higher and amounted to 96.7%.

Conclusion

As a result of our experiment on the inclusion of the feed additive cobametin in the diet of broiler chickens in the amount of 2.0 kg/t of feed of the main diet, we found that it has a positive effect on the immune status of chickens, contributes to the formation of a more intense immunity in 97-100% of the livestock, while the level of antibody titers exceeds the indicators of the control group from 1.2 to 4.5 times at different times of immunization.

Example 4

Efficiency of the use of the feed additive cobametin in growing fattening piglets

To solve this problem, the authors monitored the effect of the feed additive on zootechnical indicators reflecting the physiological state of the piglets’ organism, blood indicators indicating changes in homeostasis and metabolic processes, as well as the quality indicators of the resulting products.

The experimental design is shown in Table 9.

For the experiment, piglets aged 120 days were taken, with an average body weight by group: in the control group, the average weight of piglets was: in the control group 36.2±1.18, in the first experimental group 36.6±1.23, in the second experimental group 35.7±1.05 kg, in the third experimental group 36.3±1.12 kg.

In the control group, piglets did not receive the feed additive cobametin as part of their diet and were kept on the main diet.

The piglets of the first experimental group were given a commercial analogue of the feed additive in the composition of the main diet at a dosage of 3 mg/kg of live weight. The second experimental group received the feed additive cobametin in the composition of the main diet at a dosage of 3 mg/kg of live weight. In the third experimental group, the feed additive was added to the composition of the main diet at a dosage of 4 mg/kg of live weight.

The feed additive cobametin was included in the daily ration of piglets in experimental groups from 120 days old until the piglets reached a weight of 100 kg. The entire experimental period lasted 125 days.

During the experiment, the following parameters were taken into account in the experimental and control groups: average live weight of one head (kg) when entering the experiment and removing from the experiment; age at reaching 100 kg of body weight; average daily (g) and total body weight gain (kg).

average daily consumption of compound feed per 1 head (kg); cost of compound feed required per 1 kg of gain (kg), livestock safety.

After the end of the scientific experiment, blood was taken from six piglets from each group of piglets involved in the experiment in order to study the safety of the effect of the feed additive cobametin on the homeostasis system, monitoring the morphological parameters of the blood, as well as the effect on metabolic processes, determining and analyzing biochemical parameters.

The results of the experiment are presented in Table 10.

Analyzing the data on zootechnical indicators, it can be stated that the inclusion of a commercial analogue of the feed additive cobametin in the main diet of fattening pigs (I experimental group) led to an increase in live weight by 4.3% relative to the control at the end of the experiment, in the II experimental group this indicator exceeded the control by 11.2%, in the III experimental group the body weight was greater than the control indicator by 11.4%, and relative to the II experimental group the increase reached only 0.2%.

The authors also recorded the age of the piglets when they reached a weight of 100 kg. In the first experimental group, this weight was reached on the 245th day of fattening, which occurred two days earlier than in the piglets of the control group.

In comparison with the control group, in the first experimental group this weight was noted in piglets at 245 days, which is two days earlier than the control indicator. In the second experimental group, the body weight of 100 kg was reached at 241 days, which is six days earlier than in the piglets in the control group. The weight of 100 kg in piglets of the third experimental group was recorded earlier than in the control group by 7 days, in the first experimental group by 5 days, but the difference in achieving this body weight in comparison with the second experimental group was only one day.

The increase in body weight over the entire period of the experiment is a very important zootechnical indicator, which reflects not only the results of the effect of the feed additive on metabolic processes, but also allows obtaining a larger amount of high-quality products. The lowest increase in body weight was recorded in the control group, this indicator was at the level of 66.0 kg, which is 6.3% lower than the indicator of the 1st experimental group (70.2 kg), 17.0% less than in the 2nd experimental group (77.2 kg), 18.4% lower than in the 3rd experimental group (78.2).

Comparing the indicators of the 1st experimental group, which included a commercial analogue at a dosage of 2 mg/kg, and the 2nd experimental group, where the feed additive cobamethin was used at a similar dosage, the difference in favor of the feed additive was 10.7%.

The difference between the total body weight gain in the second and third experimental groups in percentage terms was 1.4%, in favor of the third experimental group, where the feed additive cobamethin was included in the main diet in the amount of 4 mg/kg of body weight.

Analysis of data on average daily body weight gain correlates with the results of total body weight gain over the entire experimental period.

Relative to the control group indicator, in the 1st experimental group the average daily gain was 6.2% higher, in the 2nd experimental group this indicator exceeded the control by 16.7%, the indicator of the 3rd experimental group exceeded the control by 18.3%). Comparing this indicator between the second and third experimental groups, the authors see the following data: in the 3rd experimental group the average daily gain exceeded the indicator of the second experimental group by 1.6%.

An important indicator is the daily feed consumption by the experimental groups, the value of this indicator will ultimately affect the total weight of the piglet at the end of the experiment and the selling price. The effect of the feed additive cobametin on the average daily feed consumption.

The average daily feed consumption in the experimental groups for the entire period of the experiment was higher than the control group and was: in the 1st 11.2%, in the 2nd experimental group 19.5% and in the 3rd experimental group 20.5%. Having analyzed the obtained results, it can be stated that the difference in the average daily consumption between the 1st and 2nd experimental groups was 8.3%, in favor of using the feed additive cobamethin. Comparing this indicator between the 2nd and 3rd experimental groups, it differs by only 1%. The increase in the average daily feed consumption in the 2nd experimental group can be explained by the activation of enzymatic processes, starting with the work of hydrolytic enzymes, their increased secretion by the endocrine glands, as well as the rapid growth of the piglets' body, requiring a greater amount of essential macronutrients.

In the experiment, the authors calculated feed conversion, which is determined by the ratio of feed costs to the total body weight gain during the study. The lowest feed conversion, equal to 3.1, was noted in the second and third experimental groups; relative to the control group, this indicator was 24.3% lower. In the first experimental group, feed conversion was 12.1% lower relative to the control. No mortality was recorded in the experimental groups, the survival rate of the livestock was at the level of 100%). In the control group, the mortality was 2 heads, the survival rate of the livestock was 96.0%.

Having analyzed the zootechnical parameters for all groups, the authors came to the conclusion that the introduction of 3 mg/kg of body weight of piglets (II experimental group) and 4 mg/kg of live weight into the basic diet leads to the optimization of the values of these parameters, relative to the first experimental and control groups. In the comparative aspect of the second and third experimental groups, it can be concluded that the values of the main parameters do not have significant differences between themselves, therefore, it is more expedient from an economic point of view to include the feed additive cobamethin into the diet in the amount of 3 mg/kg of animal weight.

In the comparative analysis between the 1st experimental group (use of 3 mg/kg of the commercial analogue) and the control, the authors see the following picture: the live weight of the piglet upon removal from the experiment in the 1st experimental group was higher than the control by 4.3%; the age of reaching 100 kg was 2 days earlier than in the control group; the total weight gain for the entire experimental period (kg) was higher than the control by 6.3%; the average daily weight gain for the experiment (g) was higher than the control group by 8.0%; the average daily feed consumption per head (kg) in the 1st experimental group was lower than in the control by 3.2 kg. The feed conversion in the 1st experimental group was at the level of 3.6, which is 12.1% lower than the control group. With less feed consumption, a greater total body weight gain was obtained for the entire experimental period.

The general conclusion on this section can be made as follows: the feed additive cobametin in the amount of 3 mg/kg of body weight of piglets, when included in the main diet during the fattening period, leads to an improvement in zootechnical indicators compared to the control group and the 1st experimental group using a commercial analogue.

Claims (2)

A feed additive for increasing the productivity of fattening piglets and chickens, including a compound of 2-amino-4-(S-methylsulfonimidolyl)butanoic acid, characterized in that it contains cobalt (II) synthesized with a compound of 2-amino-4-(S-methylsulfonimidolyl)butanoic acid in the following ratio of ingredients, mass %: cobalt (II) 23.7 compound 2-amino-4-(S-methylsulfonimidolyl) butanoic acid rest