RU2491550C1 - Method of prediction development of respiratory diseases in newborn calves - Google Patents

Abstract

FIELD: veterinary medicine.

SUBSTANCE: method provides for blood drawing in calves within 24 hours after birth, determination in the serum of calcium and magnesium content, calculating calcium-magnesium ratio. In case of the values of the calcium-magnesium ratio in the serum less than 3.50:1, the development of respiratory diseases is predicted in calves.

EFFECT: method enables to predict the development of respiratory diseases in newborn calves at early stages.

8 tbl, 2 ex

Description

The invention relates to the field of veterinary medicine and for predicting the development of respiratory diseases in newborn calves.

Respiratory diseases of young cattle are widespread, cause great economic damage and reduce the profitability of livestock.

In the development of respiratory diseases involved bacteria, viruses, mycoplasmas and other microorganisms in various combinations [1]. The above pathogens often play the role of the final effector of the disease, the development of which is initially determined by various kinds of conditions, such as external stress factors, impaired physiological regulation mechanisms, oxidative stress, and a decrease in the resistance of the animal organism [1, 2].

Of the respiratory diseases of calves, tracheitis, bronchitis and bronchopneumonia are most often recorded [1, 3].

Bronchitis is an inflammation of the mucous and submucous membranes of the bronchi. With the passage of bronchitis are acute and chronic. Depending on the localization of the pathological process in the bronchi of one size or another, macrobronchitis is distinguished, when the inflammatory process is localized in large bronchi, microbronchitis, when small bronchi are inflamed, and diffuse bronchitis, when inflammation spreads throughout the bronchial tree. Depending on the nature of the inflammatory exudate, bronchitis can be catarrhal, fibrinous, purulent, putrefactive and hemorrhagic [1, 3].

Tracheitis is an inflammation of the mucous membrane of the trachea. In animals, in most cases, it is registered not as an independent disease, but as a complication of laryngitis (laryngotracheitis) or bronchitis (tracheobronchitis).

The inflammatory process, starting in the bronchi, passes from the mucous membrane of the bronchi to the alveoli.

Bronchopneumonia is an inflammation of the bronchi and lungs, accompanied by the formation of catarrhal exudate, which fills the lumen of the bronchi and alveolar cavity. Bronchopneumonia refers to focal pneumonia and is characterized by lobular spread of the process [3]. First, the bronchi, bronchioles and lobules are affected, after which the process can cover several lobules, segments and lobes of the lungs (small focal and confluent pneumonia).

Tracheobronchitis and bronchopneumonia are recorded in calves mainly from two weeks to 2-3 months of age [3].

Among respiratory diseases of calves of viral etiology, parainfluenza-3 (PG-3), infectious rhinotracheitis (IRT), viral diarrhea-mucous membrane disease (VD-BS), respiratory syncytial (PC) and adenovirus infection, which often occur as mixed pathology and manifest keratoconjunctivitis, rhinitis, tracheitis, bronchitis, catarrhal bronchopneumonia, often turning into interstitial with complications of conditionally pathogenic microflora [1].

A known method for the diagnosis of respiratory diseases based on the results of clinical, radiological and laboratory studies [1, 3]. In case of parainfluenza-3, infectious rhinotracheitis, viral diarrhea, mucous membrane disease, respiratory syncytial and adenovirus infections, serological, virological and (or) molecular genetic studies are carried out, and in case of complications by bronchopneumonia, bacteriological studies are also carried out [1]. However, this method does not allow to detect the subclinical course of respiratory diseases.

A known method for the early diagnosis of respiratory diseases, based on recording on magnetic tape the voice of an animal and determining its spectral composition [4]. The ratio of the spectra judges the functional state of the respiratory system of the animal, and the low spectral bands and the distribution of signal intensity in these bands indicate a specific type of disease. The disadvantage of this method is the need to use special equipment - a microphone, processing unit, registration, display and control, as well as the difficulty of decoding the audio recording in the presence of incidental acoustic noise.

A known method for the early diagnosis of tracheobronchitis in newborn calves, including palpation of the last tracheal ring [5]. With an increase in sensitivity during palpation in calves, a cough is recorded, which makes it possible to diagnose an early manifestation of tracheobronchitis. The disadvantage of this method is that the palpation of the last tracheal ring does not allow to detect increased sensitivity of the mucous membrane of the bronchi, and to diagnose tracheobronchitis in the earlier stages of the disease.

There is a method of early diagnosis of tracheobronchitis in calves, based on the reaction of the animal to the intravenous administration of a 0.6% hydrogen peroxide solution in a 0.9% sodium chloride solution at a dose of 0.4 ml per kg of body weight [6]. In the event of a cough reaction, 1-7 minutes after the administration of this solution, tracheobronchitis is diagnosed. The method allows to detect increased sensitivity of the mucous membrane of the trachea and bronchi in the early stages of the disease, even before the development of its clinical signs.

The closest technical solution is a method for diagnosing and predicting bronchopneumonia in calves, based on the detection of dysproteinemia [7]. The main disadvantage of this method is that it does not allow to predict the development of bronchopneumonia in newborn calves in the early stages of postnatal development.

The technical result of the invention is early prediction of the development of respiratory diseases in newborn calves.

The technical result is achieved by taking blood from calves within 24 hours after birth, determining serum calcium and magnesium and calculating the calcium-magnesium ratio. When the calcium-magnesium ratio in the blood serum is less than 3.50: 1, the development of respiratory diseases is predicted in calves.

It is known that calcium and magnesium regulate many physiological functions in the body, while their metabolism is interconnected. Cations of calcium and magnesium are involved in the regulation of neuromuscular excitability, heart rate, osteogenesis processes, and regulate the permeability of cell membranes. It is believed that magnesium, acting as a physiological calcium antagonist, competes with it for voltage-dependent and receptor-directed channels. An increase in the magnesium content in the cytosol blocks the centripetal current of calcium, reduces the centrifugal transfer of sodium, and controls the duration of the action potential, affecting the potassium channels [8, 9]. Magnesium is involved in the regulation of mucociliary clearance, the exchange of phosphorergic compounds, and is part of various enzyme systems [9, 10].

It has been established that a violation of calcium-magnesium homeostasis is a risk factor for the development of bronchial asthma in people, contribute to the formation of bronchial hyperreactivity syndrome and determines the severity of the disease [8]. The role of disorders of homeostasis of calcium and magnesium cations in the pathogenesis of chronic obstructive pulmonary disease [10] and community-acquired pneumonia [11] has been established.

The essence of the method is illustrated by examples.

Example 1

Justification for predicting the development of respiratory diseases in newborn calves.

On the farm, long-term dysfunctional for respiratory diseases, often occurring in the form of bronchitis and bronchopneumonia, 20 newborn calves were picked up.

Animals on the 1st, 3rd, 7th, 14th, 21st and 30th days of life took blood, nasal and tracheal swabs for laboratory research. In the blood (serum), the content of calcium, magnesium, total protein and protein fractions, total immunoglobulin, the activity of γ-glutamyl transferase, the content of glucose, lactic (lactate) and pyruvic (pyruvate) acids, malondialdehyde were determined. The calcium-magnesium ratio in blood serum was calculated, and the ratio of lactate / pyruvate in the blood was used to assess the state of acidosis in newborn calves. Bacteriological and molecular genetic (for mycoplasmosis) studies of nasal and tracheal washes were performed. To assess the intensity of colostral immunity, serological studies of the blood serum of calves and their mothers were performed for the presence of specific antibodies to pathogens PG-3, IRT, VD-BS, RS infection and adenovirus.

In the first 1.5-2 hours after birth, the calves were determined the level of vitality: the time of realization of a confident standing posture, the appearance of a sucking reflex was taken into account, body temperature, heart rate and respiratory movements, the presence of wheezing, shortness of breath, the color of visible mucous membranes, muscle tone were determined . For one and a half months of life, animals were monitored daily. Body temperature (T), heart rate (HR) and respiratory movements (NPV), the state of visible mucous membranes, appetite, sensitivity of the larynx, trachea and intercostal spaces during palpation, the appearance and nature of cough, wheezing, shortness of breath, nasal discharge were determined. To assess the function of external respiration in calves, spirometry was performed: the tidal volume (BD) and the minute volume of respiration (MOD) were determined.

Depending on the level of viability, the time of appearance of the first clinical signs of respiratory pathology and the development of the symptom complex of macro- and microbronchitis in animals, calves were divided into five groups. The first group included calves with reduced viability, sick with microbronchitis (n = 4), the second - viable calves, sick with microbronchitis (n = 4). The third and fourth groups included viable calves infected with macrobronchitis before (n = 3) and after transferring them from the dispensary (n = 5), respectively (Table 1). The fifth group included viable calves that did not develop respiratory diseases throughout the observation period (n = 4).

From the data presented in table 1, it can be seen that in calves of the 1st and 2nd groups who subsequently became ill with microbronchitis, the first clinical signs of the disease were recorded on 5.8 ± 0.48 and 5.8 ± 1.25 days, respectively. At the same time, body temperature, heart rate and respiratory movements, minute volume of respiration and tidal volume in calves with normal (2nd group) and reduced (1st group) vitality at this age did not statistically significantly differ. However, the development of the symptom complex of microbronchitis in calves of the 1st group occurred 8.8 days earlier (P <0.05) than in animals of the 2nd group. At this stage of the disease, calves had a muffled cough, serous-mucous nasal discharge, moist finely bubbling rales, increased sensitivity of the trachea and intercostal spaces during palpation, mixed dyspnea, an increase in the frequency of respiratory movements and heart contractions, an increase in body temperature, a decrease or lack of appetite. The heart rate in calves of the 1st group was 6.1% (P <0.05) lower than in animals of the 2nd group, other clinical and physiological parameters did not statistically significantly differ. Moreover, in animals of the 1st group, the absolute and relative increase in body weight during the first 30 days of life was 0.6 kg (P <0.05) and 4.8%, respectively, less than in calves of the 2nd group. In addition, in the 1st group, the forced slaughter of one calf was recorded.

In viable calves subsequently affected by macrobronchitis in the 3rd and 4th groups, the first clinical signs of the disease were recorded on 5.0 ± 1.53 and 9.4 ± 1.50 days of life, respectively, i.e., calves in the 3rd group fell ill 4.4 days earlier (P <0.05) than in the 4th group. At this stage of the development of the disease, body temperature, heart rate and respiratory movements, minute volume of respiration and tidal volume in the calves of the 3rd and 4th experimental groups did not statistically significantly differ. Animals of the 3rd group got sick even before being transferred from the dispensary, and the macrobronchitis symptom complex developed on average 9.3 days earlier (P <0.05) than calves of the 4th group. The development of macrobronchitis in calves was accompanied by the appearance of a loud, painful cough, dry or wet large-bubbling rales in the trachea and bronchi, and serous-mucous nasal discharge. An increase in tracheal sensitivity during palpation, an increase in heart rate and respiratory movements was noted. The body temperature in calves of the 3rd group was within physiological boundaries, and in animals of the 4th group - subfebrile, a decrease in appetite was not observed.

The physiological parameters of viable calves not affected by respiratory diseases are presented in table 2.

table 2 Age-related dynamics of physiological parameters in healthy calves (5th group) Age, day T, ° C Heart rate in minutes NPV, in minutes MOD, l To ml 1st 38.8 ± 0.06 136.0 ± 4.0 63.5 ± 3.5 13.19 ± 0.92 209.4 ± 18.2 7th 39.0 ± 0.06 103.0 ± 2.9 38.5 ± 0.9 11.60 ± 0.84 301.0 ± 9.8 14th 38.8 ± 0.03 79.3 ± 0.7 30.7 ± 1.8 10.60 ± 1.01 345.0 ± 26.5 21st 39.0 ± 0.05 78.0 ± 4.0 29.7 ± 1.5 13.03 ± 1.24 437.3 ± 20.3 30th 39.1 ± 0.03 82.7 ± 1.3 27.7 ± 2.6 15.03 ± 2.05 540.7 ± 23.4

From the data presented in table 3 it can be seen that in viable calves who did not suffer from respiratory diseases (group 5), on days 14-21 (the development time of the symptom complex of micro- and macrobronchitis in the 2nd, 3rd and 4th group) body temperature, heart rate and respiratory movements were at the optimal physiological level, and tidal volume (breathing depth) was significantly higher (P <0.05) than in animals with microbronchitis and macrobronchitis during the prophylactic period.

An analysis of the results of bacteriological studies of nasal and tracheal washes in experimental calves showed that the microflora of the upper respiratory tract in newborn calves with reduced viability (group 1) did not differ in their species composition from the microflora of viable calves not suffering from respiratory diseases (group 5 ), and was represented by 5 species of microorganisms (Escherichia coli, including enteropathogenic serotypes 02, 08, 09, 026, Enterococcus faecalis, Enterococcus faecium, Staphylococcus epidermidis, Citrobacter diversus). However, in group 1 calves, enteropathogenic Escherichia coli were isolated from nasal swabs in 100% of cases during the entire study period (versus 87.5% in group 5) and in 75% of tracheal swab samples, while in viable calves, not affected by respiratory diseases, Escherichia coli from the trachea were not isolated. In calves of the 1st group, unlike animals of the 5th group, in the first 14 days of life there was an intensive population of not only the nasal cavity, but also the trachea with conditionally pathogenic microorganisms, among which Escherichia coli dominates, including enteropathogenic serotypes circulating on the farm (in 25% of cases isolated in the form of monocultures, in 75% - in association with gram-positive microorganisms: staphilo and enterococci). At the same time, in viable calves without respiratory diseases, only Enterococcus faecium (100%) was found in tracheal washes at the same time. In addition, by the 7th day of life, calves in the 5th group were not infected with pathogenic mycoplasmas, and in the 1st group, 100% of the animals were infected.

All viable calves, subsequently infected with microbronchitis (group 2), were infected with pathogenic mycoplasmas by the 7th day of life. Unlike animals of the 5th group, enteropathogenic Escherichia coli were detected in 100% of cases in the microbiocenosis of their trachea, while the frequency of their isolation from the nasal cavity remained at the level of calves that did not suffer from respiratory diseases. In calves of the 2nd group, in 66.7% of cases, the mucous membrane of the trachea was infected with group D streptococcus (Enterococcus faecalis), while in animals of the 5th group these microorganisms were not isolated from the trachea. At the same time, saprophytic Enterococcus faecium was isolated in 33.3% of cases, against 100% of samples in calves that did not suffer from respiratory diseases.

Thus, in viable calves subsequently affected by microbronchitis (group 2), against the background of 100% infection by pathogenic mycoplasmas by the 7th day of life, the tracheal mucosa was colonized by enteropathogenic Escherichia coli and Enterococcus faecalis. A high level of tracheal mucosal contamination by these pathogens can be considered not only as a protective component of immunity, but also an additional factor in damage to the respiratory tract and lungs, since Escherichia coli lipopolysaccharides have an irritating effect on the mucous membranes and induce the production of pro-inflammatory cytokines.

In calves infected with macrobronchitis before transferring them from the dispensary (group 3), changes in the microbiocenosis of the trachea and nasal cavity revealed changes similar to those described above - 100% infection of the trachea with enteropathogenic Escherichia coli and 40% Enterococcus faecalis; Enterococcus faecium (40% versus 33.3%) was isolated from the trachea somewhat more often than in animals of the 2nd group, but Escherichia coli (57.1% versus 83.3%) was isolated from the nasal cavity.

In calves infected with macrobronchitis after transferring them from the dispensary to rearing (4th group), the species composition of the upper respiratory tract microflora did not differ much from the animals of the 3rd group, except that, in addition to Escherichia coli, Enterococcus faecalis, Enterococcus faecium and In 30% of cases, Staphylococcus epidermidis in nasal washes was secreted by Citrobacter diversus and in 10% by Staphylococcus aureus, and infection with pathogenic mycoplasmas on the 7th day of life was 75% versus 100% in group 3 calves, which can be regarded as a higher level animal body resistance.

The results of serological studies showed that in viable calves who were ill with micro- (2nd group) and macrobronchitis (3rd group) during the prophylactic period, the intensity of colostral immunity to PG-3 and IRT viruses did not differ much from calves with reduced viability. Moreover, if in viable calves not affected by respiratory diseases (group 5), the level of colostral protection to PG-3, ИРТ practically did not change from the 1st to the 14th days of life, then in animals the 2nd and 3rd of the first group, the content of specific antibodies to PG-3 and RTI pathogens decreased by an average of 2.2 times by the 14th day (P <0.05). In calves infected with macrobronchitis after transferring them from the dispensary to rearing (4th group), the intensity of colostral immunity to PG-3 and IRT pathogens in the first 14 days of life did not significantly differ from animals of the 5th group, and to PG-3 virus up to 7 days of age was even slightly higher.

In addition to colostral antibodies to PG-3 and RTI viruses, specific antibodies to the causative agents of VD-BS, RS infection, and adenovirus were found in calf blood serums, although their content was significantly lower than to PG-3 and IRT, and the level of seropositivity with age of calves decreased. The presence of specific antibodies to VD-BS, RS-infection and adenovirus in the blood serum of daily calves obtained from cows that have not been vaccinated against these infections indicates the circulation of these pathogens among farm animals. The participation of VD-BS viruses and RS-infection in the etiology of respiratory diseases of calves is indicated by seropositivity by the 30th day of life in 5 out of 16 diseased animals that were previously seronegative for these infections.

In calves with reduced viability, subsequently affected by microbronchitis (group 1), antibodies to VD-BS and RS infection were detected in only 50% of cases on the first day of life, indicating a low level of their colostral protection against these pathogens. With 100% seropositivity of mother cows for VD-BS and RS infection, a satisfactory level of colostral protection in calves for VD-BS was only on the 1st day of life (82%), and for RS-infection - up to 7- mi of day age (92-100%), which subsequently led to infection of animals with these viruses.

Thus, the tension of colostral immunity in experimental calves of different groups already significantly varied on the first day of life, which affected the formation of microbiocenosis of not only the gastrointestinal tract, but also the respiratory tract, and, ultimately, determined the development of bacterial and viral infections. Not only in animals with reduced viability, but also in viable calves infected with micro- and macrobronchitis during the prophylactic period, the intensity of colostral immunity in the first days of life was lower than in individuals that remained healthy until the end of the observation (group 5) and were ill macrobronchitis at a later date (4th group). In general, 55% of the animals under observation (25% with reduced viability, 30% of viable animals with micro- and macrobronchitis during the prophylactic period) showed violations of the humoral status, which are the background for the development of both gastrointestinal and respiratory pathologies . Against the background of colostral immunodeficiency in calves of groups 1-4, a viral-bacterial mixed infection developed due to enteropathogenic Escherichia coli (serotype 08, 09, 02, 026, 0115), Enterococcus faecalis, Citrobacter diversus, pathogenic mycoplasmas, and also VD viruses BS and MS infections.

Data on the content of calcium and magnesium in the blood serum of newborn calves are presented in table 3.

From table 3 it can be seen that in the daily age, the calcium content in the blood serum of the calves of the experimental groups did not statistically significantly differ, and the magnesium content in all animals subsequently affected by micro- (1st and 2nd group) and macrobronchitis (3- I and the 4th group) were higher than those remaining healthy (5th group). Thus, the highest serum magnesium content in the daily age was observed in animals with reduced viability, subsequently infected with microbronchitis (group 1) - 1.08 ± 0.07 mmol / L, which is 40.3% more (P <0 , 05) than in viable calves who did not suffer from respiratory diseases (group 5). In calves of the 2nd, 3rd and 4th groups, the level of magnesium in the blood serum was higher than in animals of the 5th group by 28.6, 24.7 and 28.6% (P <0.05), respectively . As a result, the calcium-magnesium ratio in calves of the 5th group was higher compared to animals of the 1st and 2nd groups - by 39.2 and 27.3% (P <0.05), and the 3rd and 4th group 1 - by 21.9 and 15.8% (P <0.05), respectively. At 3 days of age, the highest values of the calcium-magnesium ratio in blood serum were also observed in calves of the 5th group - 3.95 ± 0.02, which is 32.1 and 36.7% (P <0.05) higher compared with animals of the 1st and 2nd groups, and by 35.7 and 17.9% (P <0.05) - of the 3rd and 4th groups, respectively.

By the 7th day of life, the serum calcium content did not change significantly compared to the daily age, while the magnesium content in calves with reduced viability and viable animals that were infected with micro- and macrobronchitis in the prophylactic period decreased by 17.6, 12 , 1 and 3.1% (P <0.05), respectively, in individuals infected with macrobronchitis in a later period, remained unchanged, while those remaining healthy (group 5) increased by 20.8% (P < 0.05). As a result, the calcium-magnesium ratio in blood serum in calves of the 1st and 2nd groups increased by 19.0 and 6.5% compared with the daily age, respectively, in the 3rd and 4th groups - remained unchanged and in the 5th group it increased by 20.9% (P <0.05).

Correlation analysis showed the presence of statistically significant relationships between the level of calcium-magnesium ratio in blood serum at the age of 24 hours and indicators of the function of external respiration in calves - values of the minute volume of breathing (r = + 0.81, P <0.05) and respiratory rate ( r = + 0.69, P <0.05), the time of occurrence of the sucking reflex (r = -0.39, P <0.05) and a confident standing position (r = -0.37, P <0.05) . Data on the time of occurrence of the sucking reflex and confident posture of standing, as well as the main physiological indicators in the first 1.5-2 hours after birth in experimental calves are presented in table 4. At 3 days of age, the presence of reliable relationships between the magnitude of the calcium-magnesium ratio was established in blood serum and minute respiratory volume (r = + 0.71, P <0.05), tidal volume (r = + 0.66, P <0.05), serum total immunoglobulins (r = + 0 , 41, P <0.05) and γ-globulins (r = + 0.40, P <0.05), as well as the value of the ratio of lactate / pyruvate in the blood (r = -0.41, P <0.05) - an indicator of the acid-base state and oxygen homeostasis in the newborn [12].

From the data presented in table 4, it is seen that in viable calves not affected by respiratory diseases (group 5), a confident standing position was previously recorded not only in comparison with calves with reduced viability (group 1), but with viable calves subsequently affected by micro- (2nd group) and macrobronchitis (3rd and 4th groups), and the sucking reflex appeared earlier than in calves in the 1st and 2nd groups by an average of 31.5 and 13.5 minutes (P <0.05), respectively. The presence of correlations between the level of calcium-magnesium ratio in blood serum and the time of occurrence of the sucking reflex and a confident standing position confirms the leading role of these cations (and their ratio in the blood) in the regulation of neuromuscular conduction and muscle tone in newborn calves.

It is known that a reliable sign of oxygen deficiency in the body of a newborn is a high level of blood lactate [12].

From the data presented in table 5, it can be seen that, at the age of 24, the blood lactate content in calves with reduced viability (group 1) and viable animals with micro- and macrobronchitis during the prophylactic period (2nd and 3rd group), was higher than that of calves not affected by respiratory diseases (group 5), by 136.3, 65.3 and 48.4% (P <0.05), respectively. In viable calves infected with macrobronchitis after transferring them from the dispensary to rearing (4th group), the content of lactic acid in the blood at the daily age from the animals of the 5th group did not differ significantly. At the same time, the content of pyruvic acid in the blood of all calves who subsequently became ill with respiratory diseases was lower than in animals that remained healthy by 57.1, 44.0, 44.4 and 52.1%, respectively, in the 1st, 2nd, 3rd and 4th groups (P <0.05). Moreover, the ratio of lactate / pyruvate in the blood was naturally higher in comparison with animals that did not suffer from respiratory diseases, in calves of the 1st and 2nd groups 3.79 and 2.11 times, in the 3rd and 4th groups - 2.02 and 1.52 times, respectively (P <0.05). The same picture persisted on the 3rd day of life: the ratio of lactate / pyruvate in the blood of calves with normal (2nd group) and reduced (1st <group) vitality, subsequently affected by microbronchitis, exceeded the level in animals that remained healthy (5th group), 1.43 and 2.39 times, respectively (P <0.05). In calves of the 3rd and 4th groups, who had macrobronchitis before and, respectively, after transferring them from the dispensary to rearing, the lactate / pyruvate ratio in the blood exceeded the level in animals without respiratory diseases (5th group), in 1, 67 and 1.13 times, respectively (P <0.05). The high level of lactic acid and the ratio of lactate / pyruvate in the blood of calves who subsequently became sick with respiratory diseases, indicates that they have severe hypoxia and acidosis in 1-3 days of life. At the same time, favorable conditions are created for oxidative reactions to proceed according to the acid-dependent mechanism with the formation of toxic derivatives, which make an additional contribution to an increase in the concentration of protons in the blood. Thus, the content of malondialdehyde in the blood of calves of the 1st, 2nd, 3rd and 4th groups on the 3rd day of life was higher by 55.4, 33.9, 40.2 and 69.6% (P <0.05), respectively, in relation to animals not infected with respiratory diseases (5th group). It has been shown that excessive accumulation of toxic products in the body resulting from the breakdown of hydroperoxides inhibits the molecular structure of humoral immunity factors of protein nature that circulate in the body and leads to a decrease in the resistance of animals [13]. By the 7th day of life, the content of lactic acid in the blood of calves who subsequently became ill with respiratory diseases decreased slightly compared with the daily age, however, a high level of the lactate / pyruvate ratio remained, mainly due to a deficiency of pyruvic acid.

It is known that in conditions of prolonged hypoxia and acidosis, in the absence of adequate respiratory and metabolic compensation, the transport of colostral immunoglobulins and the formation of passive immunity are disturbed in newborn calves [12].

The content of total immunoglobulins in serum and the activity of γ-glutamyltransferase (GTT) - a marker of the intensity of absorption of colostral immunoglobulins from the intestines in calves [14] - are presented in table 6.

From table 6 it is seen that in viable calves that did not have respiratory diseases (group 5), one day after birth, the level of total immunoglobulins in blood serum was higher than in animals with reduced viability (group 1) - 3.47 times (P <0.05), and with viable calves infected with micro- and macrobronchitis in the prophylactic period (2nd and 3rd groups) - 2.45 and 1.73 times (P <0 , 05), respectively, and also higher than in animals infected with macrobronchitis after transferring them from the dispensary to rearing (4th group) - 1.82 times and (P <0.05). A more intense transport of immunoglobulins in calves of the 5th group is evidenced by the level of activity of γ-glutamyltransferase in blood serum, which exceeds the average values in animals of the 1st and 2nd groups - by 2.95 and 11.96 times (P <0.05 ), Of the 3rd and 4th groups - 7.23 and 2.05 times (P <0.05), respectively. On the 3rd day of life, in calves not affected by respiratory diseases (group 5), the activity of γ-glutamyltransferase in blood serum remained higher than in animals with reduced viability (group 1) - 1.97 times (P <0.05), as well as viable calves infected with micro- and macrobronchitis in the prophylactic period (2nd and 3rd groups) - 10.28 and 7.63 times (P <0.05), respectively as well as macrobronchitis after transferring them from the dispensary to rearing (4th group) - 2.20 times (P <0.05). A higher absorption rate of colostral immunoglobulins from the intestines in viable calves not affected by respiratory diseases (group 5) is also confirmed by a significant difference (P <0.05) in the level of total protein on the 1st day of life - by 23.2% higher than in animals with reduced viability and from 9.5% (in the 4th group) to 30.0% (in the 2nd group) - compared with viable calves, subsequently affected by macro- and microbronchitis, by 3- and day - by 30.7% and from 12.4 to 31.8%, respectively (P <0.05), as well as the titer of antibodies to antigens of pathogens PG-3 and IR T (P <0.05). The relatively high activity of γ-glutamyl transferase in calves with reduced viability on the 1st and 3rd day of life can be explained by their use of hyperimmune serum against pasteurellosis, salmonellosis, Escherichiosis, PG-3 and ИРТ in accordance with the technology adopted in this farm, in while viable animals this serum was not used. On the 7th day of life, the level of total immunoglobulins in the blood serum of calves infected with micro- and macrobronchitis during the prophylactic period (groups 2 and 3) decreased by 18.03 and 22.04% compared with the daily age ( P <0.05), respectively, which is probably associated with the consumption of immunoglobulins in the antigen-antibody reaction and their subsequent utilization by phagocytes, at the same time in animals infected with macrobronchitis in a later period (4th group) and in individuals remaining healthy (5th group) - increased by 14.33% (P <0.05) or remained unchanged.

From the data presented in table 7, it is seen that physiological (transient) hyperventilation is characteristic of newborn calves in the first days of life. It is known that transient hyperventilation is aimed at eliminating metabolic acidosis in a newborn, removing fetal pulmonary fluid and expanding the lungs [12, 15].

In viable calves not affected by respiratory diseases (group 5), and in animals subsequently affected by macrobronchitis (groups 3 and 4), transient hyperventilation at 1-3 days of life led to lung expansion, which was manifested by an increase in tidal volume (depth of breath) in a newborn with a constant value of MOD. In calves with normal (2nd group) and reduced viability (1st group), subsequently affected by microbronchitis, the period of physiological adaptation was longer (up to 7 days), and the tidal volume did not change significantly compared to the daily age, which indicates incomplete expansion and low aeration of the lungs. The presence of linear relationships between the level of calcium-magnesium ratio in blood serum and indicators of the function of external respiration in calves - values of the minute volume of breathing (r = + 0.81, P <0.05) and respiratory rate (r = + 0.69, P <0.05) on the 1st day and MOD (r = + 0.71, P <0.05) and DO (r = + 0.66, P <0.05) on the 3rd day of life - indicates the important role of calcium-magnesium homeostasis in the regulation of physiological adaptation of the newborn and the transition to pulmonary respiration.

In all calves subsequently affected by micro- and macrobronchitis, electrolyte and, in particular, calcium-magnesium homeostasis was observed on the first day of life, probably due to prenatal hypoxia [9], which led to a violation of neuromuscular conduction and muscle tone in animals and was manifested by the later appearance of the sucking reflex and its weak severity. The low intensity of the sucking reflex, its later manifestation, as well as impaired absorption of colostral immunoglobulins from the intestine under conditions of pronounced and prolonged (more than 48 hours) postpartum respiratory metabolic acidosis with its inadequate respiratory and metabolic compensation, led to impaired formation of passive immunity and the development of an immunodeficiency state in a newborn, which is the background for the development of respiratory diseases.

Example 2

Justification of effectiveness.

On the farm, long-term dysfunctional for respiratory diseases, often occurring in the form of bronchitis and bronchopneumonia, 32 newborn calves were selected. Blood was taken from the calves within 24 hours after birth, serum calcium and magnesium were determined, and the calcium-magnesium ratio was calculated. The animals were kept under clinical observation for a month and a half: they determined body temperature, heart rate and respiratory movements, assessed the state of visible mucous membranes, appetite, sensitivity of the larynx, trachea and intercostal spaces during palpation, time of occurrence and nature of cough, wheezing, shortness of breath, nasal discharge.

The research results are presented in table 8.

Table 8 Verification of the effectiveness of the proposed method Indicator Calcium Magnesium Ratio: <3.50: 1 > 3.50: 1 The number of calves, goals (%) 25 (100) 7 (100) Of these, fell ill with respiratory diseases, including: 25 (100) - - Macrobronchitis: 9 (36) - The first symptoms of the disease, age (day) 7.0 ± 0.41 - The development of the symptom complex of the disease, age (day) 15.2 ± 0.57 - - Microbronchitis: 12 (48) - The first symptoms of the disease, age (day) 6.7 ± 0.36 - The development of the symptom complex of the disease, age (day) 15.8 ± 0.37 - - Bronchopneumonia: 4 (16) - The first symptoms of the disease, age (day) 7.3 ± 0.85 - The development of the symptom complex of the disease, age (day) 29.8 ± 2.14 -

From the data presented in table 8, it is seen that of 25 calves with a calcium-magnesium ratio in the blood serum within 24 hours after birth below 3.50: 1, 25 (100%) animals fell ill with respiratory diseases. Including macrobronchitis - 9 (36%), microbronchitis - 12 (48%), bronchopneumonia - 4 (16%) calves. The first clinical signs of macrobronchitis in calves were detected on 7.0 ± 0.41 days, microbronchitis - 6.7 ± 0.36 and bronchopneumonia - on 7.3 ± 0.85 days of life. The development of the symptom complex of macrobronchitis, microbronchitis, and bronchopneumonia was recorded at 15.2 ± 0.57, 15.8 ± 0.37, and 29.8 ± 2.14 days after birth, respectively.

Of the 7 calves in which the calcium-magnesium ratio in the blood serum within 24 hours after birth was higher than 3.50: 1, not one animal fell ill during the month and a half of observation.

The experiments showed the effectiveness and feasibility of the proposed method. By the magnitude of the calcium-magnesium ratio in the blood serum within 24 hours after birth in calves, it is possible to predict the development of respiratory diseases and conduct timely treatment and preventive measures.

Information sources

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Claims (1)

A method for predicting the development of respiratory diseases in newborn calves, including taking blood from calves, characterized in that blood is taken within 24 hours after birth, the serum calcium and magnesium are determined, the calcium-magnesium ratio is calculated, and in the case of calcium values a magnesium ratio in blood serum less than 3.50: 1, in calves, the development of respiratory diseases is predicted.