RU2490011C1 - Method of cattle adaptation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to agriculture and veterinary science and aims at cattle adaptation when delivering a livestock from the other regions. A preparation based on an organic compound is administered into the animals. The preparation is a composition in the form of a medical solution of formaldehyde and 0.85-0.95% sodium chloride in ratio of weight portions 2-6:994-998. The composition is introduced intramuscularly two times in a dose of 5.0-6.0 ml per a head every 7-10 days.

EFFECT: method is effective, harmless, has no side effects.

4 tbl, 1 ex

Description

The invention relates to the field of agriculture, in particular, veterinary medicine and can be used to adapt cattle when importing livestock from other regions.

A known method of keeping production groups of cows (see RF patent No. 2054252 according to class IPC A01K 67/02, publ. 02.20.1996), which consists in the formation of animals according to the physiological state of the reproductive function and stage of lactation, while the formation is carried out from uniform in origin , age, weight, adaptation to the same conditions of keeping and feeding, according to natural resistance and specific resistance to non-communicable and infectious diseases.

However, the method is time-consuming and difficult to implement in practice, since it involves the formation of heifers from households that are successful in tuberculosis for at least 4 years. The selection of animals of the same age and milk production is also difficult to do.

In addition, in the current conditions of livestock development, when it comes to adapting imported livestock to new conditions, the task of selecting animals of the same reproductive function and stage of lactation is practically impossible.

There is also a method of adapting animals to stress factors by introducing a feed additive (see RF patent No. 2233099, class IPC A23K 1/16, publ. 07.27.2004), which is used as the succinic acid salt of 2-amino-4 -methylthio- (S-oxo-S-imino) -butyric acid or a mixture of its sulfuric acid or phosphoric acid salt with succinic acid.

However, the use of feed additives does not guarantee the biochemical adaptation of animals to new conditions. As a rule, when a balance of carbohydrate metabolism is reached, a disbalance of protein and fat metabolism can occur.

Closest to the claimed is a method of adaptation of cattle (see RF patent No. 2230526 according to class IPC A61D 7/00, A61K 31/095, publ. 06/10/2004), which consists in the introduction of an organic preparation - selenopyran. This drug is currently approved in the Russian Federation as a component of biologically active additives (San. Epid. Conclusion No. 77.99.03.2.241. B.000329.10.03 of 10.31.2003).

The principle of the drug’s action is to release selenium from a bound state and its involvement in biochemical processes in stressful situations caused by illnesses, during emotional stress and nervous breakdowns, in case of poisoning and poor-quality food intake.

In addition, unlike inorganic forms of selenium, selenopyran is insoluble in water, but soluble in fats, it is inactive with respect to microorganisms and does not increase the acidity of gastric juice (see, for example, http://www.biokor.ru/info_407) .

The invention is aimed at solving the problem of creating an effective, harmless and non-side-effect method for adapting cattle regardless of changes in their conditions of feeding and feeding by regulating the bonds of protein, carbohydrate and lipid metabolism at the same time, as well as changing the ratio of energy and plastic metabolism.

To solve the problem in the method of adaptation of cattle, which consists in the introduction of a preparation based on an organic compound, according to the invention, as a preparation based on an organic compound, a composition in the form of a mixture of a solution of formaldehyde of 36.5-37% concentration with a solution of sodium chloride is used 0.85-0.95% concentration with the ratio of their weight parts 2-6: 994-998, while the composition is administered twice intramuscularly at a dose of 5.0-6.0 ml per head with an interval between injections of 7-10 days .

The sources of patent and scientific and technical information known to the authors do not describe an effective, non-toxic, easy-to-implement method of adapting cattle to new conditions of feeding and feeding when animals are imported from other regions (Russia or neighboring countries).

All currently existing methods for adaptation of cattle (cattle) are aimed at preserving the conditions of feeding and feeding that they had there from where they were imported. However, during the importation of animals (from other farms, regions, countries), stressful situations arise that change the physiological state of cattle and lead to the manifestation of various pathologies.

The efforts of livestock specialists aimed at preserving the health of animals during importation include the maintenance of full-fledged balanced diets and the necessary living conditions. This, in turn, predetermines the need to preserve classical correlation relationships in cattle metabolic processes. However, the preservation of these relations when animals are transferred from one condition to another and changes in feeding diets may impede their adaptation.

In this invention, the effect is achieved by optimizing the relationships between metabolic processes (carbohydrate, protein, lipid), as well as by changing the ratio between energy and plastic metabolic processes (the ratio of catabolic and anabolic processes).

A change in these bonds that do not violate the physiological state of animals contributes to their adaptation to new conditions: with full feeding, but a change in the conditions of feeding and diets.

The foregoing allows us to conclude that there is an inventive step in the claimed solution.

An aqueous solution of formaldehyde is a clear, colorless liquid with a peculiar pungent odor, miscible with water and alcohol in any ratio.

Formaldehyde is a representative of the HCNO aldehyde class. It is a colorless gas with a pungent odor, they say. weighing 30.03, its density at 20 ° C is 0.815, the melting point is 92 ° C, and the boiling point is 19.2 ° C. It is soluble in water, alcohol. It polymerizes easily, forming paraformaldehyde during polymerization in an aqueous medium, and polyoxymethylene in anhydrous environments (butane, hexane).

The sodium chloride solution for injection is a colorless, clear, salty taste liquid. The solution is sterile, pyrogen-free.

Sodium chloride - cubic crystals or white crystalline powder, salty taste, odorless. Soluble in water (1: 3).

The inventive tool is a clear, colorless, odorless liquid with a slightly salty taste.

The tool is prepared as follows.

Take 2-6 weight parts of a 36.5-40% medical solution of formaldehyde, add it to 998-994 weight parts of a sterile 0.85-0.95% sodium chloride solution for injection to obtain 0.07-0. 24% formaldehyde solution. The product is stored in a dark place at a temperature of 15-35 ° C.

Example 1. Take 0.2 ml of a 37% medical solution of formaldehyde, add it to 99.8 ml of a sterile 0.9% (or 0.95%) sodium chloride solution. The mixture of solutions is thoroughly mixed. The final concentration of formaldehyde in the resulting product will be 0.074 wt.%.

The studies were conducted on a healthy imported livestock of cattle in the amount of 2915 heifers aged 2-2.5 years.

In the first farm, studies were carried out on 215 heads, of which 92 were experimental, 123 were control. In the second farm - on 2700 heads, of which 1400 were experienced, and 1300 - control.

The drug was administered on the 9-10th day after all diagnostic and quarantine measures at the farms. The introduction was carried out intramuscularly at a dose of 5.5 ml twice with an interval of 7-10 days.

The interval between administrations in the amount of 7-10 days is selected from the following considerations. It was found that the introduction of the drug leads to a cascade change in biochemical parameters.

With an interval of less than 7 days, some biochemical processes “overlap” with others, which, in turn, leads to ambiguous results.

When the interval of administration of the drug is more than 7 days at the time of secondary administration, the metabolic changes caused by the first injection are completely leveled, as a result of which instead of double administration we get the achieved effect - two

Within 5 months, the disposal of animals, the number of abortions, orthopedic and hematological diseases were recorded in both households, and biochemical studies were performed. In addition, after 1.5 years, these indicators were also examined in the second farm, and in addition, indicators on mastitis and calf mortality.

The results of the analysis of the effectiveness of the proposed method of adaptation of cattle are presented in table 1.

Table 1 Analysis of the effectiveness of the adaptation method of cattle The name of indicators Values after 5 months Values of indicators after 1.5 years in the second household I farm II economy Experienced (92 goal) Control. (123 goal) Experience. (1400 goals) Control (1300 goals) Experienced (1400 goals) Control (1300 goals) Forced slaughter 9 goals (9.8%) 15 goals (12.2%) 196 goals (14.0%) 204 goals (15.7%) 196 goals (14.0%) 234 (18.0%) Stillbirth 4 goal (4.3%) 11 goals (8.9%) 65 goals (4.6%) 115 goals (8.8%) 266 goals (19.0%) 234 (18.0%) Hoof disease 8 goal (8.7%) 14 goal (11.4%) no analysis 504 goals (36.0%) 468 goals (36.0%) Mastitis - - - - 98 goals (7.0%) 364 goals (28%) Case of calves 0 156 (12.0%)

From table 1 it follows that after 5 months the forced slaughter of the treated heifers compared with the control from the first farm by 2.4%, stillbirth - by 4.6% and hoof disease - by 2.7% less.

In the second farm, also after 5 months, forced slaughter decreased by 1.7%, stillbirth - by 4.2%.

The values of the indicators after 1.5 years in the experimental group of the second farm indicate a 4% decrease in animal retirement. The manifestation of mastitis after calving is 4 times less. 100% calf safety is provided.

In addition, the milk productivity of cows at the first milk yield was 15% higher compared to the control group (not shown in the table).

In the second farm, after 1.5 years, biochemical blood tests were performed.

Biochemical parameters, as well as the ratio of energy and plastic metabolism, were determined by generally accepted methods. The research results are presented in table 2.

table 2 The results of biochemical studies of blood cows. Options Norm Experience Comte role M ± m M ± m ACT, mkkat 0.75-1.8 1.86 0.2 1.75 0.1 *** ALT, mkkat 0.12-0.58 0.87 0.1 1.45 0.05 *** Coefficient de Ritis 2.14 0.1 1.20 0.05 KK, mkkat 0.2-1.8 2.95 0.4 4.02 1,2 *** LDH, mkkat 5-16 28.28 3.6 19.59 2.1 *** Fermentemia Index 2.42 0.1 1,56 0.2 *** GGT, mkkat 0.1-0.4 0.36 0.04 0.23 0.01 *** Total protein, g / l 62-82 66.81 1,2 59.13 1.7 Albumin, g / l 28-39 29.43 0.6 28.77 0.7 *** Globulins, g / l 29-49 37.39 1,5 30.36 1.9 Albumin / Globulin 0.80 0.04 0.98 0.1 *** Urea, mmol / l 2.8-8.8 3,59 0.2 5.81 0.2 *** Total Protein / Urea 319.53 24.6 170.61 7.4 Glucose, mmol / L 2,3-4,1 3.20 0.2 2.83 0.1 *** Total cholesterol, mmol / l 1.6-5.0 3.90 0.2 1.73 0.1 *** Xs-HDL, mmol / l 2.00 0.1 1.12 0.1 *** Xs-LDL, mmol / l 1.75 0.2 0.47 0.1 *** Atherogenicity Index 0.97 0.1 0.58 0.1 *** p <0.05

From table 2 it follows that the activity of aspartate aminotransferase (ACT) did not significantly differ in groups, however, in the experiment it was slightly higher than in the control. A tendency toward an increase in ACT activity indicates an activation of the immune system and an increase in the body's resistance to infections, including intracellular ones.

The activity of alanine aminotransferase (ALT) in the experiment was significantly lower than in the control, 1.7 times. ALT is the main marker of the peripheral metabolic zone, reflecting the degree of integration of protein and carbohydrate metabolism. Since both the activity of lactate dehydrogenase (LDH) and the concentration of total protein were higher in the experiment, and the concentration of total protein is reliable, there is no reason to associate a decrease in ALT activity with a decrease in the intensity of protein or carbohydrate metabolism.

The correlation between the activity of LDH and ACT in the control was r = -0.53, and in the experiment r = + 0.85. Thus, in the control there is a medium-efficiency metabolism that obeys the Pasteur metabolic effect, and in the experiment there is an increase in the aerobic oxidation of glucose, substrate supported by an increase in glycolysis, i.e. intensification of catabolism. At the same time, the correlation between CC and ACT both in the control and in the experiment exceeded + 0.8, which indicated a highly efficient combination of the biosynthesis of ATP macroerg and creatine phosphate and their transfer from mitochondria to the cytoplasm in both groups.

The De Ritis coefficient in the experiment was significantly higher, which indicates the predominance of energy metabolism and activation of protective mechanisms. The fermentemia index was also significantly higher in the experiment, which indicates the predominance of aerobic oxidation of glucose and highly efficient energy metabolism.

Creatine kinase in the experiment shows a tendency to normalize activity.

The activity of GGT in the experiment was significantly higher, which indicates a higher intensity of nitrogen and, in particular, protein metabolism, confirmed by an increased concentration of total protein. GGT is one of the most important indicator enzymes. All body tissues use amino acids and pump them against a concentration gradient, which is realized through GGT. This is due to the need not only to use amino acids for protein synthesis, but also to stabilize its structure as opposed to the destructive effect of urea. GGT transports amino acids and peptides to cells, participates in the detoxification system, as well as in the metabolism of biogenic amines. Being a membrane-bound and energy-dependent enzyme, GGT is the last barrier to protecting tissues from foreign compounds. Carries out the destruction of denatured proteins and peptides. In the control, the correlation between GGT activity and urea concentration was r = + 0.08, and in the experiment r = + 0.77. Thus, a significant increase in GGT activity in the experiment increases the adaptive capabilities of the body due to the more pronounced stabilizing effect of GGT on the native structure of proteins.

The data for the control group showed a qualitatively identical, but quantitatively different interdependence of ACT and GGT, depending on the activity of the latter, which is generally characteristic of metabolic processes. This situation can be designated as ensuring the stability of one enzyme due to cyclic vibrations of another. It is significant that the stability of energy-dependent GGT is ensured by the polyvariance of the energy-producing ACT. The characteristic level of ACT corresponds to different levels of GGT activity. Stably low GGT activity (less than 0.25 microcatal) was combined with a regular increase in ACT activity (in this range of GGT activity, the Pearson correlation coefficient for ACT and GGT is r = + 1). With an increase in GGT level (0.25 microcatal or higher), a decrease in ACT activity was noted (in this range of GGT activity, the Pearson coefficient for ACT and GGT is -0.89). ALT, unlike ACT, has its own dynamics. However, in the zone of high GGT values, there was a decrease in the activity of not only ACT, but also ALT (in the range of high GGT activity, the Pearson correlation coefficient for ALT and GGT r = -0.98, and in general, the Pearson coefficient for ALT and GGT r = -0 , 85).

In the data on the experimental group as a whole, there was no correlation between ACT activity and GGT (r = -0.19). Neither in the zone of high nor in the zone of low values of GGT activity, a significant correlation was found between ACT and GGT, which confirms the separation of plastic and energy metabolism.

The increase in ACT activity and the De Ritis coefficient in the experiment are not accompanied by a decrease in the stability of proteins, as is the case when maintaining a strong antiphase interdependence of energy and plastic metabolism.

The concentration of total protein in the experiment was increased due to the globulin fraction, which confirms the activation of the body's defenses.

In the experiment, the urea concentration was significantly reduced and the ratio of total protein to urea was increased, which indicates an increase not only in energy, but also in plastic metabolism, i.e. about a more efficient metabolism in general.

Urea is both an indicator of both plastic (because it is synthesized) and energy (because it is synthesized from amino acid nitrogen) metabolism. The urea concentration in the experiment is lower (p <0.05) than in the control, 1.6 times. Moreover, in the experiment there was a high positive correlation (r = + 0.77) between the concentration of urea and the activity of GGT. This indicates the origin of urea from the amino groups formed during deamination of amino acids, i.e. in this case, urea is an indicator of a greater degree of plastic metabolism. The fact that the urea concentration in the experiment should be considered as an indicator of plastic metabolism is confirmed by the inverse correlation between the concentration of urea and total protein (r = -0.6). This becomes clear when one considers that both protein and urea have amino acids as their precursors.

In the experiment, the concentration of total cholesterol and lipoproteins of high (HDL) and low (LDL) density significantly increased. This indicates a higher intensity of lipid metabolism.

So, carbohydrate metabolism in the experiment compared with the control is more intense (a significant increase in LDH activity).

Protein metabolism is intensified, its dependence on carbohydrate metabolism is partially disrupted.

Lipid metabolism is increased, due to the involvement of endogenous lipids, against the background of a decrease in lipase toxicity.

The ratio of energy and plastic metabolism is changed in the direction of some dominance of the former.

In the experiment, compared with the control, the correlation of the enzyme index with key enzymes was changed (table 3).

Table 3 The dependence of the enzyme index on the activity of key enzymes ACT ADT QC LDH The control +0.79 +0.71 +0.89 -0.88 Experience +0.74 +0.28 +0.55 -0.10

As can be seen from table 3, in the control there is a high correlation of the enzyme index with the indices of the central and peripheral zones of metabolism, while completely different patterns are observed in the experiment, which are expressed in the greater autonomy of the various branches of metabolism from each other.

In the experiment, compared with the control, the correlation relationships of the indicators of protein and lipid metabolism were changed (table 4).

Table 4 The dependence of the concentration of total protein on lipid metabolism and the De Ritis coefficient Coeff. De ritis Cholesterol HDL LDL The control -0.67 +0.95 +0.53 +0.42 Experience -0.05 -0.45 +0.13 -0.55

As can be seen from table 4, in the control there is a high correlation of total protein with lipid metabolism and De Ritis coefficient. A negative correlation of the total protein and the De Ritis coefficient indicates an inverse interdependence of plastic and energy metabolism, which is absent in the experiment. In experimental animals, energy and plastic metabolism are more autonomous from each other than in control animals. In the control, a positive correlation of protein and lipid metabolism is observed, in the experiment it is negative.

There is no dependence of glucose concentration on cholesterol concentration in the control (r = + 0.18), and in the experiment it is +0.74.

The dependence of glucose concentration on urea concentration in the control is -0.67, and in the experiment +0.43.

Thus, in the experiment, compared with the control, the ratios of energy and plastic metabolism, protein and lipid metabolism, carbohydrate and lipid metabolism, carbohydrate and protein metabolism are changed. In experimental animals, various branches of metabolism are more autonomous from each other, due to which particular adverse effects in the control are easily transformed into systemic ones, and in the experiment they are stopped. This indicates an increase in the ability of animals to adapt.

Under biochemical adaptation understand the ability of organisms to change their metabolism in accordance with changes in environmental conditions. Biochemical adaptation proceeds at the molecular level.

Distinguish between urgent and long-term biochemical adaptation (P. Khochachka, Seven J. Biochemical adaptation. - M., Mir, 1988. - 568 p.), And long-term adaptation is the result of the development of urgent adaptation.

Important indicators of urgent adaptation are: increased aerobic and anaerobic oxidation of glucose, increased rate of tissue respiration, increased mobilization of lipids from fat depots. The results of biochemical tests indicate the presence of signs of urgent adaptation in experimental animals. Thus, the activity of LDH, which reflects the anaerobic oxidation of glucose, and the value of the enzyme index, which reflects the aerobic oxidation of pyruvate, were significantly higher in the experiment than in the control. ACT activity, reflecting the intensity of tissue respiration, in the experiment showed a tendency to increase. The concentration of total cholesterol, reflecting the rate of mobilization of lipids from fat depots, was significantly higher in the experiment than in the control. All this confirms the presence of signs of urgent adaptation in experimental animals.

Long-term adaptation is designed to prepare the body for possible stress. The biological purpose of long-term adaptation is to create a structural and functional base in the body for the best implementation of urgent adaptation mechanisms.

One of the most significant areas of long-term adaptation are the following.

Increasing the speed of recovery processes. Of particular importance for the development of long-term adaptation is the acceleration of protein synthesis. This leads to an increase in the content of contractile proteins, protein-enzymes, oxygen-transporting proteins. Due to the increase in the content of enzymes, the metabolism of other biologically active compounds, in particular creatine phosphate, glycogen, lipids, is accelerated. As a result of such exposure, the energy potential of the body increases significantly.

The development of resistance to biochemical shifts that occur in the body during exercise. First of all, this refers to the body's resistance to acidity caused by the accumulation of lactate. It is assumed that insensitivity to acidity growth is due to the formation of molecular forms of proteins that retain their biological functions at low pH values.

The main biochemical tests indicating the presence of long-term adaptation include the concentration of total protein, lipoproteins and total cholesterol. These indicators in the experiment were significantly higher than in the control, which suggests the presence in the experimental animals of signs of long-term adaptation.

Thus, changes in biochemical parameters characteristic of both urgent and long-term adaptation are found in experimental animals.

Based on the foregoing, we can conclude that the claimed method is effective, harmless, does not have side effects, allows us to solve the problem of adaptation of cattle regardless of changes in their conditions of feeding and feeding due to the regulation of bonds of simultaneously protein, carbohydrate and lipid metabolic processes, as well as changes in the ratio of energy and plastic metabolism.

Claims (1)

The method of adaptation of cattle to new conditions of maintenance, which consists in the introduction of a preparation based on an organic compound, characterized in that as a preparation based on an organic compound, a composition is used in the form of a mixture of a medical solution of formaldehyde with a solution of sodium chloride 0.85-0.95% concentration at a ratio of parts by weight of 2-6: 994-998, while the composition is administered twice intramuscularly at a dose of 5.0-6.0 ml per head with an interval between injections of 7-10 days.