RU2475024C2 - Method of desinsection of livestock houses and insecticidal composition for its implementation - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture. The insecticidal composition for desinsection of livestock houses, which contains fipronil and isopropyl alcohol, and comprises additionally fir oil. All components are taken at a specific ratio.

EFFECT: invention enables to broaden the range of products for desinsection of facilities of veterinary-sanitary inspection and to reduce chemical loading.

2 cl, 4 tbl, 3 ex

Description

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

The economic damage caused by parasitic insect pests to livestock breeding is very large and is reflected in a loss of fatness, an increase in body weight, and a decrease in the resistance of animals to infectious and invasive diseases [1]. The leading method of combating harmful insects is the use of chemicals to destroy them both on the surface of the animal’s body and in livestock buildings [2]. 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-vir”, “FAS”, “Fumitox” [3; four; 5; 6]. However, repeated use of the same drugs leads to the development of insect resistance to them [7; 8].

High insecticidal activity in low concentrations, a minimum consumption rate, long-term residual effect and other features are characteristic of the relatively new substance “fipronil” of the phenylpyrazole group [9].

On the basis of fipronil, insect-acaricidal agents developed by A. A. Smirnov (“Dana”) (RF patent 2181243, 2002) and A. A. Khakhalin (“Insectal-plus”) (RF patent 2340181, 2007) are known. intended for the treatment of arachnoentomiasis or the fight against blood-sucking insects on the surface of the animal’s body.

OOO Yajur-Veda has proposed an insect-acaricidal solution and insect-acaricidal concentrate containing fipronil and alfacipermetrin to kill insects in domestic animals (RF patent 2384065, 2007). According to the description of the invention to the patent, the concentration of fipronil in an insect-acaricin solution for processing animal welfare facilities is 0.1%, and in a working solution prepared from an insect-acaricidal concentrate, 0.03-0.05%. However, this does not take into account the type of processed surfaces: 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 [10] and own research [11]. The use of the same dosages for different types of surfaces can lead to irrational consumption of the drug. In addition, this invention involves an aerosol method of applying an insecticide, the disadvantage of this method when surface treatment is that the bulk of the aerosol particles settles on the floor, a small amount (5-12%) on the walls and only hundredths of the ceiling [12]. According to N. S. Balyberdin (1957), to increase the residual effect of an insecticide sprayed with an aerosol generator, it is necessary to significantly increase the dose of the drug [13].

Research and Development Center Agrovetzashchita LLC (S.V. Engashev) has developed a drug for the treatment and prevention of arachnoentomiasis in mammals, which includes fipronil, imidacloprid and an organic solvent (RF patent 2348398, 2007). The tool can be used to treat animals and their habitats for the treatment and prevention of arachnoentomiasis.

Also known is the “Method for the treatment and prevention of arachnoentomiasis of mammalian animals and the drug for the treatment and prevention of arachnoentomiasis of mammalian animals” (OOO Agrovetzashchita Research and Development Center, S.V. Engashev), which consists in the use of a composition based on fipronil (0.05- 4.5 wt.%) And one of the five regulators of growth and development of insects (0.001-0.2 wt.%) (RF patent 2329797, 2007; RF patent 2329796, 2007).

The aim of the present invention is to expand the range of means for disinsection of objects of veterinary and sanitary supervision and reduce chemical load during its implementation.

This goal is achieved by the use of an insecticidal composition, including fipronil as the active substance, fir oil as a substance that contributes to a longer preservation of the active substance on the surface, and isopropyl alcohol as a solvent.

The method consists in the fact that as an insecticidal composition, a composition containing fipronil, fir oil and isopropyl alcohol is used in the following ratio of components, wt.%:

Fipronil - 0.05-0.4,

Fir oil - 90,

Isopropyl alcohol - the rest.

When processing livestock buildings, the insecticidal composition is used in the form of 0.015-0.15% aqueous emulsions by the method of directed droplet spraying in a volume of at least 50 ml / m ² for processing non-absorbent surfaces (glass, tile, metal, painted surfaces) and 100 ml / m ² for processing absorbent surfaces (wood, brick, plaster).

The invention provides a long, irreversible insecticidal effect, and also reduces the chemical load on livestock buildings due to low dosages and a reduction in the multiplicity of treatments compared with preparations based on pyrethroids.

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.

Fir oil is a mixture of terpenes (pinene, camphene, myrcene, limonene, terpinene, etc.) and terpene alcohols (borneol, cineole, etc.), with a content of the main components of more than 90%. It is a colorless or slightly colored liquid with a coniferous balsamic odor. It has antiseptic properties. Received from needles and young fir branches by steam distillation, produced in the Russian Federation.

The invention is carried out by the following examples.

Example 1. Preparation of an insecticidal composition.

The required amount of fipronil with constant stirring (for example, using a magnetic stirrer) was dissolved in isopropyl alcohol. Then the calculated volumes of fir oil and fipronil dissolved in isopropyl alcohol were combined, while continuing to mix. Components and their ratios are presented in table 1.

Table 1 Insecticidal Ingredients No. Component Amount, wt.% one fipronil 0.05-0.4 2 fir oil 90 3 isopropyl alcohol rest

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

The insecticidal activity of fipronil (4% solution in isopropyl alcohol), fir oil (90% extract) and a mixture of these components were evaluated by dosed contact against laboratory imago flies (Musca domestica). The lethal concentration of SK ₅₀ for individual components and for the mixture was calculated by the method of weighted probit analysis (14). SK ₅₀ estimated mixtures were determined by the formula:

The coefficient of joint action of the components was determined as the ratio of SK ₅₀ of the calculated mixture to SK ₅₀ of the experimental mixture (15).

According to the results of laboratory experiments, SK ₅₀ for fipronil was 0.00018%, for fir oil 8.15%. It is known that the interaction of components in a mixture can be antagonistic, additive and synergistic. To determine the type of interaction between the components of the mixture, the joint action coefficient (KSD) was used, the determination results of which for the analyzed mixtures are presented in Table 2. The KSD values indicate the presence of an additive effect.

table 2 Characterization of mixtures of fipronil and fir oil at different ratios of components The ratio of components in the mixture of fipronil: fir oil (%) CK _{50 calculated} ,% CK _{50 experimental} ,% KSD, units 1: 225 (0.4%: 90%) 0,04477 0,0595 0.75 1: 450 (0.2%: 90%) 0,0891 0.0910 0.98 1: 900 (0.1%: 90%) 0.1765 0.2153 0.82 1: 1800 (0.05%: 90%) 0.3462 0.3707 0.93

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 amounted to SD ₅₀ 12.93, SD ₈₄ 28.0, SD _99.5 95.0 μg / g of insect mass. (fipronil). Based on the studies, we can conclude that the developed composition has an irreversible insecticidal effect. The average effective time of manifestation of insecticidal action (0.89 ± 0.08) h, the composition can be attributed to high-speed.

A comparison was made of the insecticidal activity of the claimed composition against imago flies with the activity of drugs based on pyrethroids by the method of forced contact on test objects according to the "Guidelines ..." [16]. We used glass and wooden test objects with an area of 100 cm ² , onto which a water emulsion (VE) of insecticide was applied in a volume of 0.5 ml and 1 ml, respectively. Based on the results of acute experiments, constant lethal doses of drugs were calculated (CD ₅₀ , CD ₈₄ and CD _99.5 ). 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 shown in table 3, 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. The residual effect of a 4% solution of fipronil on glass and wooden test objects when applying effective concentrations in laboratory conditions lasted 7-8 weeks.

Table 3 Constant effective doses for the claimed composition against adults of Musca domestica on various surfaces in comparison with doses for 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 420 0.0099 0,020 0,061 (0.007 ÷ 0.014) (0.013 ÷ 0.032) (0,033 ÷ 0,112) wooden 210 0.152 0.350 1,317 (0.103 ÷ 0.223) (0.203 ÷ 0.606) (0.633 ÷ 2.738) FAS (D.V. Deltamethrin) glass 240 0.010 0.024 0.109 (0.006 ÷ 0.014) (0.013 ÷ 0.045) (0,048 ÷ 0,253) wooden 320 0.258 0,903 6,519 (0.145 ÷ 0.460) (0.399 ÷ 2.045) (2,184 ÷ 19,461) Breeze (AI Cypermethrin) glass 160 0,032 0.193 3,225 (0.014 ÷ 0.074) (0,060 ÷ 0,618) (0.679 ÷ 15.313) wooden 160 1,498 2,544 5,876 (1,172 ÷ 1,913) (1,799 ÷ 3,596) (3,698 ÷ 9,337)

Example 3. The effectiveness of the disinsection of livestock buildings using the inventive composition against adults Musca domestica.

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. 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.

We tested 0.012-0.015% aqueous emulsions of a new insecticidal composition on non-absorbent surfaces (glass, painted walls, metal surfaces) and 0.13-0.15% aqueous emulsions on absorbent surfaces (brick, wood, plaster) with predominant treatment of non-absorbent surfaces in order to save the drug. The number of insects in the room before treatment was 5.46 thousand individuals / m ² , after disinsection it decreased to 0.60 thousand individuals / m ² . Thus, the insecticidal effectiveness of the proposed method of disinsection of livestock buildings using an insecticidal composition under production conditions was 89%. The residual insecticidal effect persisted for 14 days. Complete restoration of the number of insects was noted on the 20th day after treatment.

When using close concentrations of insecticides of the developed composition and “FAS”, the disinsection of premises against flies by the claimed composition was more effective both in terms of the percentage of insect deaths and the duration of the residual effect (Table 4). The effectiveness of disinsection with the proposed composition and the Breeze preparation practically did not differ (89% and 92%, respectively), however the first was applied at concentrations 2 (for absorbent surfaces) and 4 (for non-absorbent surfaces) times lower than “Breeze” ( table 4).

Table 4 The effectiveness of pest control of livestock buildings using the claimed composition and preparations based on pyrethroids. A drug The surface Concentration,% (by AI) Efficiency,% (insect death) The residual effect, days. The inventive composition (AI Fipronil) lack of absorption. 0.012-0.015 89 fourteen soaking up. 0.13-0.15 FAS (AI Deltamethrin) lack of absorption. 0.01 70 10 soaking up. 0.125 Breeze (AI Cypermethrin) lack of absorption. 0.04 92 fourteen* soaking up. 0.25 * at the same time carried out the delarvation of 0.06% CE drug at a rate of 1-2 l / m ²

Thus, the task is solved.

Sources of information taken into account:

1. Pavlov S.D. The economic effect of protecting animals from midges // Problems of Vet. sanitation. - Tyumen, 1962. - T. 20. - S.172-178.

2. Ruzimuradov A. Organization of measures against bestial flies. // Veterinary medicine. - 1978. - No. 1. - S. 34-36.

3. Bakanova E.I. Modern formulations of insectoacaricides and some aspects of their use // Des. a business. - 2004. - No. 4. - S. 57-63.

4. Dremova V.P. Pyrethrins and synthetic pyrethroids / V.P. Dremova, Yu.P. Volkov // Med. parasitol. - 1987. - No. 4. - S.76-82.

5. Dremova V.P. Medical pest control. Basic principles, tools and methods / V.P. Dremova, L.S. Putintseva, P.E. Khodakov. - Yekaterinburg: Putived, 1999 .-- 320 p.

6. Roslavtseva S.A. Neonicotinoids - a new promising group of insecticides // Agrochemistry. - 2000. - No. 1. - S. 49-52.

7. Pavlov S.D. On 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 20-24 September - Novosibirsk, 2006 .-- S.416-418.

8. Roslavtseva S.A. The danger of the formation of resistance to insectoacaricides in carriers of infectious diseases pathogens // Desdelo. - 2008. - No. 2. - S. 52-56.

9. Kostina M.N. The main directions of improving pest control measures at the present stage. // Des. a business. - 2003. - No. 1. - 51 p.

10. Nabokov V.A. Contact insecticides, their properties and use in medical pest control. - M .: Medgiz, 1958.- 246 p.

11. Levchenko M.A. Comparative evaluation of the effectiveness of new insecticides and spraying equipment in the disinsection of livestock buildings against flies // Diss. for a job. student Ph.D. in the specialty 03.00.19. Tyumen, 2009.

12. Yarny B.C. Aerosols in veterinary medicine. - M .: Kolos, 1972.- 254 p.

13. Balyberdin N.S. Aerosol and wet dispersion method of DDT and HCH for the purpose of disinfection of premises and open areas. // Tr. VNIIVS. - 1957. - T. 12. - S.339-342.

14. Pavlov S.D. Studying the effectiveness of insecticides and the resistance of insect populations to their action by the method of dosed contact (guidelines) / S.D. Pavlov, R.P. Pavlova. - Tyumen: Publishing and printing complex of the Federal State Educational Institution of Higher Professional Education Tyumen State Agricultural Academy, 2005. - 38 p.

15. Smirnov A.A. Screening of insectoacaricides and their mixtures, creation of a composition with a synergistic effect // Veterinary pathology. - 2006. - No. 1. - S.118-121.

16. Nepoklonov A.A. Guidelines for testing pesticides designed to combat animal ectoparasites / A.A. Nepoklonov, G.A. Talanov. - M .: VASKHNIL, 1973. - 48 p.

17. RF patent 2181243, 06.21.2001.

18. RF patent 2340181, 06.03.2007.

19. RF patent 2384065, 12/10/2007.

20. RF patent 2348398, 06/15/2007.

21. RF patent 2329797, 02/09/2007.

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

Claims (2)

1. Insecticidal composition for disinsection of livestock buildings, containing fipronil and isopropyl alcohol, characterized in that it additionally contains fir oil in the following ratio of components, wt.%:
Fipronil 0.05-0.4 Fir oil 90 Isopropyl alcohol Rest 2. A method of disinsection of livestock buildings, comprising small-droplet directed spraying of livestock buildings with an insecticidal composition, characterized in that a composition containing fipronil, fir oil and isopropyl alcohol is used as an insecticidal composition in the following ratio of components, wt.%:
Fipronil 0.05-0.4 Fir oil 90 Isopropyl alcohol Rest
at the same time, when processing livestock buildings, the insecticidal composition is used in the form of 0.012-0.015% aqueous emulsions in a volume of at least 50 ml / m for processing non-absorbent surfaces and in the form of 0.13-0.15% aqueous emulsions in a volume of not less than 100 ml / m ² for treating absorbent surfaces.