RU2097030C1 - Preparation for aerosol use for control over respiratory illnesses in animals and birds - Google Patents

Abstract

FIELD: veterinary science. SUBSTANCE: preparation has the following components, wt.-%: potassium iodide 0.16-0.82; polyvinyl alcohol 0.56-1.84; triethylene glycol 46.00-12.60; 40% lactic acid 4.00-44.50; hydrochloric acid 0.15-0.50, and water - the rest. EFFECT: enhanced effectiveness of preparation. 2 tbl

Description

 The invention relates to veterinary medicine, in particular to preparations for the aerosol treatment and prevention of respiratory diseases of animals, mainly infectious laryngotracheitis, infectious bronchitis, colibacteriosis, bird pullorosis and calf bronchopneumonia, in livestock (poultry) complexes and farms.

 In the fight against respiratory diseases, such drugs as triethylene glycol, lactic acid, etc. are effective in the form of aerosols (Vashkov V.I. Antimicrobial agents and disinfection methods for infectious diseases, M. 1977, p. 184).

 However, they only disinfect indoor air from pathogens, but do not have a therapeutic effect on the respiratory tract and the microflora in the respiratory organs, which significantly reduces their effectiveness during the spread of the disease. Antibiotics, sulfonamides in the form of aerosols are widely used in the fight against respiratory diseases (Pilipchuk N.S. et al. Aerosol therapy for respiratory diseases, Kiev, 1988, p. 113).

 However, in the conditions of animal husbandry, aerosols have to be generated mainly in large volumes of premises, especially in houses, where thousands, tens of thousands of animals (birds) are kept. Aerosols are suitable here, which would simultaneously disinfect indoor air and sanitize the airways of animals and would be widely available. The same drugs and those close to them are very expensive, often in short supply, so that they can be systematically sprayed in large volumes of premises. In addition, and most importantly, the aerosols of these preparations do not disinfect indoor air and only affect the respiratory organs, without interrupting the airways of the infection.

 The drugs most accessible for mass aerosol use and having the greatest simultaneous disinfecting effect in indoor air and the therapeutic effect in the respiratory tract include halogen-containing. The first place among them is occupied by iodine preparations. Iodine, as the most important microelement, increases the body's defenses, and as the most important antimicrobial component, it acts destructively on all types of pathogenic microflora.

 Known iodine-containing preparation, which includes iodine, potassium iodide, triethylene glycol and lactic acid, used against respiratory diseases (Sokolov V. D. Antimicrobial agents in poultry. M. 1984, S. 159 160). The advantage of this drug over other iodine preparations is that it provides triethylene glycol with lactic acid (40% food grade), which together are excellent solvents of iodine, which allows you to reduce 20 to 25 times more expensive potassium iodide used for this purpose. In addition, triethylene glycol and lactic acid, having an oily consistency, during aerosol spraying create the most stable finely dispersed, dense aerosol mist in rooms and thereby significantly increase the disinfection activity of iodine, excluding its premature crystallization in air and respiratory tract. In addition, triethylene glycol and lactic acid, as noted at the beginning of the description, themselves exhibit a disinfection effect in the air, and in this complex with iodine this effect is mutually increased.

 However, this effective prescription combination of an iodine-containing drug has the following disadvantages. Firstly, the amount of iodine in the preparation is very high and reaches 20-30%. It is by spraying such a concentrated preparation that a relatively good disinfection and inhalation-sanitizing effect is achieved in livestock buildings. Since iodine is the main active ingredient in the drug and the most expensive, in the practice of using aerosols there has always been a major question: how to reduce the consumption of iodine without losing its effectiveness. Secondly, despite the mitigating effect of the triethylene glycol component, iodine, especially at such elevated concentrations, has a rather high irritating effect on the mucous membranes, which limits its wider use, for example, on chickens 1-10 days old, which are most sensitive to irritants. Thirdly, the named composition of the iodine-containing preparation is soluble in water only up to 33% concentration, and then iodine crystallizes in a precipitate. This narrows the scope of the drug only in the framework of aerosol treatments, while there are respiratory diseases such as colibacteriosis, pullorosis, etc. in which the gastrointestinal tract can be affected. However, it is impossible to achieve the desired dilution of the named preparation for vodka, simultaneously with aerosol treatments.

 Closest to the invention is an iodine-containing preparation having the following composition, wt.

Iodine 0.1
Potassium Iodide (Potassium Iodide) 0.3
Polyvinyl alcohol 0.9
Water Else
This composition is approved for use in veterinary medicine (Veterinary law / Ed. By A. D. Tretyakov, vol. 2, M. 1973, p. 83) and is widely used in veterinary practice mainly by the method of feeding and feeding. The effectiveness of the use of this drug in the form of aerosols is proved, for example, by B. Turakulov (abstract of thesis. To the etiology of infectious atrophic rhinitis of pigs. Frunze, 1972, p. 14).

 The advantages of the prototype drug (described in detail in the book by V.O. Mokhnach, “Theoretical Foundations of the Biological Effects of Halide Compounds”, L. 1968, p. 24 25, etc.) consist in the fact that iodine is converted into polyvinyl alcohol from a less active to a more active valency, in the so-called blue iodine, which, in combination with polyvinyl alcohol, almost loses its irritating (cauterizing) properties, acquires complete solubility in biological media and water and has the highest disinfection compared to ordinary iodine and medicinal properties. These advantages allow several times to reduce the concentration of iodine in the preparation and its consumption for processing, not only without losing efficiency, but also increasing it, and unlimited use of blue iodine on any species and age of animals.

 With all the positive qualities listed above, this drug, however, did not enter into the widespread practice of daily aerosol treatments. Its use remains mainly at the level of aerosol chambers and low-volume sections in rooms. In necessary cases, when it is necessary to spray it in large volumes of premises, the power of the aerosol equipment and time are doubled due to large doses of the drug. The reason for this limited use is that in this prototype preparation the content of active iodine is too low (0.1%). This is 200 300 times lower than the amount of molecular iodine that is used in the above analogue preparation (p.2), recommended for aerosol treatments. Such a too low concentration of blue iodine in the preparation does not allow to create a sufficient disinfection and therapeutic-inhalation dose in indoor air. And it is also impossible to increase the concentration of blue iodine in the preparation to the optimal one, since it will precipitate. Neither an increase in polyvinyl alcohol, nor an increase in potassium iodide helps to stabilize blue iodine in the drug above 0.1 0.15%. The drug and freezing temperatures also destroy the drug. In addition, in the practice of using aerosols, a negative effect on the iodine of the pH of the medium in the respiratory tract was revealed, depending on the nature of the pathological changes. It is known that iodine in alkaline media is inactivated and its antimicrobial activity decreases. Such (to one degree or another) unfavorable pH of the medium occurs at certain stages of the disease in the upper and middle respiratory tract of animals, when a mucus-protein mass infected with bacteria accumulates in them. Lactic acid, which is present in the above analogue (before the prototype), as an alkalinity neutralizer in this case is more inert upon contact with it than iodine itself. A decrease in the antimicrobial activity of iodine in alkalizing mucous-protein accumulations in the respiratory tract leads to a decrease in the disinfection and therapeutic effect in these cases. And although in those cases where there is no alkalization in the respiratory tract and the therapeutic effect is high, on average, it decreases on average in the household. A component is needed in the preparation, which would be ahead of iodine in contact with alkaline media, preventing their inactivating effect on iodine.

 The purpose of the invention is the improvement of the therapeutic and prophylactic and economic effect when using the drug in aerosol form against respiratory diseases of animals.

 This is achieved by the fact that in addition to iodine, potassium iodide (potassium iodide), polyvinyl alcohol and water, the new preparation additionally contains triethylene glycol, 40% lactic acid, hydrochloric acid in the following ratio of components, wt.

Iodine 0.50-1.89
Potassium iodide (potassium iodite) 0.16-0.82
Polyvinyl alcohol 0.56-1.84
Triethylene glycol 46.00-12.60
Lactic acid 40% 4.00-44.50
Hydrochloric acid 0.15-0.50
Water up to 100.0
In this preparation, as in its prototype, the main active ingredient is the blue iodine-polyvinyl complex (iodine + polyvinyl alcohol), the effectiveness and degree of applicability depend on the concentration and stability of which. The triethylene glycol introduced into this new composition, which is a solvent of iodine and has an oily consistency, perfectly preserves the ionic dissociation of dissolved iodine in sufficiently high concentrations and eliminates the reverse crystallization process in contact with polyvinyl alcohol. The 40th lactic acid (food), also of an oily consistency, turned out to be an excellent solvent for polyvinyl alcohol (powdered) and its preservation in the solution from coagulation into flakes with increasing iodine concentration. As a result, this combination of components allows, in contrast to the prototype, to increase the concentration of blue iodine 15-20 times to a sufficiently high effective value. The introduction of hydrochloric acid into the preparative composition enhances the ionic stabilization of blue iodine in this composition, especially at sub-zero temperatures and in limiting iodine concentrations, and prevents blue iodine from being inactivated in the resulting alkaline media of the respiratory tract mucous membrane of animals.

 Thus, the antimicrobial activity of the new drug has increased both due to an increase in the concentration of blue iodine in it, as well as due to triethylene glycol, lactic acid and hydrochloric acid, which in themselves are disinfectants in aerosols. In addition, unlike the prototype, the new drug acquired an oily consistency, which, when sprayed, creates the most stable dense fog, where the condensation processes, and hence the withdrawal of the drug to the sediment, are minimized, i.e. significant economic consumption of the drug has been achieved. The economic advantage of the new drug in comparison with the prototype is that it is stable at all natural temperatures, including freezing temperatures, which allows you to store and transport it in the cold season without heating. In addition, an optimally concentrated preparation not only increases the disinfection and therapeutic effect, but also reduces the cost of aerosol treatments, i.e., it requires fewer aerosol devices to spray a more concentrated drug, which means less spray time, less labor for aerosol treatments .

 The proposed new preparation is a homogeneous slightly oily liquid of a dark blue color, miscible with water in all ratios. The drug can be used not only in aerosols, but also by drinking with water, by feeding with food, in cases where the gastrointestinal tract is affected.

 The following are examples of compositions with optimal and extreme values.

 Example 1. The optimal values of the ratio of the starting components in the preparation are as follows, wt.

Iodine 1.58
Potassium Iodide 0.50
Triethylene glycol 12.29
40% lactic acid 23.50
Polyvinyl alcohol 1.21
Hydrochloric acid 0.20
Water Else
Example 2. The limiting values of the ratio of the starting components in the preparation are as follows, wt.

Iodine 0.50 1.89
Potassium iodide (potassium iodite) 0.16 0.82
Polyvinyl alcohol 0.56 1.84
Triethylene glycol 46.00 12.60
40th lactic acid 4.00 44.50
Hydrochloric acid 0.15 0.50
Water Else
The greatest need is for a preparation for aerosol treatments at poultry farms, poultry farms, where respiratory diseases of birds (chicken) are most widespread, infectious laryngotracheitis, infectious bronchitis, colibacteriosis, pullorosis, as well as at calf-growing complexes and farms, in which bronchopneumonia of various etiologies is widespread. Since iodine is detrimental to all types of pathogens in the air and respiratory tract, this iodine-containing preparation will also be effective for other respiratory diseases of other animal species on duck, goose poultry complexes and farms, on complexes and farms for raising lambs, on pig farms, pig farms.

 The drug can be spray aerosolized in pure form or diluted with water in a ratio of 1: 1. Only fine mist with a particle size of 0.5 to 20 microns is effective. The technology of aerosol treatments is the same for all types of animals and preparations: before spraying, the room occupied by animals is tightly closed, ventilation is turned off; spraying is carried out for 5-15 minutes, exposure after spraying is maintained for up to 30 35 minutes, after which ventilation is turned on and the room is ventilated. The total time of aerosol treatment in a closed (without ventilation) room should not exceed 50 minutes, especially in houses, since the lack of oxygen begins to adversely affect. From this it is clear that the lower the concentration of the active substance in the preparation, the more the sprayed dose of the preparation itself is required, which leads to an increase in spraying time beyond the permissible level. To avoid this, increase the number of aerosol generators and sources of compressed air to them, which leads to more expensive aerosol treatments.

Today's most productive aerosol technology in an optimally equipped form can spray a dose of 1 6 ml / m ³ during the above time. The effective sprayed dose of our new preparation is 1-3 ml / m ³ (0.01-0.04 g per iodine). The lower limit dose of 1 1.5 ml / m ³ provides a sufficient disinfection effect in the air and a therapeutic effect in the respiratory tract (with optimal economic condition), regardless of the type of animal and the type of pathogen. The dose can be increased to 2-3 ml / m ³ in advanced (chronic) cases of the disease, which can occur in adult livestock. A further increase in dose no longer provides an increase in effectiveness. When using the prototype drug, in order to reach at least the lower dose limit of a new drug (in terms of blue iodine), it is necessary to spray it at a dose of 12-13 ml / m ³ . But this dose, according to technological and microclimatic capabilities, is sprayed only in two doses with an interval of 1 hour and ventilation after each exposure treatment. It was this achievably best dose that we used for comparative tests with the new drug. To spray this dose, it took 2 times more time and equipment to process. A comparative analysis of the cost of two treatments is presented in table 1.

The above analysis shows that the economic effect of the difference in the cost of one course of aerosol treatments with a new drug, in comparison with the prototype amounted to 5860 rubles. (in prices 1992 1993)
In addition, tests of a new preparation in the form of aerosols against the respiratory diseases listed at the very beginning in the conditions of three broiler poultry farms unsuccessful for these diseases were carried out. Broiler bird is most sensitive and more often affected by these diseases. Given that diseases do not occur more often in their pure form, the treatments were carried out against the most severe mixed forms: infectious laryngotracheitis and colibacteriosis, infectious bronchitis and colibacteriosis, pullorosis and infectious bronchitis. In all experimental and control houses, broilers were kept from the first days until the age of 58 days under identical conditions with the same type of feeding. Then they were handed over to the slaughterhouse for slaughter.

In each experiment and control house with a volume of 4500–5500 m ^3, 19,000–22,000 birds were divided into three equal groups. Everywhere a new drug was sprayed at a dose of 1-1.2 ml / m ³ , and the prototype drug at a dose of 12-13 ml / m ³ . During the treatment, the room was tightly closed, the ventilation was turned off. The exposure after spraying was held for 30 minutes, then the room was entered into normal operation. Processing in all cases was carried out, starting with the first cases of the appearance of patients in all groups, according to the scheme: once a day for 3 days in a row and then the cycle of these treatments was repeated two more times after 3 days of a break and one final treatment. Only 10 treatments in each experimental and control house. The test results were taken into account by the cost of drugs, by the number of dead (fallen) birds from these diseases and the magnitude of the increase in weight (gain). In all experiments, the new drug, in comparison with the prototype and pure control, where no treatments were performed, showed the best result.

 So, in experiments with a mixed (associated) course of infectious laryngotracheitis and colibacteriosis, where the birds were treated at 18-22 days of age (in each room of the same type, 19,000 birds), birds died from this disease by 175 animals and meat was lost (gain) 0.75 c less when processed with a new drug in comparison with the prototype, which amounted to 464900 and 300000 rubles in cost terms, respectively. The economic effect, taking into account the reduction in drug costs (Table 1), amounted to 765,400 rubles.

 In experiments with the associated course of infectious bronchitis and colibacteriosis, where aerosol treatments were carried out from 15-18 days of age (22000 birds in each room of the same type), 203 heads died from the disease and meat (gain) was lost by 0.83 c less processing of a new drug in comparison with the prototype, which amounted to 559400 and 332000 rubles in cost terms, respectively. The economic effect, taking into account the reduction in drug costs, amounted to 891900 rubles.

 In experiments with associated pullorosis and infectious bronchitis, where aerosol treatments were carried out from 5-8 days of age (19000 birds in each room), 138 animals died from the disease and 0.44 c less meat was lost when treated with a new drug in comparison with the prototype, which amounted to 366600 and 176000 rubles, respectively. The economic effect, taking into account the reduction in drug costs, amounted to 543100 rubles.

 In experiments with the associated course of pullorosis and colibacteriosis with lesions of both the respiratory and digestive tracts, where aerosol treatments were carried out from 8 to 11 days of age (19300 birds in each room) and at the same time given a preparation diluted with water with drinking water (for drinking) in a ratio of 1:15, 0.2-0.3 ml per chicken and the corresponding amount of a prototype preparation (undiluted, equal in dose of blue iodine) in a comparative herd of birds died from the disease by 160 goals and lost meat by 0.54 q less when processed ke a new drug in comparison with the prototype, which amounted to 425,100 and 216,000 rubles, respectively. The economic effect (taking into account the drug) amounted to 641600 rubles.

 The average generalized test results for all these diseases of birds are presented for clarity in table 2 per 10,000 heads.

Experiments with bronchopneumonia of calves were carried out on a farm for growing calves for meat. The calves were placed in equal (370 m ³ ) isolated sections of 40 animals (20 diseased and 20 clinically healthy). In two treatment sections, the aerosol of the new preparation was carried out, in two other aerosols of the prototype preparation, and two more groups remained under pure control (no treatment was planned). Doses of drugs, technology and treatment regimes were similar to those described in experiments on poultry, the conditions of feeding and maintenance were the same in all cases. Treatments in all groups began at 3-5 weeks of age, and test results were taken into account in calves at 2.5 months of age. Treatments with a new drug and prototype prevented the death of calves from the disease. However, in the groups treated with the new drug, calves with signs of the disease remained 5 goals less and the loss of weight gain by 1.0 kg less, which amounted to 2530 and 215600 rubles in cost terms in comparison with the prototype. The economic effect, taking into account the reduction in drug costs, amounted to 213840 rubles.

 In groups of birds and calves left under pure control, the disease quickly began to grow and the death of animals and the loss of weight gain sharply increased. Local specialists were forced to apply treatment of these groups to avoid large losses.

 In all cases, the poultry in the cultivated premises was mostly clinically healthy and only a smaller part of them were ill, and the calves were also clinically healthy and sick. Therefore, aerosol treatments on the one hand had a therapeutic effect on patients and at the same time a preventive effect on patients who were not yet ill, protecting them from infection. That is, there was a simultaneous therapeutic and prophylactic effect. Processing modes are provided specifically for a comprehensive effect. The number of treatments by veterinarians can decrease or increase depending on the course of the disease.

 Thus, the objective of the invention is achieved in full: the new drug in comparison with the prototype increases the therapeutic effect in poultry, reducing the death of the bird by an average of 169 goals, meat loss by an average of 0.64 kg per 10,000 birds, and thereby increases economic effect of 716,600 rubles. In a herd of calves, the new drug increases the therapeutic and prophylactic effect by reducing sick calves by 5 goals, reducing meat loss by 1.0 kg per 80 calves, and thereby increasing the economic effect by 213840 rubles. In addition, the economic effect is increased both in poultry farming and in other livestock production due to the reduction in cost of aerosol treatments by 1.5 times.

Claims (1)

 A preparation for aerosol use against respiratory diseases of animals and birds, containing iodine, potassium iodide, polyvinyl alcohol and water, characterized in that it additionally contains triethylene glycol, 40% lactic acid, hydrochloric acid in the following ratio of components, wt. Iodine 0.50 1.89
Potassium iodide 0.16 0.82
Polyvinyl alcohol 0.56 1.84
Triethylene glycol 46.00 12.60
40% lactic acid 4.00 44.50
Hydrochloric acid 0.15 0.50
The rest of the water

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