RU2818836C1 - Method for iron deficiency anemia correction in sucking calves - Google Patents

Abstract

FIELD: veterinary medicine.

SUBSTANCE: invention refers to clinical pharmacology and therapy of animals, and concerns a method of preventing diseases in animals caused by iron deficiency. Method for correction of iron deficiency anemia in sucking calves is characterized by the fact that from age of 5 days, a fodder additive containing a coniferous energy additive is introduced into the basic diet, linseed, fodder yeast and active carbon additive. Fodder additive is introduced in amount of 15.0 ml per head for 14 days without intervals by feeding with water in amount of 50–100 ml once a day.

EFFECT: invention usage will allow to correct iron-deficiency anemia in sucking calves.

1 cl, 2 tbl

Description

The invention relates to the field of veterinary medicine, namely to clinical pharmacology and therapy of animals, and concerns a method for the treatment and prevention of animal diseases caused by a lack of iron in their body and the correction of side effects of iron compounds.

One of the important tasks of dairy cattle breeding is to obtain high-quality products at the lowest economic costs. In this regard, the issue of using domestic feed additives based on the processing of forest biomaterial for the correction of certain pathological conditions in dairy calves is relevant [1, 2].

One of the most common metabolic diseases in young farm animals is iron deficiency anemia (IDA). Iron deficiency anemia of calves is a pathological condition of the body, characterized by disruption of the activity of hematopoietic organs and metabolism, subsequently leading to growth retardation and decreased immunity [3].

In Russian farms of all forms of ownership, the intensity of increasing the number of productive animals depends on the effective prevention and correction of various deviations from homeostasis in young animals born [4]. At the same time, in many farms for raising and fattening young cattle, iron deficiency anemia (IA) is often registered among other conditions, in which, in addition to the direct loss from the death of animals, large amounts of money are spent on the correction and implementation of various preventive veterinary and sanitary and organizational work to prevent various complications that can further cause a reduction in the number of livestock [5, 6].

Iron deficiency in the body leads to a decrease in the level of vital hemoglobin in red blood cells, the iron of which plays an important role in the formation of the oxygen-hemoglobin complex and prolonging its existence so that this complex reaches the capillaries, where it gradually disintegrates and releases released oxygen to the tissues. With a lack of iron, the duration of existence of such a complex is reduced to varying degrees, being one of the causes of hypoxia.

Signs of VA are detected in 6.9-29.3% of 1-3 day old calves and in approximately 20% of 30-40 day old calves [7]. This is due to the fact that with a relatively high iron content in plant feed, the average daily balance in the body of calves is negative, even in the first two months of life, since young animals during this period are not sufficiently able to absorb the required amount of iron from feed due to the imperfection of their digestive apparatus . The cause of VA in newborn calves is largely explained by prenatal iron deficiency in the cow's feed.

In this regard, iron deficiency in fetuses of cattle is the main cause of VA in calves. Thus, with the industrial method of rearing, VA occurs most often in the newborn phase, causing a general decrease in the animal’s resistance to infectious diseases and a slowdown in growth [4]. This type of VA occurs immediately after birth and worsens during the colostrum period due to insufficient iron intake from feed, causing a significant number of calves to become anemic [8].

VA in newborn calves can be aggravated by the lack of supply of their body with such microelements as copper, iodine, cobalt, manganese, etc. Of these microelements, the most important is copper, which is involved in the processes of hematopoiesis, in particular in the synthesis of hemoglobin, and also contributes to a sufficient level of iron adsorption from the gastrointestinal tract. -intestinal tract into the blood. Due to a lack of copper, iron begins to be absorbed worse, causing additional depression of hemoglobin synthesis, which leads to worsening anemia against the background of hypocupremia and hypofergemia [7, 9].

To correct iron deficiency, preparations containing iron are used. The most effective are iron dextran products, which are obtained by combining iron with the polysaccharide dextran, which easily forms colloidal solutions.

They are administered intramuscularly in the thigh area or behind the ear for therapeutic purposes, usually twice at a rate of at least 200 mg of iron once. In the body, iron is released from its connection with dextran and is utilized (absorbed) by the cells of the reticulohistiocytic system. Its absorption begins 3-4 hours after administration of the drug, is completed within 3-4 days and is consumed by the body within approximately 30 days [10]. Repeated administration of drugs is practiced after 7-10 days. As a result of double administration of the drug, calves in most cases are fully provided with the required amount of iron. One of the most long-term, well-tested and effective drugs is ferroglucin, which is capable of creating sufficient iron reserves in animals for the construction of the hemoglobin molecule and the functioning of enzyme systems.

There is information about the use of ferroglucin for anemia in calves [11].

As effective stimulants for the vital activity of a growing organism, modern veterinary medicine uses fosprenil, a drug based on polyprenolic phosphates obtained from pine needles [12], and krezacin, a derivative of aroxyalkylcarboxylic acids, which exhibits an effective stimulating effect on living organisms, increasing the survival of animals in unfavorable and extreme conditions, stimulating or normalizing life processes [13].

There is a known method for correcting hyperfibrinogenemia in newborn calves and piglets with anemia by using ferroglucin 150 mg (2 ml) intramuscularly, twice with an interval of 10 days, fosprenil intramuscularly, twice in different syringes at different points, the first time 0.07 ml/kg simultaneously with iron preparation, a second time at a dose of 0.07 ml/kg six days after the first injection of ferroglucin and krezacin 4 mg/kg when included in the feeding regimen for 10 days. [14]

A method of correcting the antioxidant activity of the liquid part of the blood in newborn calves with iron deficiency anemia is known from the prior art, including the use of a solution of Ferroglucin-75 intramuscularly, once in combination with the administration of glycopin [15]. The disadvantage of this method is its use only on newborn calves with already developed anemia, which does not allow using this method on other age groups of calves and using this method for the prevention of anemia, and this method does not take into account the pro-oxidant properties of iron included in the drug.

There is a known method for the prevention and treatment of iron deficiency anemia in calves in arid zones, including the administration of the complex iron dextran drug Sedimin-8e+ intramuscularly on the 5-6th day of the calf’s life in a dose of 5 ml, followed by an intramuscular injection of the drug Hydropeptone in a dose of 5 ml, which is a hydrolyzate soy protein compensated for methionine [16].

Currently, the most promising research is related to the use of bioregulatory products in veterinary medicine, which are found in abundance in tree greens.

The beneficial properties of tree greens containing carotene, chlorophyll, xanthophyll, proteins, polysaccharides, nucleic acids, flavonoids, amino acids, vitamins K, E, C and other substances that play a significant role in metabolism and in the synthesis of a number of new vitamins in the body do not cause doubts [17, 18].

Pine needles contain iron, manganese, copper, zinc, cobalt, potassium, sodium, calcium and other micro- and macroelements. The high cobalt content in the needles explains the therapeutic effect of feeding it to cattle suffering from tabes. In addition, the needles contain resinous substances, essential oils and phytoncides, which have a bacteriostatic effect on the intestinal microflora.

The purpose of the present invention is to increase the efficiency of correction of iron deficiency anemia in dairy calves.

A method for correcting iron deficiency anemia in dairy calves, characterized by the fact that from 5 days of age a feed additive containing a pine-energy additive, flaxseed, feed yeast and an active carbon additive is introduced into the main diet at the following ratio of components in mass. %:

pine-energy supplement 80.0 flax-seed 3.0 feed yeast 7.0 active carbon additive 10.0,

in this case, the feed additive is administered in an amount of 15.0 ml per head for 14 days without intervals, by drinking 50-100 ml with water, once a day.

The use of the proposed method for correcting hyperfibrinogenemia in biology and veterinary medicine will help to avoid many vascular complications in newborn calves with anemia, improve the health of the herd, reduce mortality, increase weight gain, improve the quality and volume of meat products obtained and subsequently obtain healthy offspring from these animals.

To conduct research, we used a feed additive for young cattle [19].

The duration of feeding the studied feed additive was 42 days in various doses: 5.0, 10.0 and 15.0 ml per head in courses for 14 days without intervals. The supplement was given to experimental animals from 5 days of age (n=10) by drinking with a small volume of water (50-100 ml), once a day, in addition to the main diet. The scientific experiment was carried out on breeding heifers of the black-and-white Holstein breed on the basis of JSC Agrokombinat breeding plant "Krasnogorsky", branch of Pasegovo, Kirovo-Chepetsk district, from March to May 2023. Calves from the dairy period are raised using the cold method and kept in individual houses in an unheated room in a “veal village”.

For comparative analysis, a control group of animals (n=T0) was formed according to the principle of analogue pairs, which was on the main diet during the entire experiment. Basic diet (BR): concentrate feed KK-77 - 10 granules GOST 9268-2015; powdered milk - 30 g; collected milk, 2 liters 3 times a day; warm water every 1.5 hours, 2 liters. In order to prevent IDA, all calves were given injections of the vitamin-mineral preparation Sedimin at a dose of 5.0 ml, intramuscularly, on the 2-3rd day of life, and when symptoms of diarrhea appeared, cellobacterin was given at a dose of 10 g/head per day with mixed feed up to 2 days. one month of age.

The effectiveness of the studied additive was assessed based on a clinical examination of animals in combination with modern laboratory methods. The main methods and techniques used in the course of work: - clinical observation (daily); - thermometry (once a week); - general blood test and serum iron content (4 times: before giving the supplement, on days 14, 28 and 42 when changing the dose).

Hematological and biochemical studies were performed using UR1T-3020 and iMagic-V7 analyzers based on the laboratory for immunobiochemical analysis of biological objects [20].

To differentiate IDA from anemia of parasitic origin, fecal samples were taken from all calves from the rectum and examined by the Fulleborn method according to GOST R 54627-2011 and GOST 25383-82. Parasitological studies were carried out at the diagnostic laboratory of veterinary parasitology. Based on the results of coproscopy, the extent of invasion (EI) was calculated [3, 21].

Clinical examination of experimental animals revealed signs of dyspepsia. Dyspeptic syndrome in calves was characterized by diarrhea, liquid feces of an unpleasant odor, predominantly watery consistency, yellowish or gray in color. Thus, in the control group of animals, the percentage of calves with signs of diarrhea at the beginning of the experiment was 90, after 14 days - 30, after 28 days - 20, and at the end of the experiment - 40%, respectively.

In experimental calves, signs of dyspepsia at the beginning of the experiment were recorded in 100% of animals, then in 20, 10 and 10%, respectively. The thermometry indicators of heifers in the control group varied within the range of 38.2-39.9°C, in the experimental group - 38.1-39.8°C.

Microscopy of feces revealed oocysts of eimeria species Eimeria bovis and Eimeria ellipsoidalis in 82.4 and 17.6% of cases, respectively. In control animals, eimeria oocysts were detected on the 14th day of the study with an EI of 40%, on the 28th day - 50%, at the end of the experiment - 50%. In the experimental group, eimeria oocysts were detected only on the 28th day of the experiment in three calves (EI 30%). It should be noted that diarrheal-dyspeptic syndrome occurred only in calves with an average degree of invasion.

During hematological and biochemical examination of control calves, background parameters of HGB, RBC, WBC, NBT, CPC and Fe were within the lower limit of reference values (Table 1). In dynamics, after 42 days, the main changes in the downward direction are associated with the concentration of serum iron by 12.4% (P<0.05) compared to the 28th day of the experiment.

The background parameters of HGB, RBC, WBC, NBT, CPC and Fe in the experimental group of calves were also within the lower limit of the physiological norm (Table 2). Over time, 14, 28 and 42 days after giving the feed additive at a dose of 5.0, 10.0 and 15.0 ml, a gradual increase in hemoglobin levels was noted by 6.2, 10.7 and 13.6% compared to the background and by 5.1, 3.2 and 5.2% - with control. The number of red blood cells also increased by 29.5 and 34.5% and by 9.6 and 12.6% compared to the initial and control values on days 28 and 42 of the study. With an increase in the amount of hemoglobin and red blood cells, the hematocrit increased slightly.

In dynamics, the level of serum iron concentration in the blood of experimental calves increased by 19.4% (P<0.05) with a supplement dose of 10.0 ml for 14 days and remained almost at the same level with a dose of 15.0 ml until the end of the experiment . Fe concentrations in the blood serum of experimental calves were higher by 15.4, 25.8 and 41.5% of the values of control animals on days 14, 28 and 42 of the experiment.

As for the dynamics of the number of leukocytes, all values fluctuated between 7.50±1.74-8.98±3.56 ×10 ⁹ /l and by the end of the experiment the number of WBC decreased slightly by 2.9%. However, compared to control animals, the number of WBC was higher by 12.4%.

Thus, based on the results of the studies, we can conclude that the use of a feed additive for young cattle and calves from 5-7 days of age eliminates diarrhea syndrome in 90% of cases and helps to increase the level of serum iron concentration within 28-42 days.

Sources of information accepted during the examination of the application:

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Claims (3)

A method for correcting iron deficiency anemia in dairy calves, characterized by the fact that from 5 days of age a feed additive containing a pine-energy additive, flaxseed, feed yeast and an active carbon additive is introduced into the main diet in the following ratio of components in wt.%: pine-energy supplement 80.0 flax-seed 3.0 feed yeast 7.0 active carbon additive 10.0, in this case, the feed additive is administered in an amount of 15.0 ml per head for 14 days without intervals by drinking 50-100 ml with water once a day.