MD1530Z - Method for preventing immunodeficiency dyspepsia in calves - Google Patents

Abstract

The invention relates to the field of veterinary medicine and can be used for preventing immunodeficiency dyspepsia in newborn calves.The method for preventing immunodeficiency dyspepsia in calves comprises feeding newborn calves with a mixture containing, per 1 L: skimmed milk powder - 100 g, apitherapeutic product - 1.0…2.0 g, water at a temperature of 38-40°C - the rest, in a dose of 1000,0 mL/head once a day, for 30 days, at the same time the apitherapeutic product contains, in a ratio of 3:1, powder of dead bees and a mixture of drone larvae homogenized with lactose and glucose.The result of the invention consists in reducing the incidence of calves due to immunodeficiency dyspepsia.

Description

The invention relates to veterinary medicine and can be used for the prophylaxis of immunodeficiency dyspepsia in newborn calves.

Diseases of newborn animals, which occur against the background of an immunodeficiency state, are widespread among farm animals. Against the background of an immunodeficiency state, pathogenic and conditionally pathogenic microorganisms are activated, which leads to an increase in the morbidity and mortality of animals. The study of the species composition of the pathogenic microflora selected from healthy, sick or dead animals indicates a poly-microbial composition in a wide associated variety.

Thus, the cause of gastrointestinal diseases in young animals is often mixed microflora (mixed infection) against the background of an immunodeficiency state, which complicates the course of these diseases and the choice of an effective drug.

Therefore, the widespread occurrence of diseases of microbial etiology that cause a decrease in productivity and reproductive quality of animals, forced slaughter and their death, requires major costs for treatment and prophylaxis, and negatively affects both the epizootic and economic situation of animal husbandry.

For animal husbandry at the current stage, a stringent condition for effective management is increased productivity, the inherent characteristics of which are not only an increase in production, but also an increase in the overall resistance of the organism with high feed conversion and ecological safety of obtaining food products.

In this case, it is very important to fully provide the animals with vitamins and the nutritional value of the ration. However, to achieve an optimal balanced ration, ensuring the completion of energy consumption, amino acids, vitamins, macro- and microelements without the additional introduction of biologically active additives is almost impossible.

Therefore, additional sources are constantly being sought that increase the body's potential reserves, optimizing the acceleration of recovery processes. In this area, general strengthening remedies based on bee products have become widespread, which delay the onset of fatigue signals due to the expansion of the body's biochemical and functional reserves.

The most appropriate method that increases the effectiveness of prevention and treatment of animals is the rational use of components of combinations of various biologically active substances, which positively affect the immune system and have a wide range of immunostimulating effects. Some of these are bee products. Means based on bee products have high biological activity, are a source of di- and monosaccharides, vitamins, micro- and macroelements.

A method of increasing the body's resistance is known, using a remedy for apitherapy and apiprophylaxis Apimikroelfit-1, which contains extracts of medicinal plants: propolis bioflavonoids, dry mummy extract, deer antler extract, royal jelly and bee honey [1]. This method is due to the high biological activity of Apimikroelfit-1, which has therapeutic and prophylactic immunostimulating properties of general strengthening and increases the body's resistance. However, the specified remedy is very complex in composition, contains mineral-organic, biological, vegetable and animal ingredients, and for widespread use for animals it is very expensive and costly.

There is a known method of increasing the body's resistance with the help of an apitherapeutic remedy, which has a general strengthening and adaptogenic effect, which includes dry eleutherococcus extract, dry licorice root extract, dry rosehip extract, estifan, silymarin, propolis tincture, and natural honey [2].

The disadvantage of this method is that the composition of the apitherapeutic remedy includes adaptogens of plant origin, which are classified as stimulants of a doping nature. In addition, with their prolonged use, accumulation and habituation of the body to them is possible. In large doses, they can have a stimulating effect with energy consumption.

The method of strengthening the body with the help of a general prophylactic and fortifying remedy, with a broad spectrum of action, which contains honey, ascorbic acid, algae powder, spirulina, calcium stearate or stannic acid in the following ratio, wt. %: honey 22.0…28.0; ascorbic acid 8.0…12.0; calcium stearate or stannic acid 0.8…1.2; spirulina algae powder - the rest is known [3].

The disadvantage of this method is that the proposed remedy does not contain easily digestible proteins. In addition, this remedy has a fairly high content of honey, while other components introduced into the recipe cannot provide a sufficiently high level of biological value.

It is known that alkaline hydrolysate of pasture, with a dry matter concentration of 25 mg/ml, is used as a remedy to stimulate the immune system of animals, resulting in the activation of T- and B-lymphocyte systems, lysozyme, increased phagocytic activity of neutrophils and bactericidal activity of the immune system [4].

The disadvantage is that during the hydrolysis of the pasteurization with sodium hydroxide at a temperature of 95-1000C, the heat treatment significantly reduces the concentration of vitamins and thermolabile amino acids, which reduces the biological activity of the hydrolysate.

There is a known method of raising young bulls, which consists of feeding calves daily up to the age of 40 days with 5 kg of whole milk, hay, silage and concentrates at discretion, to which 3 kg of skimmed milk is added during the following growth period, while 25-55 g of pollen is added to the daily portion of whole milk [5]. This method leads to increased assimilation of biologically active substances and increased daily body mass gain of calves.

The disadvantage of this process is that adding 25-55 g of whole pollen to the daily portion of whole milk does not allow the full amount of biologically active substances contained in pollen to be achieved, because the lipid membrane of pollen is very resistant to the effects of enzymes of the gastrointestinal tract of animals, the pollen transiting through the gastrointestinal tract, and only less than 5% of the pollen grains are absorbed.

The closest solution is the method of treatment of viral-bacterial enteritis in calves, which includes watering the calves with a mixture containing components I and II. Component I contains honey, ethyl alcohol, alkaline hydrolyzate of pasteurization, Ringer-Lokk solution, and component II contains colostral immunoglobulin solution, sodium thiosulfate solution, theotropin solution and Ringer-Lokk solution. At the same time, components I and II are taken in an amount of 50.....150 ml and 50.....100 ml respectively and diluted in 500 ml of boiled water, and the calves are watered 2.....3 times a day, for 2.....3 days under fasting conditions [6].

The disadvantage of this method is that the constituents of component I have mainly energetic properties and as a means of substitution therapy due to the inclusion of honey, ethyl alcohol and alkaline hydrolysate of pasteurization, which compensates for the lack of monosaccharides, alcohol and amino acids that occur in the body of calves sick with enteritis. The constituents of component II are mainly a means of etiotropic therapy, have a specific effect on pathogens of infectious diseases that cause infectious enteritis, that is, a means of passive prevention and therapy of infectious diseases of animals.

The problem solved by the invention consists in stimulating the body's natural resistance in calves for the prophylaxis of immunodeficiency dyspepsia.

The problem is solved by the method of prophylaxis of immunodeficiency dyspepsia in calves, which includes feeding newborn calves with a mixture containing, per 1 L: skimmed milk powder - 100 g, apitherapeutic product - 1.0-2.0 g, water at a temperature of 38-40°C - the rest, in a dose of 1000.0 ml/head once a day, for 30 days, at the same time the apitherapeutic product contains, in a ratio of 3:1, dead bee powder and a mixture obtained by homogenizing drone larvae in a ratio of 1:6 with lactose and glucose, taken in equal parts.

The apitherapeutic component, powder of dead bees and drone larvae homogenized with a mixture of lactose and glucose, contains easily digestible biologically active and immunostimulating substances, capable of activating the immune system and metabolic processes of animals in minimal concentrations, which allows solving the problem of the invention.

The result of the invention consists in reducing the incidence of calves becoming ill due to immunodeficiency dyspepsia.

The invention is illustrated by the following examples, which do not limit the scope of the applicant's claims.

Examples of embodiments of the invention

Example 1

The process of preparing apitherapeutic immunostimulating food for calves.

The following components are used to prepare the claimed preparation: skimmed milk powder, dead bee powder, lactose and glucose mixture and homogenized drone larvae.

The mass of dried dead bees represents worker bees, which were collected during the spring renewal of the bee colony. The raw material is a mass of black-brown bees with a specific odor. Upon detailed examination, whole bees and various parts (head, thorax, abdomen, legs, wings, etc.) are visible. The average size of whole bees is 10-12 mm. Also, in a small amount, larger individuals (drones) can be found. Drying of dead bees was carried out at a temperature of 18-20°C for 3-4 days, then they were cleaned of impurities and ground to a powder state.

To obtain homogenized drone larvae, drone brood was reared in accordance with the general procedures for the maintenance and rearing of bees from healthy colonies, with a strength of at least 10 spaces between the combs populated with bees and reserves of carbohydrate and protein food for 7-9 days, from the end of May to the end of June. At the same time, bees fully rear drone brood when there is a stable honey harvest of carbohydrate and protein food and stop rearing it if there are less than 2.5 kg of honey and 0.12 kg of brood in the colonies. Up to 300 g of drone larvae are obtained from one colony of bees. Drone larvae were obtained using special combs with drone cells. The store comb was placed behind the comb with the brood as a cover frame. A signal for establishing the construction frame in the hive served the beginning of bleaching the combs - a sign of readiness to renew the nest in the family. Combs with drone larvae covered with wax caps were removed from the nests and transferred to the laboratory for further work. The wax caps on the covered brood were carefully cut with a beekeeping knife heated in boiling water. Then, with a light blow, the larvae were removed from the cells on a tray and collected in a container and by pressing a homogenized mixture was obtained. Due to the fact that the homogenized drone brood is a perishable protein product, in order to preserve the biologically active substances, the obtained homogenized mixture was immediately preserved. For this, part of the homogenized mixture was placed in a porcelain mortar, six parts of adsorbent (by mass) were added, using a mixture of lactose and glucose in a ratio of 1:1, and ground thoroughly. The crude homogenized mixture of adsorbed drone brood was stored at a temperature of 4-6°C for approximately 3 months before drying, the final product can be stored at ambient temperature for up to three years.

The apitherapeutic component was prepared by mixing in a 3:1 weight ratio of dead bee powder and homogenized drone brood with a mixture of lactose and glucose. To stimulate the natural resistance of the animal body for the purpose of prophylaxis of immunodeficiency dyspepsia in calves in the early postnatal period, a mixture of apitherapeutic composition with skimmed milk powder was used, in a proportion of 1-2 g of apitherapeutic component per 100 g of skimmed milk powder.

According to organoleptic and physico-chemical parameters, the immunostimulating feed for calves in the early postnatal period, consisting of a mixture of skimmed milk powder and bee products (dead bee powder + drone brood homogenized with a mixture of lactose and glucose), must comply with the following requirements and norms (see table 1 below).

Table 1

Organoleptic and physicochemical indices of immunostimulating feed for calves in the early postnatal period

Name of indices Characteristic and norm External appearance and color Homogeneous white powder with a slight cream tint Specific odor Mass fraction of moisture, %, not more than 5.0±0.50 Mass fraction of fat, %, not more than 1.5±0.15 Mass fraction of protein, %, not less than 34.0±3.4 Mass fraction of lactose, %, not less than 50.0±5.0

Example 2

Developing a procedure to stimulate the natural resistance of the calves' body to prevent immunodeficiency dyspepsia.

To develop the optimal scheme for the prevention of dyspepsia with the help of immunostimulating feed based on bee products in the conditions of the Denishnikov farm in the Grodno region, 70 one-day-old calves with reduced viability (with a weak sucking reflex, depression and immunodeficiency, confirmed by laboratory studies) were selected from the Black-spotted cows, from which 7 groups of animals, 10 animals each, were formed according to the principle of analogous pairs. In this case, one group was considered a control, the rest experimental.

The animals in the control group were maintained under the conditions of the technology adopted on the farm and were additionally administered 1 liter of dissolved skimmed milk powder (100 g skimmed milk powder + 900 ml water), orally, once a day. The calves in the experimental groups were also maintained under the conditions of the technology adopted on the farm and at the same time, they were administered various doses of the apitherapeutic component included in the immunostimulating feed according to the presented scheme (see table 2). In the experiment, observations of the animals were carried out up to the age of 30 days.

Table 2

Scheme of experience in developing the optimal composition and scheme for using immunostimulating feed for the prophylaxis of immunodeficiency dyspepsia in calves

Animal batches Number of heads Method, dose of apitherapeutic component and frequency of feeding Control 10 Lactation scheme, adopted on the farm + 1 liter of dissolved skimmed milk powder (100 g skimmed milk powder + 900 ml water) per/head for calves, once a day. I 10 Lactation scheme, adopted on the farm + oral immunostimulating feed, in a dose of 1 liter per/head for calves once a day (1g of apitherapeutic component per 100 g dissolved skimmed milk powder) from the first day to the 30th day after birth. II 10 Lactation scheme, adopted on the farm + oral immunostimulating feed, in a dose of 1 liter per/head for calves, once a day (1.5 g of apitherapeutic component per 100 g dissolved skimmed milk powder) from the first day to the 30th day after birth. III 10 Lactation scheme, adopted on the farm + oral immunostimulating feed, in a dose of 1 liter per/head for calves, once a day (2 g of apitherapeutic component per 100 g of dissolved skimmed milk powder) from the first day to the 30th day after birth. IV 10 Lactation scheme, adopted on the farm + oral immunostimulating feed, in a dose of 1 liter per/head for calves, 2 times a day (1 g of apitherapeutic component per 100 g of dissolved skimmed milk powder) from the first day to the 30th day after birth. V 10 Lactation scheme, adopted on the farm + oral immunostimulating feed, in a dose of 1 liter per/head for calves, 2 times a day (1.5 g of apitherapeutic component per 100 g of dissolved skimmed milk powder) from the first day to the 30th day after birth. VI 10 Lactation scheme, adopted on the farm + oral immunostimulating feed, at a dose of 1 liter per/head for calves, 2 times a day (2 g of apitherapeutic component per 100 g of dissolved skimmed milk powder) from the first day to the 30th day after birth.

The introduction of various doses of the apitherapeutic component in the immunostimulating feed in the early postnatal period in the experimental groups stimulated to a greater extent the increase in live weight and average daily gain compared to the young of the control group (see table 3).

As can be seen from Table 3, young animals from experimental groups two and three, which received immunostimulating feed once a day, at a dose of 1 liter per/head in calves with an apitherapeutic component content, at a dose of 1.5 g and 2.0 g per 100 g of skimmed milk powder, exceeded all other groups in terms of productivity.

By the end of the study, young animals in these groups exceeded calves in the control group in average daily gain by 16.7-17.5%.

Table 3

Dynamics of live weight and average daily gains in experimental calves (n = 70)

Indices Animal batches Control I II III IV V VI ±m ±m ±m ±m ±m ±m ±m Weight of calves, kg: At birth 30.90± 0.23 30.90± 0.23 31.00± 0.21 30.70± 0.26 31.20± 0.39 31.10± 0.35 31.10± 0.31 At the end of the experiment 42.30± 0.50 43.70± 0.21* 44.30± 0.50* 44.10± 0.72 43.80± 0.68 43.10± 0.66 44.20± 0.65* Average daily gain, g 380.01± 12.37 426.65± 6.67** 443.32± 11.17** 446.66± 18.73* 420.00± 17.36 400.01± 11.11 436.68± 18.88*

Note: - the significance level of the authenticity criterion in relation to the control batch

*P < 0.05, **P < 0.01.

Apparently, the maximum positive effect from the use of the studied dose of immunostimulating food containing 1.5-2.0 g of apitherapeutic component was obtained due to better digestibility of the use of nutrients in the ration and improvement of assimilation processes (see table 4).

Table 4

Prophylactic efficacy of using immunostimulating feed in calves with dyspepsia (n = 70)

Indices Control lots I II III IV V VI Number of animals in the lot, heads 10 10 10 10 10 10 10 Calves fell ill, heads 10 2 0 0 0 0 0 Calves fell ill, % 100 20 0 0 0 0 0 Average duration of the disease, days 7.8±0.3 4.6±0.3 0 0 0 0 0 Died, heads 3 0 0 0 0 0 0 Mortality, % 30 0 0 0 0 0 0 Safety, % 70 100 100 100 100 100 100

When assessing the clinical condition of animals with reduced viability from the experimental groups, it was found that the disease did not occur in them, except for the animals from the first experimental group, in which it evolved in a milder form, without visible systemic changes. The duration of the disease was 4.6 days. In calves, a slight suppression of the general condition was observed, a decrease in appetite, the body temperature of the animals remained within the physiological norm, frequent bowel movements, feces were liquid, in some cases with an admixture of mucus.

In animals infected with dyspepsia from the control group, which were not given immunostimulating food, dyspepsia was acute and was characterized by increased inhibition, decreased appetite and an increase in body temperature by 0.5-1.0°C. In calves, there was an increase in gastrointestinal tract peristalsis, constant involuntary defecation, liquid feces, yellow in color with an admixture of mucus, the duration of the disease was 7.8 days.

The proposed scheme contributed to increasing animal safety up to 100%.

Example 3

Study of the influence of immunostimulating feed on the prophylaxis of immunodeficiency dyspepsia in calves.

The results of the research demonstrated that the use of immunostimulating feed in the diet of calves with reduced viability contributed to the activation of oxidation-reduction and metabolic processes, ensured a more intense formation of cellular factors of nonspecific defense of the animal body with increased growth and development. The hematological parameters of the blood in experimental calves with reduced viability, treated with various doses of the apitherapeutic component in the composition of the immunostimulating feed are presented in Table 5.

Table 5

Hematological blood parameters in experimental calves (n = 70)

Animal batch Research period Erythrocyte indices, 1012/l Leukocytes, 109/l Hemoglobin, g/l ±m ±m ±m Control At the beginning of the experiment 6.93±0.25 6.21±0.33 103.50±4.65 At the end of the experiment 7.24±0.17 6.98±0.30 94.60±2.40 I At the beginning of the experiment 7.59±0.30 7.04±0.22 110.70±4.90 At the end of the experiment 7.98±0.21* 7.40±0.32 99.80±2.33 II At the beginning of the experiment 7.11±0.36 6.76±0.27 99.40±4.04 At the end of the experiment 8.57±0.29** 7.73±0.33 109.30±3.30** III At the beginning of the experiment 6.63±0.29 7.22±0.25 95.80±4.12 At the end of the experiment 8.49±0.23** 7.21±0.42 104.20±2.29* IV At the beginning of the experiment 7.16±0.31 7.14±0.29 104.6±3.34 At the end of the experiment 8.23±0.29* 7.34±0.38 106.80±4.11* V At the beginning of the experiment 6.88±0.28 6.87±0.35 106.00±4.89 At the end of the experiment 8.15±0.31* 7.56±0.30 103.30±4.26 VI At the beginning of the experiment 6.79±0.27 7.19±0.36 103.10±4.12 At the end of the experiment 8.30±0.32* 7.71±0.33 104.80±5.03

Note: - the significance level of the authenticity criterion in relation to the control batch

*P<0.05, **P<0.01.

The results of the blood parameter tests in calves showed that at the beginning of the experiment the concentration of erythrocytes in calves with reduced viability of the control group and the experimental groups was approximately at the same level and constituted: erythrocytes 6.63-7.59x1012/l and leukocytes 6.21-7.22x109/l. The hemoglobin concentration in animals from the control and experimental groups was 103.10-110.70 g/l.

The study of the hematological composition of the blood showed that the calves' body actively responded to the administration of biologically active compounds by increasing the intensity of oxidation-reduction processes.

The maximum and authentic number of erythrocytes and hemoglobin was observed in the blood of calves from the second experimental group, which received immunostimulating feed in a dose of 1 liter per head of calves, with a content of apitherapeutic component in a dose of 1.5 g per 100 g of skimmed milk powder, once a day and was higher than the control group, respectively by 18.4% (P <0.01) and 15.5% (P <0.01). The identified trend equally refers to an increase in the content of leukocytes.

By the end of the experimental studies, the content of leukocytes in the blood of animals from the second experimental group was also the highest and increased by 10.7% compared to calves from the control group, however, the established increase had a trend character. A marked increase in hemoglobin concentration was observed in other experimental groups.

The content of erythrocytes, hemoglobin and leukocytes in the blood of animals from experimental groups I, III, IV, V and VI increased compared to calves from the control group by 10.2-17.3%, 5.5-12.9% and, respectively, 3.3-10.5%.

Table 6 presents the results of the study of the concentration of total proteins and protein fractions in the blood serum of calves with reduced viability, receiving various doses of apitherapeutic component in immunostimulating food for the prevention of dyspepsia.

The results of studies on protein metabolism showed that at the beginning of the experiment, the concentration of total protein in the blood serum of animals with reduced viability of the control group and the experimental groups were approximately at the same level with non-essential fluctuations and amounted to 48.00-58.33 g/l.

The albumin and globulin content was approximately at the same level and amounted to 27.82-31.90 g/l and 20.07-28.74 g/l, respectively (see table 6).

Table 6

Biochemical blood parameters in experimental calves (n = 70)

Animal batch Research period Indices total proteins, g/l albumins, g/l globulins, g/l ±m ±m ±m Control At the beginning of the experiment 52.34±1.27 31.04±0.92 21.30±1.61 At the end of the experiment 56.23±1.52 30.70±1.22 25.53±1.91 I At the beginning of the experiment 58.33±1.80 29.59±1.05 28.74±2.19 At the end of the experiment 63.38±1.42** 33.67±1.15 29.71±1.77 II At the beginning of the experiment 50.33±1.37 30.26±0.84 20.07±1.68 At the end of the experiment 64.10±1.62** 36.27±0.93** 27.83±1.22 III At the beginning of the experience 48.00±1.34 27.82±0.84 20.18±1.70 At the end of the experience 63.10±2.01* 35.15±0.94* 27.95±2.25 IV At the beginning of the experience 51.62±1.79 30.22±0.92 21.40±1.32 At the end of the experience 63.61±1.97* 35.01±1.52* 28.61±0.80 V At the beginning of the experience 54.83±1.22 31.90±1.38 22.94±1.32 At the end of the experience 63.27±2.19* 33.89±1.48 29.05±0.90 VI At the beginning of the experiment 53.52±1.37 31.26±0.88 22.26±1.11 At the end of the experiment 62.99±2.09* 34.18±1.38 28.81±1.39

Note: The significance level of the authenticity criterion in relation to the control group

*P < 0.05, **P < 0.01.

As can be seen from the data in Table 6, in the animals of the second experimental group, which received immunostimulating feed in a dose of 1 liter per head in calves with an apitherapeutic component content in a dose of 1.5 g per 100 g of skimmed milk powder once a day, at the end of the studies the concentration of total protein and albumin in the blood serum increased by 14% and 18.1%, respectively (P <0.01), compared to the control group. The concentration of total protein in the blood serum of animals from experimental groups I, III, IV, V and VI increased by 12.7% (P <0.01), 12.2% (P <0.05), 13.1% (P <0.05), 12.5% (P <0.05) and 12.0% (P <0.05) respectively and increased to 63.10-63.61 g/l compared to 56.23 g/l in the control group. The albumin content increased by 9.7%, 14.5% (P <0.01), 14% (P <0.05), 10.4% and, respectively11.4% compared to the control group.

The revealed changes apparently indicate a more complete and high-quality assimilation of milk proteins in the body of animals that received immunostimulating feed at a dose of 1 liter per/head in calves with an apitherapeutic component content of 1.5 g per 100 g of skimmed milk powder once a day.

The results of the study of the level of natural resistance of the body of calves with reduced viability, receiving various doses of the apitherapeutic component of the feed, showed that the use of immunostimulating feed contributed to an increase in the cellular and humoral protection of the animal body (see table 7).

Table 7

Indicators of cellular and humoral defense of the organism of experimental calves (n = 70)

Animal batch Research period Indices Phagocytic activity, % Bactericidal activity, % Lysozyme activity, % Complementary activity, % ±m ±m ±m ±m Control beginning 41.70±1.27 34.48±1.57 16.52±0.39 1.86±0.11 end 45.50±1.49 52.17±1.56 17.51±0.34 4.48±0.15 I beginning 42.40±1.21 34.70±1.52 16.35±0.31 1.93±0.10 end 49.40±1.46 58.57±1.64* 18.30±0.48 5.28±0.21** II beginning 40.30±1.14 35.21±1.71 17.15±0.41 2.19±0.11 end 52.30±1.28** 60.48±1.80** 18.97±0.31** 5.42±0.24** III beginning 41.80±1.08 33.62±1.61 16.80±0.48 2.22±0.15 end 51.10±1.18* 56.41±2.15 18.67±0.49 5.24±0.23* IV beginning 41.60±1.32 27.39±1.37 21.81±1.16 2.06±0.13 end 50.30±1.75 55.81±2.09 17.81±0.52 4.89±0.19 V beginning 42.20±1.41 34.68±1.75 19.91±0.92 1.97±0.10 end 49.00±1.21 56.93±1.80 17.06±0.50 4.15±0.21 VI beginning 40.80±1.26 29.37±1.19 20.98±0.94 1.79±0.12 end 51.50±1.37* 54.05±2.21 16.71±0.41 4.10±0.15

Note: The significance level of the authenticity criterion in relation to the control batch

*P < 0.05, **P < 0.01.

The most pronounced increase in phagocytic activity was observed in animals from the second experimental group, which received immunostimulating feed once a day, in a dose of 1 liter per/head in calves with an apitherapeutic component content of 1.5 g per 100 g of skimmed milk powder. Calves from this group exceeded the control group by 14.9% (P <0.01) according to this indicator. Also, the results presented in Table 7 indicate that immunostimulating feed increases the parameters of bactericidal, lysozyme and complement activity of blood serum. The most pronounced and authentic increase in the indicators of humoral factors of the body's defense was observed in calves from the second experimental group. So, the indicators of bactericidal activity of blood serum from the second experimental batch of calves exceeded these indicators of the control batch by 16.0% (P <0.01), and the indicators of lysozyme and complement activity by 8.3% (P <0.01) and, respectively, by 21.0% (P <0.01).

The best hematological, biochemical and immunological parameters of the animals in the second experimental batch were consistent with the further increase in the resistance of the animals' body.

Thus, feeding calves with immunostimulating food based on bee products (dead bee powder + drone brood homogenized with a mixture of lactose and glucose) and skimmed milk powder ensures increased activity of animals, increased content of erythrocytes, hemoglobin and total proteins in the blood. These changes in the blood composition of calves indicate the normalization of a number of biochemical processes in the body, an increase in the amount of oxygen consumed and, in general, the beneficial effect of the remedy on the body of calves.

1. RU 2033798 C1 1995.04.30

2. RU 2098108 C1 1997.12.10

3. RU 2145228 C1 2000.02.10

4. MD 889 B1 1997.12.31

5. MD 2755 F1 2005.05.31

6. MD 3360 F1 2007.07.31

Claims (1)

Method of prophylaxis of immunodeficiency dyspepsia in calves, which includes feeding newborn calves with a mixture containing, per 1 L: skimmed milk powder - 100 g, apitherapeutic product - 1.0-2.0 g, water at a temperature of 38-40°C - the rest, in a dose of 1000.0 ml/head once a day, for 30 days, at the same time the apitherapeutic product contains, in a ratio of 3:1, dead bee powder and a mixture obtained by homogenizing drone larvae in a ratio of 1:6 with lactose and glucose, taken in equal parts.