RU2581929C2 - Biologically active preparation for protecting plants from pests, production method thereof, microcontainer for said preparation, method of making same and method of protecting plants from pests - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: group of inventions relates to protecting plants from pests. Disclosed is a method of producing biologically active preparation for protection of plants, biologically active preparation for protection of plants, method of producing micro containers for method implementation micro container for biologically active preparation and method of protecting plants from pests, where method involves activation of biologically active preparation and its application onto plants. Method of producing biologically active preparation involves introduction of entomopathogenic fungi and liquid phase in micro containers enclosed, decantation of liquid phase and drying micro containers together with entomopathogenic fungi spores. Method of making micro containers involves adding solvent polyisocyanate, stirring obtained solution in aqueous dispersion medium until micro emulsion state, production of microcapsules and heating of microcapsules with perforated shell and forming holes in it.

EFFECT: invention enables minimising the effect of adverse factors on the active substance bio insecticides viability, improved consumer and commercial properties of biologically active preparations during mass use, wider range of bio insecticides application.

10 cl, 16 dwg, 4 ex

Description

FIELD OF THE INVENTION

The present invention relates to the field of plant protection against pests and is intended for use in industrial, scientific purposes, agriculture, horticulture and forestry. In particular, the invention provides a method of protecting plants from pests by treating plants with a biologically active preparation in which the bioinsecticide is placed in a protective microcontainer. The invention also provides the aforementioned biologically active preparation and microcontainer and methods for their preparation and manufacture.

State of the art

The large-scale use of pesticides has a number of significant drawbacks, the most important of which are the emergence of resistant pest populations and environmental pollution. In addition, many years of experience in locust control indicate that insecticides usually provide only a temporary decrease in numbers and severity at their places of application, but in general they can hardly affect dramatically the course of long-term population dynamics. On the contrary, total treatments destabilize the ecological situation due to the extermination of natural enemies and natural epizootics, which lengthens the periods of mass reproduction by several years.

One such method of suppressing harmful phytophages is the microbiological method of protection.

Preparations based on entomopathogenic microorganisms are well known and widely used throughout the world to control the number of locusts. Unlike harsh chemical insecticides that cause irreparable harm to ecosystems and are prohibited by law in water and environmental protection zones, bioinsecticides are substances that do not harm recreational and water protection zones and are safe for warm-blooded animals, including humans, can be used in areas where organic products are produced.

The above problems are widely discussed in numerous publications, for example: in the journal "Agrochemistry", 2010, No. 12, p. 24-28, "The effect of fillers on the biological efficiency of the conidia of the entomopathogenic fungus Beauveria bassiana against locusts in Kazakhstan" by V.Yu. Kryukova et al .; in Lomer C.J., Bateman P.P., Johnson D.L., Lagewald J., Thomas M. Biological control of locusts and grasshoppers // Annu. Rev. Entomol. 2001. V. 46. P. 667-702, and Charnley A.K., Collins S.A. Entomopathogenic fungi and their role in pest control // Environmental and microbial relationships. The Mycota: A comprehensive treatise on fungi as experimental systems for basic and applied research / Eds. C.P. Kubicek, K. Esserand I.S. Druzhinina. Springer, 2007. P. 159-187; Lachininsky A.B., Sergeeva M.G., Childebaev M.K., Chernyakhovsky M.E., Lockwood J.A., Kambulin V.E., Gapparova F.A. “Locusts of Kazakhstan, Central Asia and adjacent territories”, Laramie: MAPA and Un-t. Wyoming, 2002. 387 p.

However, the use of entomopathogenic microorganisms against locusts is associated with a number of difficulties associated with the instability of their action. This is primarily due to such limiting arid climate factors as solar insolation, high temperature and low air humidity. It is known that under the influence of direct sunlight conidia of fungi lose their viability for several hours, which leads to a significant decrease in the effectiveness of mycoinsecticidal biological products. This is stated in the works: Gromovy T.I. "Entomopathogenic fungi in forest protection", Novosibirsk: Nauka, 1982. 80 pp., Inglis G. D., Johnson D. L., Goettel M.S. "Effects of temperature and sunlight on mycosis (Beauveria bassiana) (Hyphomycetes: Sympodulosporae) of grasshoppers under field conditions // Environ. Entomol 1997. V. 26. P. 400-409, Braga GUL Flint SD, Messias CL, Anderson AJ, Roberts DW Effect of UV-B on conidia and germlings of the entomopathogenic hyphomycete Metarhizium anisopliae // Mycol. Res. 2001. V. 105. No. 7. P. 874-882, Braga GUL, Flint SD, Miller CD., Anderson AJ , Roberts DW Variability in response to UV-B among species and strains of Metarhizium isolated from sites at latitudes from 61 ° N to 54 ° S // J. Invertebr. Pathol. 2001. V. 78 P. 98-108, Wraight SP , Inglis GD, Goettel MS Fungi // Field manual of techniques in invertebrate pathology. Application and evaluation of pathogens for control of insects and other invertebrate pests. Springer, 2007. P. 223-248.

Therefore, it seems relevant to search for fillers of protectors of entomopathogenic microorganisms. Several studies have shown the promise of using fillers such as clays, humates, activated carbon, titanium dioxide, zinc oxide, fluorescent whiteners (Tinopal LPW, Blankophor BSU), vegetable and mineral oils, molasses, milk powder, egg albumin, etc. See , for example, works: Inglis GD, Goettel MS, Johnson DL Influence of ultraviolet light protectants on persistence of the entomopathogenic fungus Beauveria bassiana II Biol. Contr. 1995. V 5. No. 4. P. 581-590, Edgington S., Segura H., de La Rosa W., Williams T. Photoprotection of Beauveria bassiana: testing simple formulations for control of the coffee berry borer // Int. J. Pest Manag. 2000. V. 46. No. 3. P. 169-176; Kassa A. Development and testing of mycoinsecticides based on submerged spores and aerial conidia of the ento-mopathogenic fungi Beauveria bassiana and Metarhizium anisopliae (Deuteromycotina: Hyphomycetes) for control of locusts, grasshoppers and storage pests. Doctoral diss. GOttingen: Georg-August-University, 2003.170 p .; Inglis G. D., Goettel M.S., Eriandson M.A., Weaver D.K. Grasshoppers and locusts // Field manual of techniques in invertebrate pathology. Application and evaluation of pathogens for control of insects and other invertebrate pests. Springer, 2007. P. 627-654.

These protectors may vary in their effectiveness depending on the types of micromycetes used, targets and their environment.

Among the whole variety of entomopathogenic microorganisms, one of the most promising groups from the point of view of locust control, as the above studies show, is fungi from a number of anamorphic genera - Metarhizium and Beauveria. As a result of the work, two preparations based on the fungus Metarhizium anisopliae var. Were created and successfully introduced. acridum - Green Muscle ^® (South Africa) and Green Guard ® (Australia), which have high biological efficiency (85-95%) against migratory, desert, Moroccan locusts and fillies. On the basis of B. bassiana in the USA, two experimental locust preparations were created - Mycocide GH ^® and Mycotrol ^® . K. However, tests of these drugs on the territory of the former USSR showed their low efficiency in the climatic conditions of the territories of the former USSR. Analysis of the tests showed that these drugs are extremely sensitive to UV radiation, temperature and humidity. The proposed methods for treating agricultural land as a part of water-oil suspensions, humates, clay, molasses and other widely used fillers do not significantly improve the results of their action and at the same time close the possibility of using such preparations with ultramal spraying.

The present invention is directed to the further development of fillers of protectors of entomopathogenic microorganisms, and in a completely different direction from the prior art described above, which has no closest analogues. The technical solution according to the present invention allows to minimize the influence of negative factors on the viability of the active substance of bioinsecticides, in particular entomopathogenic microorganisms, to improve the consumer and commercial properties of biologically active preparations for mass use, to expand the range of application of bioinsecticides to ultrafine spraying.

Disclosure of invention

The present invention provides a method for producing a biologically active preparation for protecting plants from pests, which consists in introducing a biologically active suspension in the form of fungal spores and a liquid phase into microcontainers and then decanting the liquid phase and drying the microcontainers together with the fungal spores.

As fungi, entomopathogenic fungi can be used, in particular, an entomopathogenic fungus selected from the group consisting of Beauveria bassiana, Pandora neoaphidis, Entomophaga maimaiga, Metharhizium anisopliae var. acridium and Metharhizium anisopliae var. anisopliae and more preferably an entomopathogenic fungus of the species Metharhizium anisopliae var. acridium.

From the above microcontainer, 1 to 100 fungal spores can be introduced.

The present invention also provides a biologically active preparation for protecting plants from pests and diseases obtained by the above method, as well as a method of manufacturing microcontainers for implementing the above method, according to which microcapsules with a shell of a polymeric material and a core of an organic solvent are prepared, microcapsules are heated to a temperature of 300 ° C for perforation of the shell and the formation of holes in it under the influence of vapor pressure of the solvent, while the dimensions of the holes are regulated I am the ratio of the components of the polymeric material of the shell and the change in vapor pressure of the solvent.

In the above method of manufacturing microcontainers, microcapsules can be obtained with a size of from 5 to 500 microns.

As the polymeric material can be used polyurea.

The thickness of the aforementioned shell can be selected from 0.05 to 5 μm.

The dimensions of the above holes can be adjusted to a diameter of at least 5 microns.

The present invention also encompasses the construction of a microcontainer obtained by the above-described method of manufacturing microcontainers, as well as a method of protecting plants from pests, which includes activating the above biologically active preparation in an aqueous medium and applying said preparation to plants.

The present invention consists in the basic idea of using a “programmable properties” microcontainer made of a synthetic polymer in the form of a hollow container with openings for introducing spores as a filler-tread bioinsecticide. Such a microcontainer has the following advantages over known fillers:

1. Dispersion - microcontainer sizes from 1 to 500 microns. You can ask when they are received. No grinding of the filler-tread required. Universality for different disputes.

2. The diameter of the holes in the shell of the filler-tread - can be set upon receipt of the microcontainer for various sizes of spores. Universality for different disputes.

3. Inert polymer of the filler-tread shell with respect to spores and the environment.

4. Biodegradable polymer shell filler-tread, which helps maintain environmental safety.

5. The polymer shell of the filler-tread has protective properties from solar radiation.

6. The polymer shell of the filler-tread practically does not change its properties at temperatures from minus 20 to plus 50 ° C, and the properties of the microcontainer do not change under these conditions.

7. The polymer of the filler-tread is insoluble in water and does not swell in it.

The microcontainer according to the present invention completely protects the bioinsecticide contained therein from harmful UV radiation, maintains the necessary humidity for the life of microorganisms, protects them from high temperatures, has a prolonged predetermined action time and good “sticking” properties. The size of the microcontainers can be agreed with the main manufacturers of equipment for ultra-small spraying.

Ultra-small spraying is a small drop spraying with a preparation (i.e. at least 80% of the preparation is sprayed in the form of drops with a size from 50 to 150 microns) of the treated surface at a rate of up to 5 liters per hectare. Ultra-small spraying ensures good penetration of the drug into the aisles of even thickened crops, a high density of the coating of plants, including the lower part of the leaves, which allows to reduce the consumption of the drug by at least 20-30%, in comparison with other spraying methods.

The use of chemical insecticides is legislatively limited or prohibited in water protection and nature protection zones, where locusts develop. Thus, the creation of a fundamentally new safe biologically active drug will significantly increase the cultivated area and, as a result, prevent a destructive invasion of especially dangerous pests on farmland.

The present invention proposes a direction other than the prior art for the development of fillers for bioinsecticide protectors. It proposes to place bio-insecticide in a microcontainer and thereby effectively protect it from the negative effects of the environment, followed by an adjustable rate of release. The technical solution according to the present invention allows:

1. Reduce by 3.8-4.2 times the effect of UV radiation by placing the spores of the fungus inside the microcontainer, where they will be, and not in a mixture with the filler or on its surface. In the latter case, there is a decrease in the intensity of exposure to UV radiation, for example, in an oil-water solution due to a decrease in the evaporation rate, and in the first case, the fungi conidia themselves are protected directly by the wall of the microcontainer and thereby create the most favorable conditions for their development.

2. Reduce the effect of high temperature, such as soil surface or vegetation. As shown above, a number of authors have shown, by the example of conidia of entomopathogenic fungi, that when the temperature rises, they die before the desired effect occurs. The placement of the bioinsecticide inside the microcontainer creates a kind of thermos that prevents excessive overheating of the active substance. When using a microcontainer, an external temperature of 60-70 ° C is not critical for microorganisms and the death of sprouted conidia on the surface of the container is not critical for the effective operation of the drug.

3. Reduce the influence of humidity factor. At high solar activity and high temperature, intensive evaporation of moisture necessary for the normal development of bioinsecticides occurs. As a result of drying, the conidia of the fungus pass into the spore inactive phase and lose their abilities as a bioinsecticide. For conidia of the fungus when placed inside the microcontainer according to the present invention, with their preliminary soaking in liquid, ideal conditions for the development of microorganisms inside the container are created with an adjustable output of microspores on the surface of the container. In contact with the surface of the microcontainer, pests become infected with spores of entomopathogenic fungi. Due to a predetermined exit speed to the surface of conidia, the biologically active preparation according to the present invention, in contrast to the ones used, has a prolonged effect for several days, while the known chemical and biological insecticides remain active for several hours or, at best, the first day from the time of application , which allows the use of biological products without tight binding to the time frame.

4. To improve the adhesive properties of biologically active preparations for protecting plants from pests by imparting special properties to the walls of the microcontainer. So laboratory studies have shown a significant improvement in the wind resistance of this formulation compared to traditional ones. When it enters the surface of a plant or soil, the preparation according to the present invention does not roll, but is firmly fixed on the surface and, if a pest enters the body, grows there.

5. To increase the weight of a biologically active preparation for protecting plants from pests in comparison with the weight of the active substance of this preparation (for example, conidia of mushrooms), which allows avoiding the fog effect over the treated area during aerial processing, and the ability to set the necessary microcontainer sizes (from 5 to 500 microns) gives an undeniable advantage when using the drug for ultra-small spraying, with minimal use of fluid, which is especially necessary in arid and desert climates. 6. To abandon the traditional world-wide conidial mass production method used by the two-phase cultivation method, when at first deep cultivation is carried out for several days, and then the inoculum is applied to surface carriers in order to accumulate the biomass of the fungus for several weeks. Proposed by the present invention, the methods allow to abandon surface cultivation, requiring significant areas, energy costs and labor. The methods according to the present invention allow the conidial mass of the fungus to be introduced directly from the reactor (fermenter) into the microcontainer with a significant increase in the concentration of the active substance inside the microcontainer compared to the initial one in the solution.

Brief Description of the Drawings

In FIG. 1 shows hollow containers filled with an organic solvent - microcapsules. Microcapsules are made of polyurea, and xylene acts as an organic solvent. The figure shows the diameters of the microcapsules (14.53 microns, 81.48 microns and 122.73 microns).

In FIG. 2-3 show hollow containers with at least one opening - microcontainers. The medium is water.

In FIG. Figure 4 shows microcontainers in the liquid phase at 100x magnification. The diameter of the microcontainer (157.09 microns) and the holes in it (40.40 microns) are also marked on this figure.

In FIG. 5-6 show microcontainers containing conidia of mushrooms at 400x magnification. Figure 5 shows the diameter of the opening of the microcontainer (44.30 μm) and the diameters of the conidia of the mushrooms (4.59 μm and 4.21 μm). In FIG. 6 conidia are marked by arrows.

In FIG. 7 shows microcontainers containing conidia of mushrooms (shown by arrows), placed in the liquid phase with conidia of mushrooms.

In FIG. 8 shows a microcontainer with an opening.

In FIG. Figure 9 presents spores of entomopathogenic fungi in the liquid phase. The spore diameter is from 3.5 to 5 microns. The figure shows the spore diameters (3.65 μm, 3.89 μm and 4.65 μm).

In FIG. 10 shows microcontainers containing conidia of fungi placed in the liquid phase.

In FIG. 11 is a graph of mortality of locust larvae when using a mycoinsecticidal preparation in various formulations. Preparations were used to treat insects on a shaded area.

In FIG. 12 is a graph of mortality of locust larvae using a mycoinsecticidal preparation in various formulations. Preparative forms were used to treat insects in open areas.

In FIG. 13 is a graph of mortality of locust larvae when using a mycoinsecticidal preparation in various formulations. The formulations were processed food with drying in the shaded area.

In FIG. 14 is a graph of mortality of locust larvae using a mycoinsecticidal preparation in various formulations. The formulations were processed food with drying in open areas.

In FIG. 15 is a graph of mortality of locust larvae when using a mycoinsecticidal preparation in various formulations. Preparative forms treated the soil before the direct settlement of insects.

In FIG. Figure 16 shows a mortality chart of locust larvae using a mycoinsecticidal preparation in various formulations. The soil was cultivated with preparative forms, followed by exposure before insect colonization.

SUMMARY OF THE INVENTION

As mentioned above, the essence of the present invention is the creation of a fundamentally new method of obtaining a biologically active preparation for protecting plants from pests, in which the active substance of the said preparation is placed inside the microcontainer.

Thus, the main means for implementing the above method for producing a biologically active preparation for protecting plants from pests are microcontainers, and the present invention also provides a method for the manufacture of such microcontainers, which involves the use of microencapsulation to produce special microcapsules, from which microcontainers are obtained for specific temperature conditions for due to the perforation of the microcapsule shell and the formation of holes in it.

Known methods for producing microcapsules containing solutions of pyrethroid and organophosphorus insecticides in organic solvents, as well as microcapsules containing only organic solvents. In these methods, an insecticide solution or an organic solvent is mixed with a polyfunctional isocyanate, the insecticide being mixed until a homogeneous solution is added, ethylene glycol or polyvinyl alcohol is added to the aqueous solution, stirred at 4700 rpm and 70 ° C for 18 hours to obtain the desired product (see ., for example, UK patent No. 2214080, CL A01N 25/28, 1989). However, such methods are not considered effective enough, since they are laborious. In addition, in these methods, toxic organic compounds are used in the preparation of microcapsules.

There are also known methods for producing microcapsules of preparations for exterminating household insects, based on the preparation of a composition consisting of microcapsules with a core of active insecticidal material, wherein a solution of chlorpyrifos in organic solvents or a method for producing microcapsules containing freons is used as the active insecticidal material. However, in the first case, an insecticide solution is used, and in the second, a thin-walled shell is obtained, which completely collapses when the microcapsules are heated.

The present invention provides a simplified method for producing a microencapsulated solvent by shortening the synthesis time and obtaining a microcapsule shell that is not completely destroyed when heated.

The above method according to the present invention is carried out due to the fact that in the method of producing microcapsules based on the preparation of an aqueous suspension consisting of microcapsules with a core of an organic solvent surrounded by a shell of a polymeric material, polyisocyanate is introduced into the solvent to form microcapsules, after which the resulting solution is mixed in an aqueous dispersion medium containing 0.5% polyvinyl alcohol in distilled water, for 5-20 minutes to obtain a microemulsion with a particle size, equal to 5-500 microns, then to form the shell of the microcapsules, a 10% solution of polyethylene polyamine in water is continuously introduced while reducing the stirring speed; wherein the ratio of polyisocyanate dissolved in the encapsulated solution and polyethylene polyamine dissolved in the aqueous dispersion medium is 1: 1.

In the synthesis of microcapsules use:

Xylene (TU 6-09-3825-88 amend. 1.2)

Colorless transparent liquid; mass fraction of the main substance,% mass., not less than 99.3; density at 20 ° C, g / cm ³ - 0.876-0.880; distillation temperature limits at 760 torr, in which not less than 95% vol. drug - 143-145 ° C; bromine number, in g of bromine per 100 g of the drug, not more than 0.05; the degree of purification on a model scale of not higher than 0.15; fat content is not more than 10.

Butyl acetate - is a colorless transparent liquid with a characteristic odor (GOST 22300-76), the mass fraction of the main substance is not less than 98.3% of the mass .; mass fraction of non-volatiles not more than 0.002% of the mass .; mass fraction of acids (in terms of acetic acid) not more than 0.005% of the mass .; mass fraction of water not more than 0.1% of the mass.

Polyethylene polyamine (PEPA), TU 2413-357-00203447-99 - brown transparent liquid; mass fraction of total nitrogen 30; the presence of chlorion is absent; mass fraction of mineral impurities 0.2; mass fraction of the fraction distilled off at the remainder. pressure of 1.3 kPa (10 mm Hg) in the temperature range:

0.75 ° C no more than traces 1,

from 0.75 ° С to 200 ° С not less than 23.0;

the mass fraction of the bottom residue boiling above 200 ° C is within 65-75; mass fraction of tertiary amino groups is in the range of 5-9; mass fraction of water - no more than 2; mass fraction of acid titrated nitrogen in the range of 19.5-22.0 %%; curing ability - not more than 1.5 hours.

Polyisocyanate - a reddish-brown viscous liquid, crystallizes below 10 ° C; _{boiling point} - 400 ° C; d ²⁰ ₄ - 1.22-1.25; t _isp - 185 ° C.

Polyvinyl alcohol, TU 6-09-4004-67, thermoplastic microcrystalline structure, molar mass of 10-50 thousand; t _{glass transition} - 57 ° C, density - 1.29 g / cm ³ , _{decomposition} t - 220-235 ° C (without melting), soluble in hot water, stable in oils, fats; diluted in acid and alkali.

Receiving microcontainers is carried out in two stages. At the first stage, microcapsules containing an organic solvent are obtained in a known manner, and then a microcontainer is made from these microcapsules at the second stage.

First stage. Obtaining an emulsion of a solution of polyisocyanate and primary shells of microcapsules

1. In solution 1, the polyisocyanate is dissolved.

2. Solution 2 is poured into the emulsifier reactor, mixing is carried out in the middle mode and holding for at least 5 minutes.

3. In a emulsifier reactor, solution 1 is dosed in a thin jet mode.

4. The revolutions of the mixer are increased to obtain emulsion droplets of the required size (during control it is carried out by sampling, examined under a microscope), the mixture is kept under these conditions for at least 7 minutes until the micro picture remains constant.

5. To the resulting mixture, solution 3 is slowly instilled (in 20 minutes).

6. The rotation speed of the mixer is reduced to a quarter of the maximum, and everything is kept under stirring for at least 10 minutes.

Second stage. Microcapsule shell extension

7. Stirring is stopped, and the resulting mass is poured into a storage reactor with 200 ml of water. Then again, slow mixing and tracking to prevent the formation of sediment are carried out, after which the resulting mass (Fig. 1) is poured into a storage tank.

To obtain large quantities of microcapsules, the first stage is carried out repeatedly with the discharge of the obtained product into the storage reactor, with 200 ml of water being added each time.

Example 2. The manufacture of microcontainers

The aqueous phase is removed from the resulting microcapsule suspension by decantation and vacuum filtration. Then the wet microcapsules are dried at a temperature of 55-75 ° C under flowing conditions to a constant weight.

The dried microcapsules are placed in a heating cabinet at a temperature of 200-300 ° C and maintained under these conditions with periodic stirring to constant weight. As a result, the solvent is removed from the microcapsules, perforating (breaking) their shell with the formation of microcontainers (Fig. 2, 3, 4 and 8).

The size of the microcontainer opening obtained by breaking through the solvent vapor from inside the spherical microcapsule is determined by the following interdependent parameters:

1. The strength of the shell of the microcapsule, which is determined by its thickness and diameter of the microcapsule, as well as the strength characteristics of the material of the shell, that is, the chemical composition of the polymer.

2. The value of the pressure of the saturated vapor of the solvent inside the microcapsule, and the rate of increase of this pressure when heating the microcapsule.

With the same diameter of the microcapsules and the same shell thickness, to obtain relatively small holes, high pressure of saturated vapor of the solvent and slow heating of the microcapsule are necessary. For large openings, low solvent saturated vapor pressure and slow microcapsule heating.

The shell material can be from the same polymer (for example, polyurea), but of a different composition and from any other polymer, then the parameters for the saturated vapor pressure and its growth rate will change when the microcapsule is heated to obtain a hole of a given size.

If microcapsules of polyurea of a certain composition have a diameter of 50 μm, a shell thickness of 0.5 μm, and xylene acts as a solvent, then heating them from room temperature to 240 ° C in 5 minutes will give an opening diameter of 5 μm, while heating in 30 minutes - 15 microns.

If you change only the composition of the polyurea, the above heating procedures will already give other hole diameters. If you change the thickness of the shell, then change the size of the holes. Also, the size of the holes will vary depending on the type of polymer and solvent.

Therefore, when receiving microcontainers, the diameters of the holes in them are laid in advance, based on the initial parameters of the microcapsules - the strength of the shell of the microcapsule and the pressure of saturated steam, that is, during the synthesis of microcapsules, when they are calculated in advance. At the same time, it is taken into account that the hole cannot be larger than the diameter of the microcapsule, and it makes no sense to receive holes with a diameter smaller than the size of the fungus spore. A microcontainer with a diameter less than the spore diameter is not needed.

Example 3. Obtaining a biologically active drug

1 liter of biologically active suspension in the form of spores of fungi and the liquid phase is placed in a container of 2 liters (Fig. 9), equipped with a mixing device with a propeller stirrer, and mixed at a speed of 300-700 rpm.

Then, micro-containers in the amount of 50 grams are dosed in small portions into this container and the resulting mass is mixed for 40-60 minutes. The end of spore introduction into microcontrollers is monitored by the turbidimetric method when a constant optical density is achieved in periodically collected samples of the liquid phase. Microcontainers with spores introduced into them are shown in FIG. 5, 6, 7 and 10.

Then, the aqueous phase is removed from the obtained suspension of microcontainers by the method of decantation and vacuum filtration, and wet microcontainers containing spores are dried at a temperature of 25-45 ° С under flowing conditions to constant weight.

Example 4. Comparative tests of locust mycoinsecticidal preparations in various preparative forms

The purpose of these tests was to assess the dynamics of mortality of herd locusts from fungal infections, depending on the preparative forms of mycoinsecticides of locust preparations.

The studies were conducted on the basis of the following conidia-based formulations Beauveria bassiana (Balsamo-Crivelli) Vuillemin:

1. Aqueous suspension.

2. An oily suspension.

3. Conidia placed in the microcontainer of the present invention.

Studies were carried out on larvae of different ages and adults of Asiatic locust and Italian prus. Untreated locust larvae acted as controls.

Processing was carried out by the following methods:

1. Application of solutions directly to the insect by spraying with a hand spray.

2. Feed processing.

3. Tillage.

The methodology of the experiments

The infectious load was introduced at the rate of 7 · 10 ¹² conidia / ha. The experiments were carried out in closed cages with a fine mesh size of 100 × 100 × 100 cm, located in open and shaded areas. To reduce the wind transfer of conidia of the fungus, the cages were separated by a windproof partition. The number of individuals in one cage was 20 copies. Weather conditions: average air temperature 23-25 ° C to 36 ° C, soil temperature up to 45 ° C, humidity 49-56%, wind from 5 to 15 m / s. Observations were carried out for 30 days.

1. Insect Treatment

Analysis of the mortality rate of the larvae using various preparative forms showed the following results.

In the shaded area

The death of insects was 80-100% on the 25-27 day of experiments for all preparative forms (Fig. 11). It is worth noting that the aqueous emulsion of bioinsecticide is less effective in time compared to the oil suspension and suspensions of microcontainers. So, the death of up to 40% of individuals when treated with an aqueous suspension occurred on days 14-16, and when treated with oil suspensions and suspensions of microcontainers on days 8-9 (Fig. 11).

In open areas

With intense sunlight, the effectiveness of the aqueous suspension fell by more than two times and the insect mortality rate was not more than 40-45% on the 25th day of the experiment (Fig. 12). This fact, most likely, is explained by the fact that during the first 10-16 hours the fungus did not penetrate the body cavity of the insect, and because of the high solar installation, the death of conidia occurred. The second factor may be that, in the absence of adhesive properties in the solution, particles (solution drops) roll off the body of the insect without damaging it. In the case of the use of oil suspensions, the effectiveness of mycoinsecticide decreased on average to a mortality rate of 60-70% (Fig. 12), which is associated with the protective properties of the oil from solar radiation and drying, as well as increased adhesion properties. The results obtained are fully correlated with previous tests (Kryukov V.Yu., Lednev G.R., Levchenko M.V., Yaroslavtseva O.N., Makarov E.N., Baimagambetov E.Zh., Duysembekov B.A. , Glupov VV Effect of fillers on the biological efficiency of the conidia of the entomopathogenic fungus Beauveria bassiana against locusts in Kazakhstan. Agrochemistry, 2010, No. 12, pp. 24-28).

When using the formulation in the form of suspensions of microcontainers, no fundamental differences from experiments conducted in shaded areas were observed. The death of insects on the 25th day of the experiment was 85-100% (Fig. 12), which is explained by the reliable protection of the microorganism in the microcontainer from solar radiation, drying out and the high adhesive properties of the walls of the container, which allows it to fix on the body of the insect.

2. Feed Processing

The processing was carried out with a manual sprayer in several versions:

- processing immediately before placing the feed in the tank,

- processing with drying of the feed for several hours in vivo.

General trends compared to applying mycoinsecticide directly to the insect are a 15–20% reduction in mortality.

Shaded areas

When comparing the effectiveness of the three formulations, one should note the general tendency for insect mortality to decrease by 5-10% for suspensions and up to 25% for aqueous solutions when processing feeds directly when placed in a cage compared to direct processing of an insect. In the case of drying the feed, the effectiveness of the aqueous solution drops by more than two times and amounts to no more than 40-50% (Fig. 13) in comparison with the direct processing of the insect, which is associated with the rolling of the solution drops from the leaves of the feed and their drying. In the case of an oil suspension and the use of emulsions with microcontainers, the decrease in feed efficiency is not so significant and amounts to about 10% (Fig. 13).

In open areas

The effectiveness of the first two preparative forms significantly decreases compared with experiments on shaded areas, which is most likely associated with an increase in solar activity and a higher temperature, which contribute to the rapid drying of the drops. If during the first hours the bioinsecticide does not enter the insect with food or does not linger on its body, then its action ceases due to drying out. Mortality is 40-55% for oil emulsions and about 30% for water emulsions (Fig. 14). An increase in temperature and an increase in the UV factor do not have such significant effects on the suspension with microcontainers, and the mortality rate is 75-80% (Fig. 14).

3. Soil treatment

For the experiments, the following methodology was used:

- direct processing before placing insects,

- soil treatment, holding for 36 hours at the site, followed by locust infestation.

Soil treatment with bioinsecticide primarily means a contact way of spreading the infection. Therefore, the period of effective action of the drug is especially important.

Direct processing before insect colonization

The aqueous solution retains its activity for several hours, while the rate of decrease in efficiency directly depends on the temperature of the soil. The maximum values of the death of locusts amounted to about 30% (Fig. 15). The oil emulsion showed higher mortality rates of up to 50% (Fig. 15). The emulsion with microcontainers showed stable insecticidal properties, and the loss of locusts was 70-75% (Fig. 15).

Aged Soil Processing

Treatment with an aqueous solution - the drug practically does not work, and the death of locusts is single, no epidemiological surge is observed (Fig. 16).

Oil emulsions in open areas are ineffective due to drying of the solution. In the shaded areas, part of the solution remains in active form and locust infection occurs. As a result, the percentage of death is about 30-35% (Fig. 16).

In the case of an emulsion with microcontainers, the effectiveness of the drug does not change. This is due to the fact that the walls of the microcontainer reliably protect microorganisms from the harmful effects of negative factors, and the liquid inside the microcontainer allows them to develop favorably and exit to the outer surface of the microcontainer through predetermined openings. In the case of death of the surface layer, it is replaced by a new highly active one. The percentage of locust death in the case of emulsion with microcontainers is quite high and amounts to 70-75% (Fig. 16).

findings

Testing of three preparative forms of bioinsecticide showed that the most resistant to adverse environmental influences is the formulation in the form of an emulsion with microcontainers. This drug has a long exposure, which allows it to be used as an effective barrier to control locusts. The wide temperature range and resistance to UV radiation allows its use in various climatic zones.

Claims (10)

1. A method of obtaining a biologically active preparation for protecting plants from pests, comprising introducing a biologically active suspension in the form of spores of entomopathogenic fungi and a liquid phase into microcontainers, which are hollow containers, in the form of a shell of synthetic polymer material with at least one a hole for introducing spores, decanting the liquid phase and drying at 25 ÷ 45 ° С of microcontainers together with spores of entomopathogenic fungi under flowing conditions to a constant weight. 2. The method of claim 1, wherein an entomopathogenic fungus selected from the group consisting of Beauveria bassiana, Pandora neoaphidis, Entomophaga maimaiga, Metharhizium anisopliae var. acridium and Metharhizium anisopliae var. anisopliae. 3. The method according to claim 1, wherein the entomopathogenic fungus is an entomopathogenic fungus of the species Metharhizium anisopliae var. acridium. 4. The method according to any one of paragraphs. 1-3, in which from 1 to 100 spores of fungi are introduced into the microcontainer. 5. A biologically active preparation for protecting plants from pests and diseases, obtained by the method according to claims. 1-4. 6. A method of manufacturing microcontainers for implementing the method according to paragraphs. 1-4, comprising introducing into the solvent a polyisocyanate, then mixing the resulting solution in an aqueous dispersion medium containing 0.5% polyvinyl alcohol in distilled water for 5 ÷ 20 minutes to obtain a microemulsion with a particle size of 5 ÷ 500 μm, and for producing microcapsules, the shell of which is formed by the continuous introduction of a 10% solution of polyethylene polyamine in water with a decrease in the stirring speed, with a shell of a polymeric material, which is a polyurea, and a core from an organic solution xylene, and heating the microcapsules to 300 ° C with perforation of their shell and the formation of holes in it under the influence of solvent vapor pressure, the size of the holes being controlled by the ratio of the components of the polymer material of the shell and the variation of the solvent vapor pressure, and the ratio of dissolved in the encapsulated solution polyisocyanate and soluble in an aqueous dispersion medium of polyethylene polyamine take 1: 1. 7. The method according to p. 6, in which the shell thickness is selected from a thickness of 0.05 to 5 microns. 8. The method according to p. 6, in which the size of the holes is adjusted to a diameter of at least 5 microns. 9. The microcontainer for a biologically active preparation according to claim 5, obtained by the method according to PP. 6-8. 10. A method of protecting plants from pests, comprising activating a biologically active preparation according to claim 5 in an aqueous medium and applying said drug to plants.

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