RU2464782C1 - Method of disinsection of livestock buildings - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture. The method of disinsection of livestock buildings, which includes processing of livestock buildings by method of directional atomising with insecticidal composition which consists of fipronil, phenol-free coal-bearing kreoline and acetone. All components are taken at a specific ratio. And during processing of livestock buildings the insecticidal composition is used as 0.005-0.2% aqueous emulsions in an amount of at least 50 ml/m² for processing non-absorbing surfaces - glass, tile, metal, painted surfaces, and at least 100 ml/m² for processing absorbing surfaces - wood, brick, plaster.

EFFECT: invention enables to develop an effective method of disinsection of livestock buildings at extending the range of action on pests.

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Description

The invention relates to the field of disinfection of livestock buildings and can be used in the field of veterinary medicine and livestock.

Insects are widespread in nature. In agriculture, they play an important role. A significant number of them live near animals. It has been proven that from the attack of a large number of insects (vultures, flies), cows reduce milk production to 30%, and young animals do not gain weight gain [1, 2, 3].

The harm caused by insects consists mainly of veterinary and economic indicators and lies in the fact that they are ectoparasites and carriers of pathogens of many infectious and invasive diseases [4].

The need to combat arthropods dictates the need to develop and introduce into production new, modern means of pest control [5, 6]. To date, a large number of insecticides of various formulations based on synthetic pyrethroids (permethrin, deltamethrin, cypermethrin, fenvalerate), neonicotinoids (imidacloprid, thiamethoxam, acetamipride), etc., for example, Aqua-Vir, have been studied and recommended for use for controlling insects. ”,“ Arsenal ”,“ Bazan ”,“ Biorin ”,“ Deltatsid ”,“ Inta-virus ”,“ FAS ”,“ Fumitox ”[5; 6; 7; 8; 9]. However, repeated use of the same drugs leads to the development of insect resistance to them [10; eleven].

Coalless phenolic creole has a strong disinfectant, antiseptic and antiparasitic effect. It is used for psoroptosis of animals for therapeutic and prophylactic purposes. They are used for preventive and forced disinfection, disinfestation, disacification, disinfestation of livestock and poultry facilities, equipment, implements, items for caring for animals, for refueling mats and barriers. For the treatment of infected and purulent wounds, cuts, hoof creases, and also used to treat burns, biting midges, purulent conjunctivitis, eczema of parasitic origin.

Known insecticide and acaricidal drug (RF patent 2150829, 2000, ceased action), which includes creolin and the active substance synthetic pyrethroid (or a mixture of pyrethroids). The drug is intended for the treatment of plants or animals against ectoparasites. Also known is the acaricidal preparation Creohin-Leptocide containing the active substance cypermethrin and creolin (RF patent 2105549, 1998).

However, long-term use of drugs with creolin, in which pyrethroids are the active principle, against insects causes resistance in their populations [12], which requires an increase in drug consumption rates and the number of treatments [13, 14]. Therefore, the use of pesticides from other groups with a different mechanism of action is promising.

High insecticidal activity in low concentrations, a minimum consumption rate, long-term residual effect and other features are characteristic of the substance “fipronil” of the phenylpyrazole group [15].

On the basis of fipronil, the insecticaricides “Dana” (patent of the Russian Federation 2181243, 2002), “Insectal-plus” (patent of the Russian Federation 2340181, 2007), insecticaricidal solution and insectoacaricidal composition concentrate (patent of the Russian Federation 2384065, 2007), drug are known for the treatment and prevention of arachnoentomoses of mammalian animals (RF patent 2348398, 2007) and a method for the treatment and prevention of arachno-entomoses of mammalian animals and a drug for the treatment and prevention of arachno-entomoses of mammalian animals (RF patent 2329797, 2007; RF patent 2329796 , 2007). In the above means and methods, we did not find a composition containing fipronil and creolin.

The aim of the present invention is to develop an effective method of disinsection of livestock buildings while expanding the spectrum of action on harmful insects, including those resistant to pyrethroid drugs.

The objective of the invention, in particular the method of disinsection of livestock buildings, is solved by the fact that in the method of disinsection of livestock buildings, which involves treating livestock buildings by the method of directed droplet spraying with an insecticidal composition, according to the invention, an composition containing acetone as a solvent is used as the solvent a binder base with weak insecticidal properties, phenol-free coal creolin, as active ingredient, effective against pyrethroid resistant insects fipronil, with the following component ratio, wt.%:

Fipronil - 0.025-0.5,

Coalless phenolic creole - 90,

Acetone is the rest.

Fipronil is an insecticide from the group of phenylpyrazoles of contact and intestinal action with a long-lasting effect. The substance is registered on the territory of the Russian Federation. It is an odorless white powder.

Phenolic-free coal creolin has an insecticidal, antiseptic, antiparasitic effect. It is a mixture of coal oil, rosin, sodium ichthyol, neonol and water. In appearance it is an oily liquid, transparent in a thin layer, with the smell of coal oil, from dark brown to black-brown. It forms a stable emulsion of finely white or milky gray color with water. It is made in the territory of the Russian Federation.

According to the invention, when processing livestock buildings, the type of surface to be treated is taken into account and an insecticidal composition is used in the form of 0.005-0.2% aqueous emulsions in a volume of at least 50 ml / m ² for processing non-absorbent surfaces (glass, tile, metal, painted surfaces) and not less than 100 ml / m ² for processing absorbent surfaces (wood, brick, plaster).

The technical result of the invention is to obtain an effective method of disinsection of livestock buildings while expanding the spectrum of action on harmful insects, including those resistant to pyrethroid drugs.

The invention is carried out by the following examples.

Example 1. Preparation of an insecticidal composition

The required amount of fipronil is weighed and, with constant stirring (for example, using a magnetic stirrer), dissolved in acetone. Then, the calculated volumes of creolin and fipronil dissolved in acetone are combined, while continuing to mix. The prepared mixture is poured into 1-2 liter plastic bottles. Components and their ratios are presented in table 1:

Table 1 Insecticidal Ingredients No. Component Amount, wt.% one Fipronil 0.025-0.5 2 Phenolic phenol free creole 90 3 Acetone rest

Example 2. Insecticidal activity of the claimed composition against imago Musca domestica in the laboratory

The insecticidal activity of a mixture of fipronil and phenol-free creole was evaluated using dosed contact against the adult flies (Musca domestica) of a laboratory culture. The lethal concentration of SK ₅₀ for the active substance (fipronil) was calculated by the method of weighted probit analysis [16], table 2.

table 2 CK ₅₀ (by AI) of mixtures of fipronil and creolin with different ratios of components The ratio of components in the mixture of fipronil: creolin phenolic free coal (%) The number of insects in the experiment CK ₅₀ % 1: 180 (0.5%: 90%) 360 0,00034 1: 900 (0.1%: 90%) 360 0,00021 1: 1800 (0.05%: 90%) 360 0.00014 1: 3600 (0.025%: 90%) 260 0.00010

According to the results of laboratory tests of the insecticidal activity of the claimed composition, lethal doses of the agent for flies of the laboratory culture averaged CD ₅₀ 14.0, CD ₈₄ 36.0, CD _99.5 179.0 μg / g of insect mass. (fipronil). The developed composition has an irreversible insecticidal effect.

Example 3. Evaluation of the sensitivity of the imago Musca domestica laboratory culture and natural population to pyrethroid drugs and the claimed composition

In laboratory conditions, a comparison was made of the insecticidal activity of the claimed composition against the imago flies of laboratory and natural populations with the activity of drugs based on pyrethroids by the method of dosed contact according to the “Methodological guidelines ...” [16], table 3.

Table 3 The sensitivity of the Musca domestica imago of laboratory culture and the natural population to pyrethroid drugs and the claimed composition A drug The number of insects in the experiment DM, μg ai / g insect mass Resistance indicator SD ₅₀ SD ₈₄ SD _99.5 Laboratory culture The inventive composition (AI Fipronil) 180 14.0 36.0 179.0 - FAS (AI Deltamethrin) 240 0.31 1.05 7.43 - Samarovka insecticide (d.v. cypermethrin) 160 2.85 8.00 40.40 - Natural population The inventive composition (D.V. 180 16,0 35.0 192.0 1,1 fipronil) FAS (AI Deltamethrin) 240 1.00 2.72 13.19 3.2 Samarovka insecticide (d.v. cypermethrin) 230 7.50 29.60 255.75 2.6

From the table it follows that the sensitivity of the flies of the laboratory culture and the natural population to the claimed composition does not differ. The sensitivity of flies of the natural population to pyrethroid drugs is lower than that of laboratory culture flies, which indicates the development of the process of resistance of natural flies to pyrethroids.

Example 4. The study of the insecticidal activity of the claimed composition and preparations based on pyrethroids against imago Musca domestica on various surfaces

In laboratory conditions, a comparison was made of the insecticidal activity of the claimed composition against adult flies with the activity of drugs based on pyrethroids by the method of forced contact on test objects according to the “Methodological guidelines ...” [17]. Glass and wooden test objects with an area of 100 cm ^{2 were used} , onto which a water emulsion (VE) of insecticide was applied in a volume of 0.5 ml and 1 ml, respectively (table 4).

Table 4 Insecticidal efficacy of the claimed composition against Musca domestica imago on various surfaces in comparison with preparations based on pyrethroids (mg ai / 100 cm ² ) A drug The surface The number of insects in the experiment SD ₅₀ SD ₈₄ SD _99.5 The inventive composition (AI Fipronil) glass 180 0.0085 (0.0067 ÷ 0.0107) 0.013 (0.0095 ÷ 0.0183) 0.026 (0.017 ÷ 0.041) wooden 210 0.116 (0.008 ÷ 0.177) 0.255 (0.141 ÷ 0.461) 0.882 (0.399 ÷ 1.946) FAS (AI Deltamethrin) glass 240 0.010 (0.006 ÷ 0.014) 0.024 (0.013 ÷ 0.045) 0.109 (0.048 ÷ 0.253) wooden 320 0.258 (0.145 ÷ 0.460) 0.903 (0.399 ÷ 2.045) 6.519 (2.184 ÷ 19.461) Samarovka insecticide (d.v. cypermethrin) glass 420 0.020 (0.010 ÷ 0.040) 0.088 (0.034 ÷ 0.234) 0.926 (0.253 ÷ 3.397) wooden 240 0.320 (0.150 ÷ 0.690) 1.670 (0.570 ÷ 4.880) 22,430 (5,33 ÷ 94,51)

To determine the residual insecticidal effect of funds on surfaces, insect contacting was carried out for the first 7 days after treatment of test objects daily, and subsequently with an interval of 6-7 days. Flies of 3-5 days of age were used for experiments.

From the data given in table 4, it is seen that the developed composition for insecticidal action on surfaces is not inferior to the well-known highly effective drugs. Its residual insecticidal effect on glass and wooden test objects at the level of 60-100% (depending on the dose of the active substance) lasted 10-12 weeks.

Example 5. The study of the effectiveness of the proposed method of disinsection of livestock buildings

Production tests of the proposed composition were carried out in the Federal State Unitary Enterprise Uchkhoz of the Tyumen region. We processed the internal walls, windows, and the entrance gates of the pigsty with an aqueous emulsion of the product using an Oleo-Mac sprayer. In this case, the type of processed surfaces was taken into account: absorbent (wood, plaster, etc.) or non-absorbent (glass, metal, tile, etc.), effective dosages for which may differ by an order of magnitude according to published data [18] and our own research [19]. The use of the same dosages for different types of surfaces can lead to irrational consumption of the drug, therefore, in production conditions, we applied concentrations of the inventive composition CK _99.5 , calculated according to the results of laboratory experiments for two types of surfaces: absorbent and non-absorbent.

From Example 2: SD _99.5 for glass surfaces was 0.026 mg ai / 100 cm ² (upper limit 0.041), which corresponds to 0.0052% (upper limit 0.0082%) of an aqueous emulsion. For the convenience of preparing working emulsions under production conditions, these values were rounded to 0.005-0.01%. SD _99.5 for wood surfaces was 0.882 mg ai / 100 cm ² (upper limit of 1.946), which corresponds to 0.088% (upper limit of 0.195%) of an aqueous emulsion. For the convenience of preparing working emulsions under production conditions, these values were rounded to 0.1-0.2%.

Thus, in the production, 0.005-0.010% aqueous emulsions were tested on non-absorbent surfaces (glass, painted walls, metal surfaces) and 0.1-0.2% aqueous emulsions on absorbent surfaces (brick, wood, plaster) with predominant processing non-absorbent surfaces in order to save the drug.

To account for the number of flies, they were caught during the day on sticky sheets 10 × 50 cm in size, located at 8 reference points in the room, and the average number of individuals per 1 m ^{2 of the} surface was calculated. The number of adult insects was taken into account for three days before disinfestation and after until their numbers were completely restored in the premises. The effectiveness of pest control was expressed in absolute numbers and in percent. The residual effect was considered effective until the number of insects was reduced by 70% or more.

The number of insects in the room before treatment was 6.2 thousand individuals / m ² , after disinsection it decreased to 0.56 thousand individuals / m. Thus, the insecticidal effectiveness of the claimed composition in a production environment was 91%. The residual insecticidal effect persisted for 14 days. Complete restoration of the number of insects was noted on the 20th day after treatment. Thus, the task is solved.

Information sources

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10. Pavlov S.D. About the resistance of insects of the gnus and housefly complex to the action of modern insecticides. / S.D. Pavlov, R.P. Pavlova, S.M. Mavlyutov. // Mat. VII Interregional meeting of entomologists of Siberia and the Far East in the framework of the Siberian Zoological Conference September 20-24. - Novosibirsk, 2006.- S. 416-418.

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12. Sokolyanskaya M.P. Esterase mechanisms of resistance formation in a housefly (Musca Domestica) to insecticides of various chemical classes. / M.P. Sokolyanskaya, D.V. Amirkhanov. // Agricultural chemistry. - 2008. - No. 7. - S. 56-61.

13. Lineva V.A. The appearance of house flies resistant to DDT and HCH. / V.A. Lineva, V.P. Okulov. // Honey. parasitology. - 1952. - No. 3. - S.334-336.

14. Zakharenko V.A. Strategy to overcome pesticide resistance of pests. // The current state of the problem of resistance of pests, pathogens and weeds to pesticides in Russia and neighboring countries at the turn of the XXI century: Materials of the IX meeting, December 20-22. 2002, St. Petersburg.- SPb .: 2002. - S.8-9.

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25. RF patent 2329796, 02/09/2007.

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27. RF patent 2105549, 02.27.1998.

Claims (1)

The method of disinfection of livestock buildings, including the processing of livestock buildings by the method of directional small-drop spraying with an insecticidal composition, which consists of fipronil, phenol-free creole and acetone in the following ratio, wt.%:
Fipronil 0.025-0.5 Phenolic phenol free creole 90 Acetone Rest
at the same time, when processing livestock buildings, the insecticidal composition is used in the form of 0.005-0.2% aqueous emulsions in a volume of at least 50 ml / m ² for processing non-absorbent surfaces - glass, tile, metal, painted surfaces and at least 100 ml / m ² for processing absorbent surfaces - wood, brick, plaster.