RU2675975C1 - Antistress temperature-regulating feed additive - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to the field of agriculture, namely to the antistress temperature-regulating feed additive. Feed additive is a feedstuff that contributes to providing the available energy of animals, enhancing the enzymatic processes in the rumen and optimizing the indices of non-specific resistance of the organism in conditions of high ambient temperatures. Feed additive contains the following initial components: coniferous energy extract, propylene glycol, crushed active charcoal, linseed oil and sugar. All the ingredients are taken at specified ratio.EFFECT: use of the invention will improve the overall condition of the cows, as well as the qualitative and quantitative parameters of productivity.1 cl, 9 tbl

Description

The invention relates to the field of agriculture and can be used as an energy feed additive in cattle breeding, which has a positive effect on the physiological and biochemical status of the animal organism. The invention is intended to provide affordable animal energy and at the same time improve feed conversion under adverse environmental temperature conditions, which counteracts the negative energy balance during heat stress, contributing to an increase in milk productivity and milk fat in the summer.

High milk yields are usually observed after January and February calving, while low milk yields are most often observed during calving in August and September. Seasonal fluctuations in milk production are caused by the influence of direct and indirect environmental factors. The direct effect is associated with the influence of high temperatures on milk yield, the indirect effect is associated with the negative effects of heat stress, under the influence of which changes in the metabolism in the body of both mother and fetus occur during the period before calving. An important aspect in the summer period is also an increased number of somatic cells up to the level of mastitis, a decrease in the indicators of fat and protein in milk, that is, a decrease in the quality indicators of milk. In addition, the stronger the cows try to cool, the more their maintenance requirements increase.

The mechanism through which heat stress affects the productivity of dairy cows and their ability to reproduce is only partially explained by a decrease in feed intake. These include changes in endocrine status, worsening of the rumination and absorption of nutrients, as well as an increase in energy expenditure for maintaining homeostasis of the body. These factors lead to an imbalance between energy consumption and its use and explain why cows significantly lose weight during heat stress.

Given that heat stress leads to reduced feed intake and the formation of heat, usually associated with the digestion of coarse feed in the rumen, it is recommended to increase the energy saturation of the diet, increasing the concentration of concentrated feed and reducing the proportion of feed. Such a strategy can lead to a decrease in the pH level in the rumen, which in turn increases the risk of subclinical acidosis. This leads to a less favorable environment of the scar and a decrease in its function, a decrease in the digestibility of the protein, and a decrease in the number of symbiotic bacteria.

Under thermal stresses, in connection with a decrease in the consumption of dry feed mass and an increase in energy deficiency, a problem such as ketosis, characterized by a violation of carbohydrate, protein and fat metabolism and accompanied by the accumulation of a large amount of ketone substances in the body, is relevant. An important factor in the occurrence of ketosis is the lack of easily digestible carbohydrates. With a carbohydrate deficiency, liver glycogen stores are consumed, resulting in hypoglycemia. In summer, the main cause of ketosis is obesity, low energy density or its insufficient consumption (for example, due to hypocalcemia).

Heat stress can reduce feed intake by more than 30%, and even on well-managed farms with artificial cooling, it reduces feed intake by 10-15%.

In addition to external cooling of the animals, in order to reduce the negative impact of heat stress during the hot period, it is extremely important to use correctly selected and balanced food. For example, feed additives containing easily digestible glycogen components that contribute to a decrease in the rate of thermal fermentation, due to the greater efficiency of feed use. At the same time, it is possible to maintain food intake corresponding to the physiology of the body, which is especially important in the summer.

Currently, technical solutions have been developed that contribute to the solution of one or several separate tasks for optimizing cicatricial digestion, maintaining a balance between the influx of heat from the environment and heat generation to stabilize the body's homeostasis, and improve the natural resistance indices when creating feed additives for feeding cows during the transit period.

Known therapeutic agent for farm animals "Rumisol" containing sodium salts, potassium salts, potassium chloride and excipient. As sodium and potassium salts, the product contains sodium chloride, potassium chloride, as well as sodium and potassium salts of one or more organic acids selected from the group of ascorbic, formic, acetic, valerianic, caprylic, enanthic, malic, tartaric, lactic, oxalic, succinic , propionic, citric, malonic, glutaric acid, and as an excipient - glucose and / or propylene glycol. The use of a therapeutic and prophylactic agent ensures the restoration of water-electrolyte balance, energy metabolism and regulation of the pH of the digestive tract during dyspepsia of animals, ketosis and rumen acidosis in cows, sheep and goats, diarrhea of various etiologies, feed intoxications, mycotoxicosis, dehydration, heat stress, disturbances in water -salt balance, provides stimulation of digestion, increase in overall tone and increase milk productivity [Melikhov SV, Melikhova MS, Pozdnyakova TN Therapeutic and prophylactic agent for farm animals "Rumisol" // RF Patent No. 2547423, IPC A23K 1/175, A61K 33/00, 03/27/2014 (1)].

The disadvantage of the analogue is that during the first hour after consumption, the salts of organic acids dissolve, and the highest level of volatile acids in the rumen after eating food occurs after 4-6 hours or more. By this time, the added salts of organic acids are disposed of in the rumen. Therefore, the effectiveness of the use of small doses of such compounds is minimal, and high doses significantly inhibit feed intake due to the deterioration of its taste and negatively affect the growth of microflora and the condition of the scar mucosa.

Known feed additive for highly dairy cows for dividing, containing crushed corn grains - 35%, soybean meal (with a mass fraction of protein 46% and above) - 40% and dry vegetable fat - 25% with a daily rate of 1.0-1.5 kg / goal. / day. As a dry vegetable fat, “protected” fat in the dry “BergaLac” form was used. It is stated that the proposed feed additive is aimed at increasing the energy supply of highly dairy cows during milking, has a high productive effect and high quality [Kiseleva N.V., Tolmatsky O.V. Feed additive for highly dairy cows on a bed // RF Patent No. 2496327, IPC A23K 1/00, A23K 1/18, 10.27.2013 (2)].

The disadvantages of this technical solution is that the additive is a high-energy mixture, more applicable for the concentrated type of feeding cattle for fattening (for example, corn grain, as one of the components, has a high content of carbohydrates, mainly starch - up to 560 g per kg product, and the average amount for cereal protein - up to 92 g per kg [Norms and diets for feeding farm animals. Reference manual. 3rd edition revised and supplemented. / Ed. by A. P. Kalashni Kova, V.I. Fisinina, V.V. Shcheglova, N.I. Kleimenova. - Moscow. 2003. - 456 p. (3)]), but not suitable for giving dairy cows, besides after calving. High energy saturation of the additive can cause an increase in lactic acid fermentation, acidification of the cicatricial chyme. This contributes to a change in the ratio of acetate, propionate, leads to the development of acidotic phenomena in the body and a decrease in the fat content in milk.

In addition, the use of “protected” BergaLac t-310 fat as an additive component representing a complex of fractional palm oil containing up to 75% palmitic acid promotes excessive accumulation of palmitic acid (the content of palmitic acid in the liver increases in the post-heating period) in the liver, exerting a large load on it, which leads to its obesity. The concentration of fatty acids in the blood is the highest after calving. Adding fats to the diet further increases their content. If the animal has a tendency to ketosis, fats in the form of glycerides are susceptible to beta oxidation in the liver, which results in the accumulation of ketone bodies in the blood. As a result, the addition of fats to the diet of cows during the first weeks of lactation contributes to an imbalance in nutrition, a decrease in appetite and overall energy consumption. When more fat comes from the feed at the beginning of lactation, the cow consumes less dry matter.

The adverse effect of palm oil-based fats on the animal's reproductive system, which consists in the accumulation of palmitic acid in the fluid of the follicle cells, has been studied, which complicates the development of the egg and its division, the quality of the cell wall of the follicles and their size deteriorate, which limits the effect of fodder fats on the composition of oocytes [Santos J.E., Bilby T.R., Thatcher WW, Staples C.R., Silvestre FT Long chain fatty acids of diet as factors influencing reproduction in cattle // Long chain fatty acids of diet as factors influencing reproduction in cattle // Reprod Dom Anim. - 2008. - No. 43 (Supp. 2). - p. 23-30 (4)].

Also, the invention does not declare the effect of this additive on animals under conditions of elevated ambient temperatures.

The closest technical solution is a method of treating subclinical ketosis in cows. A method of treating subclinical ketosis in cows involves administering 500 ml of propylene glycol per head with food 2 times a day (250 ml in the morning and 250 ml in the evening) for 7 days. Additionally, Khotynets zeolites are included in a dose of 3% of the dry weight of feed per head and 15 g of lecithin per 100 kg of live weight of the cow for 7 days once in the morning by mixing with the diet. As stated, the use of the invention will improve the effectiveness of treatment, increase milk yield and improve the quality of milk [Yarovan N.I., Novikova I.A. A method for the treatment of subclinical ketosis in cows // RF Patent No. 2492700, IPC A23K 1/175, 09/20/2013 (5)].

The disadvantage of this method of increasing the productivity of cows is the increased dosage of propylene glycol to 500 ml per head per day. At dosages above 250-300 ml per head per day, the use of propylene glycol has a side effect, since it partially oxidizes in the rumen of a cow to - D-lactate (lactic acid). Unlike DL-lactate, normally present in the rumen, it is poorly utilized by the scar microflora and suppresses it, lowering the pH and accumulating in the body. At the same time, an overdose of propylene glycol is quite real with excessive introduction into the diet and insufficient mixing with food.

The application states that the positive effect of the Khotynets zeolites with subclinical ketosis is explained by the fact that these zeolites have a sorption ability with respect to free radicals and are sources of mineral elements, including metals with variable valency, which leads to an increase in the activity of antioxidant enzymes. But the disadvantage of zeolites is a narrow spectrum of adsorption efficiency; in addition, along with mycotoxins, they also bind nutrients (vitamins), since they have a large pore size. Zeolites are crystalline aqueous aluminosilicate minerals having a higher affinity for water than mycotoxins; they bind up to 200% of their initial mass of water. In addition, when entering these sorbents, there is a risk of blocking the elements of the digestive system by precipitated clay particles.

Also in this invention describes the use of hydrolyzed lecithin - "Centrolex F", which is a soya lecithin in the form of highly concentrated phospholipids. The presence of such a component as soya lecithin is apparently due to the fact that the main exporter of lecithin is the United States, where soya is the predominant oilseed crop. However, most of the soy used is genetically modified. Studies show the negative effects of food supplemented with genetically modified soybeans for the health of laboratory mammals. With an increase in the proportion of genetically modified soy in the diet of animals, changes are found in the protein-lipid composition of the blood. Reduced resistance of red blood cells to hemolysis and their viability, that is, the effect of soybean on some indicators of metabolic processes [Alba N.A., Kuzmicheva L.V., Zinovieva E.V., Bochkareva A.K., Lopatnikova E.A. The effect of GM soy on the protein-lipid composition of animal blood // International Journal of Applied and Basic Research. - 2012. - No. 2. - from. 67-67 (6)]. In addition, it is known that food allergy to soy proteins is a common occurrence. The established increase in hypersensitivity to soy proteins requires further deeper study of the allergenic composition of soy products.

The invention does not declare the effect of this additive on animals under conditions of high temperatures and, therefore, stopping the consequence of heat stress.

SUMMARY OF THE INVENTION

The problem to which this invention is directed is to use an anti-stress thermoregulatory feed additive in cattle breeding in order to prevent a deficiency of the animal’s energy balance during the transit period and to eliminate the effects of temperature stress.

This problem is solved in that the anti-stress thermoregulatory feed additive, consisting of a component containing biologically active substances of coniferous woody greenery - coniferous energy extract and a balanced energy complex that includes propylene glycol and sugar, affects the efficiency of milk synthesis and the prevention of metabolic disturbances at high temperatures, due to the action of the components, both at the level of the scar and at the level of metabolism. When using the additive, the function of the scar is stabilized, the number of symbiotic microorganisms increases and the production of enzymes increases. The process occurs due to a correctly selected period of splitting of its constituent components. The composition of the additive includes activated charcoal. The inclusion of active charcoal promotes the adsorption of xenobiotics in the diet of a diet prone to spoilage, especially in the summer. The introduction of activated carbon is also due to the fact that endotoxins can be produced in the rumen of an animal under heat stress, due to the launch of the compensatory mechanism of thermoregulation. In the summer, in order to dissipate the internal heat of the body, the blood flow to the gastrointestinal tract decreases, the level of absorption of nutrients decreases, the final fermentation products (volatile fatty acids) accumulate in the rumen, which contributes to a decrease in pH. In the rumen there is a change in the composition of the populations of microorganisms. The concentration of decomposition products (lysis) of microorganisms - lipopolysaccharides, which are toxic substances - endotoxins, increases in the scar fluid.

The anti-stress thermoregulatory feed additive is a feed product that helps provide accessible energy to animals, enhances the enzymatic processes in the rumen and optimizes indicators of nonspecific resistance of the body in conditions of high ambient temperatures, with the following ratio of components, wt. %:

Coniferous energy extract - 78%

Propylene glycol - 10%

Shredded active charcoal - 5%

Flaxseed oil - 2%

Sugar - 5%.

The components of the studied additives are selected according to the duration of fermentation, due to which a prolonged energy effect is achieved. When one energy component finishes splitting, the other is at the peak of splitting. The prolonged energy effect helps to stabilize the pH of the rumen, which does not lead to the active development of bacteria - producers of lactic acid, capable of normal development at low pH values. Consequently, there is no shift in the direction of bacterial fermentation towards the production of lactic acid, the causes of asedotic phenomena in the rumen.

First, sugars break down, which are, as it were, a trigger for the breakdown of other components. The breakdown of sugars gives propionic acid, an important energy source for scar epithelium, which improves the development of villi and the absorption of nutrients in the feed ration.

After sugars, propylene glycol is fermented. It is almost completely digested in the rumen. Fermentation takes place in just a few hours in propionic acid. Propionic acid through the walls of the rumen enters the liver, where it is processed into glucose.

Glycerin, which is part of the coniferous energy extract, is broken down last. It is partially fermented in rumen into butyric and propionic acid. Butyric acid has a positive effect on the epithelium of the scar. It is partially adsorbed as such, enters the liver, there it is converted to glucose.

Coniferous energy extract, a natural vitamin carrier, is an extract of pine needles, extracted with glycerin at a temperature of 60 ° C with a liquid module of 1: 5. The needles contain carotene, chlorophyll, xanthophyll and other substances that play a role in metabolism and in the synthesis of a number of new vitamins in the body; moreover, carotene, which is provitamin A, is contained in the needles twice as much as in carrots. In winter and autumn, the deficiency of vitamins can be made up by adding pine and spruce needles to the diet, rich in vitamins A, C, B2, K, E, P. The group of compounds included in the extractive part of the coniferous energy extract - stilbenes are powerful fungicides against parasitic fungi and many viruses. Together with other classes of aromatic compounds - flavonoids and lignans, they provide reliable protection against pathogens of the digestive tract of ruminants. In addition to compounds that directly affect pathogens, pine needles, which are the raw material for obtaining coniferous energy extract, contain compounds with an immune-modulating effect. Such compounds include triterpene acids, jasmonic acid derivatives, terpenoids and polyprenols. Polyprenols are physiologically active substances whose phosphates perform coenzyme functions in living organisms in the biosynthesis of glycoproteins and glycoproteins. Glycoproteins and glycoproteins act as receptors for plasma and intracellular membranes, are part of immunoglobulins B and T lymphocytes, and determine the blood group in red blood cells. The content of polyprenols in the raw materials used for the production of the drug is about 1%.

The additive also includes crushed active charcoal, with iodine adsorption capacity of 30% [GOST 6217-74. Crushed active charcoal. Technical conditions M. 2003.8 s. (7)] containing macro-, meso- and micropores. Depending on the size of the molecules that need to be kept on the surface, activated charcoal absorbs a wide range of molecular impurities, due to a certain ratio of pore sizes, therefore, as an additive component, activated carbon already has properties that do not require modification of the structure and cost of the product to detoxify inadequate feed quality fed with the supplement.

In the long run, heat stress leads to a weakening of immunity or a decrease in reproduction rates. Under the influence of high temperatures, the body increases the content of chemically active molecules of various nature with a large oxidizing potential - peroxides, superoxides, atomic oxygen, hydroxyl radicals. Under the influence of stress factors, including heat stress, the concentration of reactive oxygen species increases sharply, which leads to the destruction of cellular structures. At a time when stressful situations arise, it is extremely important to provide the body with an additional amount of antioxidants to maintain the effective functioning of the antioxidant system. The use of coniferous energy extract and linseed oil as part of an anti-stress thermoregulatory feed additive significantly increases the antioxidant status of animals, which is characterized by improved cow health and improved quality of dairy products.

Flaxseed oil is a source of polyunsaturated fatty acids necessary for animal life, and especially during pregnancy. Flaxseed oil, which is part of the supplement, contains a complex of vitamins: E, A, B, D, K, as well as monounsaturated fats. Adding antioxidants in the form of a-tocopherol (vitamin E) to animal feed has a beneficial effect on the condition of animals, stabilizes lipids, and reduces the formation of cholesterol oxidation products. The content of calcium, iron, copper, as well as vitamins A, D and E, neutralizes the effects of free radicals. Dairy cows, thanks to flax oil, give milk with an improved fat profile.

Obtaining an anti-stress thermoregulatory feed additive consists of mixing coniferous energy extract, propylene glycol to a uniform consistency when heated to a temperature of 60 ° C, then serving portionwise, linseed oil and activated charcoal with constant stirring, after which the components are mixed again for 10- 20 minutes to a homogeneous mass, then cool and pack.

The study of the beneficial properties of the anti-stress thermoregulatory feed additive was carried out under the conditions of a scientific-production experiment on cows of the dairy herd of the farm of AST-Group LLC in the Stavropol district of the Samara region from July 1 to September 23. This summer-autumn period is characterized by the most unfavorable temperature background for the physiological functioning of polyastric animals.

Example. In 2017, from July 1 to September 23, a scientific and production experiment was conducted in the conditions of the economy of OOO AST-Group in the Stavropol District of the Samara Region. The objective of the work was to obtain scientific data on the use of anti-stress thermoregulatory feed additives in feeding dairy cows in order to reduce the energy deficit of the body during the transit period and the effects of temperature stresses.

The object of the study was cows of black and motley breed 3 lactation. In the studies, 2 groups of animals (control and experimental) were formed with 10 animals each, according to the scheme presented in table 1. The groups were formed according to the principle of analogues taking into account live weight, physiological state of productivity and lactation.

Animals of the control and experimental groups were in the same conditions. Their feeding was carried out according to the daily routine adopted at the farm.

In the experiment, the cows of the control group received the main diet; experimental group - the main diet along with an anti-stress thermoregulatory feed additive component composition: coniferous energy extract, propylene glycol, activated charcoal, linseed oil, sugar in an amount of 150 g / head / day.

At the end of the experiment, whole and stabilized blood samples were taken from animals (n = 5) from each experimental group with the determination of indicators characterizing the metabolic state (total protein, albumin, globulins, creatinine, urea, total bilirubin, total cholesterol, calcium, phosphorus, alkaline phosphotase, glucose, ACT, ALT, ketone bodies), in the department of physiology and biochemistry of agricultural animals, FSBI Federal Research Center VIZh them. L.K. Ernst. At the end of the experiment, the level of nonspecific blood immunity of experimental animals (n = 5) was determined in the laboratory of microbiology of the bactericidal activity of blood serum (BASK).

Milk yield (gross, daily average) is calculated on the basis of control milkings from all experimental animals (n = 10).

To determine the milk quality of experimental animals (n = 10), average milk samples were taken and the following were determined in the Testing Research Laboratory of the Federal State Budget Educational Institution of Higher Education Samara State Agricultural Academy: fat mass fraction, protein mass fraction, somatic cell content.

To characterize cicatricial digestion in animals (n = 5) in the middle of the experiment, samples of the contents of the rumen were taken using an esophageal probe 3 hours after feeding with determination of cicatricial fermentation parameters.

The diets of animals were made in accordance with their live weight and productivity. Table 2 presents the average diet of cows for the period of the experiment. The main diet of animals consisted of hay, green mass, grain mix (barley, oats, sunflower meal). 150 g of an anti-stress thermoregulatory feed additive was added to the diets of the experimental group of cows, as a result of which its energy value was higher than in the control group by 2.2 MJ.

In order to study the effect of the anti-stress thermoregulatory feed additive fed in diets on milk productivity, we recorded milk productivity for each group of cows.

As can be seen from the data in table 3, feeding the anti-stress thermoregulatory feed additives in the diet described above, provided an increase in milk productivity.

The differences compared with the control are statistically significant at * - P <0.05.

On the 30th day of the experiment, the average daily milk yield of natural fat in the control group decreased by 2.2 liters, in the experimental group - by 1 liter compared to the initial milk yield. The average daily temperature was 33 ° C with a relative humidity of 63%. On the 45th day of the experiment, the milk yield decreased in cows of the control group by 1.2 liters, in the experimental group - by 0.9 liters. On the 60th day of the experiment, this decrease was 0.9 L and 0.3 L, respectively.

Analyzing the data, a tendency was observed to slow down the decline of the lactation curve, despite the rather high temperature indices of the environment (average temperatures in the experimental area were 27-31 ° С in the 1st half of the experiment, 23-27 ° С in the 2nd) . This tendency was expressed in the fact that the average daily milk yield per experiment at natural fat content and after transferring to 3.4%, the fat content in the cows of the experimental group was 16.26 ± 0.4 kg and 18.32 kg and was higher by 10 respectively , 9% and 11.2% in comparison with animals of the control group, where the values were - 14.66 ± 0.2 kg and 16.47 kg, respectively; the gross milk yield of 3.4% milk of the control group amounted to 1400.0 kg, experimental - 1557.0 kg, which is 11.2% higher than the control group. The increase in the productivity of experimental animals is explained by the optimization of cicatricial digestion and a decrease in thermal fermentation due to the use of easily digestible carbohydrates, needles oligosaccharides and fatty acids. This is facilitated by a well-balanced balance of components: once a cow enters the body, part of easily digestible carbohydrates and oligosaccharides is spent on the growth of the microbial mass of the rumen, the other part is absorbed through the walls of the rumen, and coniferous fatty acids enter the bloodstream through the small intestine. The energy of the components is effectively used by the animal’s body and does not load the liver.

The fat and protein content in the milk of cows was higher among the cows of the experimental group, which accordingly affected the improvement of the quality indicators of milk. There was a decrease in the number of somatic cells in the milk of cows fed with an anti-stress thermoregulatory feed additive, which may determine the bacteriostatic effect of the coniferous energy extract included in the supplement.

The cost of nutrients for the production of 1 kg of milk of 3.4% fat content in the groups of cows treated with the studied supplement was less. So, in cows of the experimental group, the consumption of concentrated energy feed was 10.1% lower than in control animals, due to which there was no decrease in the pH level in the rumen, to 4-5 or lower (the norm in cows is 6.5-7.2 ), accompanied by various violations of the functions of the pancreas and a deterioration in general health, which in turn minimized the risk of subclinical acidosis as an alimentary disturbance of the digestive process in the pancreas.

The efficiency of the use of energy and nutrients of feed in ruminants is directly dependent on the nature of metabolic processes in the rumen, microbial processes in the pancreas. To study the effect of the test additive on the rumen fermentation processes, at the end of the experiment, we used a rumen content to determine the pH, the total content of volatile fatty acids (VFA), the molar ratio of individual fermentation acids, the concentration of ammonium nitrogen, and the total amount microorganisms and their individual species in the rumen.

Analyzing the data of Table 4, it should be noted a slight increase in the total acidity of the cicatricial content within the physiological norm in experimental cows, which is associated with the intensification of fermentation processes and the formation of acidic metabolites in the rumen in the form of volatile fatty acids when feeding an anti-stress thermoregulatory feed additive. The total amount of volatile fatty acids, the final products of the breakdown of carbohydrates in the pancreas, was 44% higher in experimental cows compared to the control group. This fact indicates a more intensive course of carbohydrate hydrolysis in experimental animals. Considering the molar ratio of individual short-chain acids, an increase in the proportion of acetic acid in experimental cows and a slight decrease in the proportion of propionic and butyric acids should be noted, which is a positive factor. The concentration of ammonia nitrogen in the experimental animals was slightly higher compared with the control (13.9%), which may indicate a higher proteolytic activity of cicatricial microflora.

The differences compared with the control are statistically significant at * - P <0.05.

The introduction of 150 g of anti-stress thermoregulatory feed additives into animal diets had a beneficial effect on the rumen microflora (Table 5). In the experimental period of studies, there was a tendency to increase the total number of mesophilic aerobic and facultative anaerobic microorganisms (KMAFAnM) in the rumen of cows of the experimental group. The same trend was observed with respect to lactose-positive and lactose-negative microorganisms.

Reflection of metabolism is the internal environment of the body. Blood carries out stabilization (homeostasis) of the internal environment, which is necessary for the vital functions of cells and tissues, ensures the functional unity of the body.

It is known that blood, being the internal environment of the body and connecting all systems and organs into a single whole, serves as an indicator of the processes occurring inside it. In this regard, biochemical parameters were determined, as well as factors of natural resistance of animals in comparison with the control.

* - The standard values of biochemical parameters are taken from the reference manual “Recommendations for detailed feeding of dairy cattle” (VIZH named after L.K. Ernst, 2016).

In studies, there was a tendency to an increase in the blood of experimental animals in comparison with control concentrations of total protein (2.7%), albumin (3.5%) with a decrease in urea level (10.1%). The latter fact may indicate an increased involvement of urea, a product of protein metabolism, in assimilation processes.

Creatinine is a protein metabolism product in the synthesis of which the amino acids methionine, glycine and arginine participate. The creatinine concentration in the blood of the cows of the experimental group was lower than in the control by 15.7%, which can also indicate a more intensive course of protein synthesis.

Glucose is a source of energy in all vital processes occurring in the body. In studies in the blood of cows receiving an anti-stress thermoregulatory feed supplement in the diet, glucose levels were 15.7% higher.

The level of cholesterol in cows receiving an anti-stress thermoregulatory feed additive in the diet was significantly lower compared to control (26.0%), which also indicates the highest intensity of metabolic processes in experimental animals.

Excessive tension of the endocrine regulation of metabolism due to the increased ratio of ketoplastic compounds to glucoplastic compounds in the future leads to disruption of energy metabolism and to the development of ketoses.

The content of ketone bodies in the blood is shown in table 7.

The blood ketone content on the 85th day of the experiment in the cows of the experimental group was 4.2 mg%, while in the cows of the control group their concentration was 7.2 mg%, that is, in the cows of the control group there was a tendency to some increase ketone bodies, exceeding the norm, which may be a sign of the development of subclinical ketosis.

There were no significant differences in the content of individual macronutrients in the blood of experimental animals (table 8).

* - The standard values of biochemical parameters are taken from the reference manual “Recommendations for detailed feeding of dairy cattle” (VIZH named after L.K. Ernst, 2016).

Analyzing the data presented in table 9, we see that the cows of the experimental group showed an increase in the percentage of lysis relative to the control by 8.8%. It should be noted the increase in the value of bactericidal activity in cows receiving a stress-reducing thermoregulatory feed additive with a diet by 2.2%.

Based on the data of biochemical blood tests, it follows that the inclusion of anti-stress thermoregulatory feed additives in the diets of lactating cows positively affects the course of nitrogen and carbohydrate-fat metabolism in the body and indicators of natural resistance, which is already evident at the level of cicatricial digestion.

Based on the results of studying the use of anti-stress thermoregulatory feed additives in feeding dairy cows, it seems possible to draw the following conclusions:

- feeding the studied anti-stress thermoregulatory feed additive to cows led to an increase in average daily milk yields of milk of natural fat content by 10.9%, while reducing the cost of feed per unit of output;

- the use of the studied additives in the amount of 150 g / head per day to dairy cows contributed to the strengthening of enzymatic processes in the rumen, which was expressed in an increase in the formation of VFAs by 8.7% with an increase in the proportion of acetate and a decrease in the proportion of propionate. In the rumen of experimental cows, there was a tendency to increase the total number of mesophilic aerobic and facultative anaerobic microorganisms (KMAFAnM);

- the inclusion in the diets of the studied anti-stress thermoregulatory feed additive had a positive effect on the carbohydrate-fat and protein metabolism of lactating cows, which was manifested in an increase in the concentration of total protein by 2.7%, albumin by 3.5%, glucose by 15.7% with a decrease in the content urea by 10.1%, creatinine by 15.7%, cholesterol by 26.0%;

- the use of anti-stress thermoregulatory feed additives in the diets of lactating cows in an amount of 150 g / head per day contributed to an increase in the bactericidal activity of blood serum by 2.2% and the percentage of lysis by 8.8% compared to control animals.

The technical and economic advantages of the proposed anti-stress thermostatic feed additive for cows are to effectively prevent disturbances in energy metabolism in the body of polyastric animals, optimize enzymatic processes in the rumen, which positively affects the course of carbohydrate-lipid metabolism and non-specific resistance indices at high temperatures. When using an anti-stress thermoregulatory feed additive, cows improve their general condition, as well as qualitative and quantitative parameters of productivity.

Information sources

1. Melikhov S.V., Melikhova M.S., Pozdnyakova T. N. Treatment and prophylaxis for farm animals "Rumisol" // RF patent No. 2547423, IPC A23K 1/175, A61K 33/00, 03/27/2014 g.

2. Kiseleva N.V., Tolmatsky O.V. Feed additive for highly dairy cows for breeding // RF patent No. 2496327, IPC A23K 1/00, A23K 1/18, 10.27.2013

3. Norms and rations for feeding farm animals. Reference manual. 3rd edition revised and expanded. / Ed. A.P. Kalashnikova, V.I. Fisinina, V.V. Shcheglova, N.I. Kleimenova. - Moscow. 2003 .-- 456 p.

4. Santos J.E., Bilby T.R., Thatcher W.W., Staples C.R., Silvestre F.T. Long chain fatty acids of diet as factors influencing reproduction in cattle // Long chain fatty acids of diet as factors influencing reproduction in cattle // Reprod Dom Anim. - 2008. - No. 43 (Supp. 2). - p. 23-30

5. Yavrovan H.I., Novikova I.A. A method for the treatment of subclinical ketosis in cows // RF patent No. 2492700, IPC A23K 1/175, 09/20/2013

6. Alba N.A., Kuzmicheva L.V., Zinovieva E.V., Bochkareva A.K., Lopatnikova E.A. The effect of GM soy on the protein-lipid composition of animal blood // International Journal of Applied and Basic Research. - 2012. - No. 2. - from. 67-67

7. GOST 6217-74. Crushed active charcoal. Technical conditions M. 2003.8 s.

Claims (2)

An anti-stress thermoregulatory feed additive, characterized in that it is a feed product that helps provide accessible energy to animals, enhances the enzymatic processes in the rumen and optimizes the indicators of nonspecific resistance of the body in high ambient temperatures, with the following ratio of starting components, wt.%: Coniferous Energy Extract 78 Propylene glycol 10 Shredded active charcoal 5 Linseed oil 2 Sugar 5