RU2557527C1 - Method of correction of immunobiochemical status in cows in prenatal and postpartum periods - Google Patents

Abstract

FIELD: veterinary medicine.

SUBSTANCE: invention is a method of correction of immunobiochemical status of cows in the prenatal and postpartum periods. The invention comprises the following steps: the dry cows within 10-12 days prior to and 10-12 days after parturation are given orally the composite agent based on organic acids, containing fumaric, ascorbic, succinic and citric acid based on per dose, mg/kg body weight: fumaric acid - 3.0-5.0; ascorbic acid - 4.5-7.5; succinic acid - 6.0-10.0; citric acid - 1.5-2.5, in combination with dualfold intramuscular injection tetrahydrovit 30 days before and on the day of parturation at a dose of 10 ml/head, and threefold intramuscular injection of iron complex 30, 15 days before and on the day of parturation at a dose of 0.2 ml/10 kg bodyweight.

EFFECT: invention provides a correction of immunobiochemical homeostasis at the level providing for physiological parturation and the postpartum period and obtaining viable offspring.

14 tbl, 3 ex

Description

The invention relates to veterinary medicine, relates to a method for correcting the immunobiochemical status of cows in the prenatal and postpartum periods and can be used for therapeutic and prophylactic protection of cows from mass diseases of the reproductive organs and for obtaining a physiologically healthy offspring.

Pregnancy, the birth following it, and the postpartum period in all mammals are accompanied by significant changes in the metabolism, which can manifest themselves in clinical and subclinical metabolic disorders. In this case, the most vivid picture of the tension of metabolic processes develops at the final stage of pregnancy and in the early postpartum period. Along with this, it was noted that the development of obstetric pathology in animals is based on a disorder in the synthesis and metabolism of hormones, vitamins, proteins, carbohydrates, lipids, mineral and other biologically active substances. The high physiological role of trace elements in animals is characterized by the fact that they are closely associated with the activation of hormones, enzymes, vitamins and other biologically active substances (BAS) that support homeostasis. Trace elements actively combine with proteins, resulting in the formation of new substances that have high activity in the body. If the body lacks trace elements, the formation of hormones, vitamins and enzymes is significantly reduced and, accordingly, the overall metabolism decreases. A significant amount of enzymes is closely associated with trace elements. So, manganese is an active component of the arginase enzyme, with which proteins are broken down. Trace elements activate the synthesis and activity of various vitamins, and in some of them they are included as components. For example, vitamin B ₁₂ contains cobalt. The effect of trace elements on the body is carried out mainly through enzymes, vitamins and hormones. By increasing their activity, microelements significantly increase the overall metabolism of proteins, carbohydrates, lipids, etc., contribute to increased respiration, better hematopoiesis, protein synthesis, as well as better absorption of feed nutrients, thereby increasing the growth and development of animals, increasing their productivity and reproductive ability . Vitamins and minerals play an important role in maintaining the homeostasis of the body of cows. So, zinc is involved in the metabolism of nucleic acids, carbohydrates, proteins and fats, is of great importance in the functioning of the immune system and is part of hormones. Iron is involved in redox processes. It is part of hemoglobin and a number of enzymes (oxidases, peroxidases, catalases), including cytochromes, involved in biological oxidation. Manganese takes part in the formation of connective tissue and cartilage, ensuring the functioning of the reproductive function, is necessary for lipid and cholesterol metabolism, and counteracts fatty degeneration of the liver. Copper is a vital trace element involved in metabolism and tissue respiration, hematopoiesis, is part of hormones and enzymes, and has an anti-inflammatory effect. Cobalt is part of cyanocobalamin, promotes the excretion of water by the kidneys, the blocking and elimination of toxic elements from the body. Selenium protects the body from harmful substances and toxins, stimulates the metabolism and immune defense of the body. Iodine regulates the rate of chemical reactions, is part of the thyroid hormones. Vitamin A plays an important role in the growth and reproduction of cells, ensures the normal state of the mucous membranes (barrier function), supports the functions of the retina and the process of light perception. Vitamin D is involved in the regulation of calcium-phosphorus metabolism. Vitamin E normalizes the functions of the reproductive organs (contributes to the fertilization and development of embryos), affects the activity of the pituitary and thyroid gland, destroys the most reactive forms of oxygen and accordingly protects polyunsaturated fatty acids from destruction [1].

Disorders of mineral metabolism often lead to a weakening of the immune system, impaired reproductive function and fertility [2]. With latent deficiency of macro- and microelements, with a violation of the ratio of minerals in the body, the disease proceeds without visible clinical signs.

Not the last role is assigned in connection with the occurrence of various pathological conditions for lipid peroxidation. Currently, it has been proven that lipid peroxidation processes not only play an important role in the normal physiology and biochemistry of the cell, but also act as a universal nonspecific link in the development of various pathologies, and depending on their level of activity, they can also turn into a leading link in the pathogenesis of diseases.

The value of the state of immunobiochemical status as a pathogenic factor in obstetric pathology of cows is confirmed by the low efficiency of methods of prophylaxis with the use of drugs without taking into account immunobiochemical processes.

A known method for the correction of metabolic pathologies, treatment and prevention of their consequences, including the use of a universal complex preparation containing sodium selenite, vitamin E, succinic acid, zinc sulfate and pharmazin, which is administered intramuscularly 45, 30, 15 days before delivery and on the day of delivery [3].

Still known are means of increasing the reproductive ability of farm and domestic animals based on various biologically active substances that positively affect reproductive function, improve blood circulation, based on micro and macro elements and vitamins [4]. As a result of the correction of metabolic processes, metabolic reorientation of the body occurs, which has a significant effect on the level of natural resistance.

Means are also known that provide antioxidant protection of the body, contribute to the normalization of metabolism and increase resistance due to the reduction and prevention of the accumulation of toxic lipid peroxidation products, for example, a preparation containing succinic and ascorbic acids [5].

As a preferred analogue, a method for normalizing the immunobiochemical status of cows in the prenatal and postpartum periods is considered, including a single intramuscular injection of a 0.5% sodium selenite solution 20-25 days before delivery, a double injection before and twice after delivery with an interval of 10 days of tetravit containing vitamins A, D ₃ , E and C. At the same time, succinic acid is administered orally for 20–25 days before and after childbirth [6].

However, the known methods do not ensure the normalization of the immunobiochemical status in full, acting on its individual indicators without taking into account the mechanisms of metabolic disorders depending on the physiological state of the animal.

The technical solution to the problem is to increase the immunoreactivity of animals in the prenatal and postpartum periods, improve intrauterine development of the fetus and preserve the complex effect of biologically active substances on the maximum number of body defenses, including the antioxidant defense system.

The problem is solved in that in the method for correcting the immunobiochemical status of cows in the prenatal and postpartum periods, which consists in prescribing organic acids, vitamin and mineral complexes to deep-cows, organic acids are used in the form of a composition called “Bio-FAYAL” containing fumaric , ascorbic, succinic and citric acids, tetrahydrovit as a vitamin complex, and iron complex as a mineral complex.

The method is as follows.

For cows, for 10-12 days before and 10-12 days after birth, the Bio-FAYAL compositional agent containing fumaric, ascorbic, succinic and citric acids per dose, mg / kg body weight, is orally administered: fumaric acid - 3, 0-5.0; ascorbic acid - 4.5-7.5; succinic acid - 6.0-10.0; citric acid - 1.5-2.5, in combination with a double intramuscular injection of tetrahydrovit 30 days before and on the day of birth at a dose of 10 ml / goal. and triple intramuscular injection of iron complex 30, 15 days before and on the day of birth at a dose of 0.2 ml / 10 kg of live weight.

A composite agent based on organic acids, called “Bio-FAYAL”, contains substances (fumaric ascorbic, succinic and citric acids) that have membrane-protective and immune-enhancing properties. Succinic and citric acids are important factors in the regulation of the physiological state and increase the overall resistance of animals and birds, activate the nervous system, the kidneys and intestines, have an anti-stress effect. Succinic and citric acids have antidote properties, cleansing the body of heavy metals, radionuclides, salts of nitric and nitrous acids. In addition, succinic acid has lactoprotective and antiviral effects. Citric acid stimulates the formation in the intestines of chelated forms of calcium, zinc, iron, etc., which are much more easily absorbed by the body. It is reliably known that citric acid is a synergist of succinic acid, enhancing the biological effect of the latter. Ascorbic acid (vitamin C) plays an important role in redox processes, reactions of carbohydrate and protein metabolism, reduces cholesterol and calcium levels in the blood, reduces the deposition of lipids and calcium in organs, activates the enzymes of the stomach, intestines, has antihemorrhagic effect, prevents the development of infectious beginning in the body, stimulates the exocrine pancreatic function, erythropoiesis and the system of mononuclear phagocytes, provides anti-inflammatory effect of ionized of calcium, it activates phagocytosis. Fumaric acid is a natural metabolite of living organisms, provides emergency ATP synthesis, thereby counteracting stress at the cellular level. It is resistant to oxidation, temperature fluctuations and compatibility with other biologically active substances. The accelerated formation of ATP with the participation of fumaric acid contributes to the conservation of glucose for the synthesis of glycogen in the liver and ascorbic acid in the body. The accumulation of reserve nutrients and ascorbic acid in the liver prolongs the period of its active functioning and ensures the cleansing of the liver of metabolic products.

Tetrahydrovit - a complex of 4 vitamins with a content of 1 ml of solution: vitamin A - 25000 ME; Vitamin D ₃ - 5000 ME, Vitamin E - 25 mg, Vitamin C - 50 mg, makes up for the deficiency of vitamins in animals [7].

Iron complex - a drug in the form of an injectable solution, intended for the prevention and treatment of iron deficiency anemia, micronutrient deficiencies, normalization of metabolism, increase productivity and preservation of livestock in cattle, which includes a complex of ethylenediamidineduccinic acid and lysine with iron, manganese, copper , zinc, cobalt, selenium, iodine and water for injection. 1 ml of the solution contains as active substances, mg: iron - 10.0; Manganese - 7.0; copper - 1.0; zinc - 9.0; cobalt - 0.12; selenium - 0.11; iodine - 0.26 in the form of chelates and water for injection [8].

The essence of the method is illustrated by examples.

Example 1. To study the effect of the Bio-FAYAL compositional agent on the immunobiochemical status, four groups of deep-skinned cows were selected according to the principle of analogs 15-20 days before the expected birth: 3 groups — experimental, 1 group — control. All animals were in the same conditions of feeding and keeping.

The cows of the first experimental group (n = 9) were fed with the Bio-FAYAL composite agent mixed with animal feed, containing per dose, mg / kg body weight: fumaric acid - 4.0; ascorbic acid 6.0; succinic acid - 8.0; citric acid - 2.0; to the cows of the second experimental group (n = 8) - the composite Bio-FAYAL means containing per dose, mg / kg live weight: fumaric acid - 5.0; ascorbic acid - 7.5; succinic acid - 10.0; citric acid - 2.5; to the cows of the third experimental group (n = 10) - the composite Bio-FAYAL means containing per dose, mg / kg of live weight: fumaric acid - 7.0; ascorbic acid - 10.5; succinic acid - 14.0; citric acid - 3.5; within 10-12 days before and within 10-12 days after birth. Animals of the fourth group (n = 10) did not receive drugs and served as a control.

To assess the immunobiochemical status of the experimental animals, laboratory blood tests were performed before the experiment - 15-20 days before birth and 10-12 days after birth. Immunobiochemical status was evaluated by morphobiochemical indicators (table 1), indicators of natural resistance (table 2) and immune status (table 3).

The animals were monitored, noted the nature of the course of the prenatal, labor and postpartum periods, performed clinical and gynecological examinations of cows, took into account the timing of involution of reproductive organs and insemination. The results are presented in table 4.

When analyzing the results of immunobiochemical blood tests (tables 1, 2, 3), it was found that the composite tool “Bio-FAYAL” did not adversely affect the studied parameters. The most physiological dynamics of immunobiochemical parameters was observed in cows of the first and second experimental groups. As can be seen from table 4, all cows in the control group showed pathology of childbirth and the postpartum period. The use of the Bio-FAYAL composite agent in experimental animals reduced the incidence of reproductive organs in cows in the birth and postpartum periods by 20.0-37.5% in comparison with the control, significantly reduced the time of genital involution after delivery in the cows of the first and second experimental groups by 7.0 and 10.3 days, respectively, compared with the control group, a significant decrease in the number of days of infertility and the duration of the service period by 12.6 days and the fertilization index by 26.6% in cows of the second experimental group. Fertilization of cows in the experimental groups compared with the control was higher by 10.0-18.9%. Studies have confirmed the validity of the claimed doses of the composite tool "Bio-FAYAL".

Example 2. To justify the industrial applicability of the claimed method, four groups of deep-skinned cows were selected 30 days before the expected calving on the basis of analogue pairs: 3 groups — experimental, 1 group — control. The cows of the experimental groups were assigned: the first group - the composite tool "Bio-FAYAL", containing, based on the dose of mg / kg body weight: fumaric acid - 5.0; ascorbic acid - 7.5; succinic acid - 10.0; citric acid - 2.5, within 12 days before and 12 days after birth (oral), iron complex at a dose of 0.2 ml / kg body weight 30 and 15 days before and on the day of birth (intramuscularly), tetrahydrovit at a dose of 10 ml / goal 30 days before and on the day of birth; the second group - iron complex at a dose of 0.2 ml / kg body weight 30 and 15 days before and on the day of birth (intramuscularly), tetrahydrovit at a dose of 10 ml / goal. 30 days before and on the day of birth (intramuscularly); the third group - a composite tool "Bio-FAYAL", containing, based on the dose of mg / kg body weight: fumaric acid - 5.0; ascorbic acid - 7.5; succinic acid - 10.0; citric acid - 2.5, for 12 days before and 12 days after birth (oral). The cows of the control group were not prescribed drugs. Blood sampling was carried out before the start of the experiment - 30-35 days before childbirth and 10-14 days after birth. The results were taken into account, as in example 1. The results are presented in tables 5, 6, 7, 8. The born calves were weighed on the first day after birth and on the 30th day of life and their condition was assessed by the main clinical indicators. The results are presented in tables 9, 10, 11.

Studies have shown that the claimed method ensured that optimal lipids, vitamin A (table 5) and bactericidal activity of blood serum were maintained at an optimal level after delivery, an increase in lysozyme activity of blood serum by 17.7% (table 6), Ig G by 25 , 7%, Ig A - by 40.0%, Ig M - by 52.2% (table 7).

As can be seen from table 8, the incidence of cows in the first, second and third experimental groups was lower than in the control by 55.6; 7.8 and 48.8%, respectively. A more physiological course of the birth and postpartum period in animals of the first experimental group caused a reduction in the term of genital involution by 18.7 days (p≤0.001) compared with 4 days in the second and 14.6 days (p≤0.001) in the third experimental group, a decrease in the duration of infertility by 16.6 days (p≤0.001) compared with 8.5 in the second and 13.7 days (p≤0.01) in the third experimental groups and the fertilization index by 25.6% (p≤0, 05) compared with 8.4% in the second and 20.0% in the third experimental groups, respectively, compared with the control. Fertility in animals of the experimental groups was at the level of 80.0-88.9%, which is 3.3-22.2% higher than in the control. In the first and third experimental groups, there were no recorded cases of retention of the placenta, while in the second experimental and control groups with retention of the placenta, 20.0 and 20.2% of the cows, respectively. In addition, stillbirth was recorded in two cows of the control group.

As can be seen from table 9, on the 3-7th day after birth, the hemoglobin content in calves obtained from cows of the first, second and third experimental groups exceeded the control group by 45.3 (p≤0.001), 44.9 (p≤0.001 ) and 60.6% (p≤0.001), respectively. The hemoglobin level in the calves of the control group was 75.9 ± 1.6 g / l, which is significantly lower than the physiological norm and indicated a state of hypoxia. The number of red blood cells in all experimental calves corresponded to the physiological norm, while in animals of the first experimental group, the indicator was significantly higher in comparison with the second group by 15.8 (p≤0.05). The glucose level in all experimental calves was characterized by high indicators, which corresponded to the physiological norm in the early postnatal period (4.0-5.8 mmol / l), while in the experimental calves the glucose values exceeded those of the control calves. The copper content in the blood serum of calves of the first and second experimental groups exceeded the corresponding indicator of the third experimental and control groups by 11.4 (p≤0.05) and 8.3% (p≤0.05) and 14.7 (p ≤0.01) and 11.5% (p≤0.05), respectively. The concentration of low and medium molecular weight substances (VNSSM) in all animals except for calves of the second experimental group was at the level of 15.7-16.1 units. In young animals of the second experimental group, the studied indicator was 18.3 ± 0.2 units, which is 13.7-17.3% (p≤0.001) higher than in calves of other groups. The most optimal VNSMM indices were noted in the first and third experimental groups - 15.7 ± 0.2 and 15.6 ± 0.3 units, which indicated a decrease in the level of endogenous intoxication in both cows and their offspring. As can be seen from table 10, the bactericidal activity of blood serum in all experimental calves was at a relatively high level, however, in the experimental groups its indices were higher than the control by 3.5-11.2%. The phagocytic index in calves of the first experimental group exceeded the value of the corresponding indicator of the control group by 22.2% (p≤0.05), and the content of retinol was higher than in the control by 28.7% (p≤0.05).

As can be seen from table 11, there was no significant difference in the live weight of newborn calves by group, with the exception of the second experimental group, in which the live weight of calves at birth was 8.8% higher (p≤0.05) compared with the control. A month after birth, the live weight of calves of the first and third experimental groups was higher than that of control animals by 11.0 (p≤0.01) and 8.0% (p≤0.05), respectively. The absolute average daily gain in live weight in calves of the first and third experimental groups was 413.3 and 400.0 g, which is 26.5 and 22.4% higher than in the control.

As can be seen from table 12, the incidence of calves in the first experimental group was 22.2% compared with 50.0% in the second, 30.0% in the third experimental group and 71.4% in the control. In calves of the first experimental group, the first signs of gastrointestinal diseases were observed on the 7-8th day of life, and in calves of the control group - 2-3 days after birth. The disease in the calves of the control group was characterized by a more severe course. The calves of the experimental groups (first and third) were ill mainly in a mild form, the treatment was carried out by prescribing a diet and drinking rehydration solutions and astringents. The safety in these groups was 100%.

The obtained results confirmed that the combined use of the Bio-FAYAL composite agent, iron complex and tetrahydrovit according to the claimed scheme contributed to the correction of immunobiochemical homeostasis at a level that ensures the physiological course of childbirth and the postpartum period and the production of a viable offspring with higher growth energy.

Example 3. To determine the comparative effectiveness of the claimed and known methods, four groups of deep-skinned cows were selected 30 days before the expected birth, according to the principle of analogue pairs: 3 experimental groups, 1 control group. The cows of the experimental groups were assigned: the first group - the composite tool "Bio-FAYAL", containing, based on the dose of mg / kg body weight: fumaric acid - 5.0; ascorbic acid - 7.5; succinic acid - 10.0; citric acid - 2.5, within 12 days before and 12 days after birth (oral), iron complex at a dose of 0.2 ml / kg body weight 30 and 15 days before and on the day of birth (intramuscularly), tetrahydrovit at a dose of 10 ml / goal 30 days before and on the day of birth (the claimed method); the second group - a 0.5% solution of sodium selenite at a dose of 10 ml / goal. 20 days before birth (intramuscularly), tetravitis at a dose of 10 ml / goal. twice with an interval of 10 days before and after childbirth, succinic acid in a dose of 1.0 g / goal. and within 20 days before and after childbirth (oral) (analogue); the third group - a 0.5% solution of sodium selenite in a dose of 10 ml 20 days before birth (intramuscularly), tetravit in a dose of 10 ml twice with an interval of 10 days before and after childbirth (intramuscularly) (basic method). The cows of the control group were not prescribed drugs. Accounting for the results, as in example 1. The results are presented in tables 13 and 14.

As can be seen from table 13, the claimed method provided a more effective correction of the immunobiochemical status: for all the studied parameters, an increase was noted, with the exception of the hemoglobin content and the level of phagocytic activity of neutrophils, at the same time, these indicators were within physiological norms. Optimization of metabolic processes, an increase in the overall natural resistance and immune status in cows contributed to a decrease in the level of obstetric pathologies by 47.8% compared with the control, by 17.8% compared with the base method and by 7.8% compared with the analogue method a reduction in the term of infertility by 16.6 days compared with the control, by 8.1 days compared with the base method and by 2.4 days compared with the similar method, an increase in fertility by 28.9% compared with the control, by 18.9% compared with the base and with the analogue method (table 14) .

The high efficiency of the method is associated with the combined action and optimal selection of dosages and regimens for the use of the Bio-FAYL composite agent based on organic acids, a complex of vitamins in the form of a tetrahydrovit preparation, and a mineral complex in the form of iron complex, each of which has a wide spectrum of pharmacological activity.

Sources of information taken into account

1. Berezov, T.T. Biological chemistry. - M.: Medicine, 1998 .-- 704 p.

2. Zinchenko L.I., Pogorelova I.E. Mineral and vitamin nutrition of cows. - L .: Kolos, 1980, 77 p.

3. RF patent No. 2268033 C2, 2006.

4. RF patent No. 2392824 C1, 2010.

5. RF patent No. 2289402 C2, 2006.

6. RF patent №2252767 C1, 2005.

7. www / vettorg.net / pharmacy

8. www / vetlek.ru / reestr / item.php

Claims (1)

A method for correcting the immunobiochemical status of cows in the prenatal and postpartum periods, which consists in administering organic acids, vitamin and mineral complexes to deep-cows, characterized in that fumaric, ascorbic, succinic and citric acids are used in the form of a composition containing fumaric, ascorbic, succinic and citric acid per dose, mg / kg body weight: fumaric acid - 3.0-5.0; ascorbic acid - 4.5-7.5; succinic acid - 6.0-10.0; citric acid - 1.5-2.5, as a vitamin complex - tetrahydrovit, as a mineral complex - iron complex, according to the following scheme: a compositional agent containing, based on the dose of mg / kg body weight: fumaric acid - 3.0 -5.0; ascorbic acid - 4.5-7.5; succinic acid - 6.0-10.0; citric acid - 1.5-2.5, within 12 days before and 12 days after delivery (oral), iron complex - at a dose of 0.2 ml / kg body weight 30 and 15 days before and on the day of delivery (intramuscularly) , tetrahydrovit - at a dose of 10 ml / goal. before and on the day of birth (intramuscularly).