RU2330673C1 - Method of production of anti-infective agent - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to anti-infective materials (agents) and methods of production thereof, characterised by biocompatibility with animal or human body liquids and tissues. Invention concerns method of production of anti-infective agent, production of anti-infective agent implying modification of inorganic mineral with silico- and alumooxycompounds, namely, Na-shaped bentonite, inorganic metal salts in polar solvent, followed by bentonite keeping in salt solution, isolation of promodified bentonite from solution and drying at temperature not higher 100°C. Before being modified bentonite is enriched with Na+ ions through processing with 3-10% aqueous solution of chloride sodium with following washing and filtering of produced semiproduct thereafter modified by 10-20% inorganic metal salts solution represented with silver nitrate or copper sulphate. Modified bentonite is kept in specified salt solutions within 12-24 hour. Then promodified bentonite is cleared from sodium salts through washing and filtration. After being dried made agent is milled to particle dispersion 20-150 nm. Thus inorganic mineral are processed with specified solutions in ratio, weight fraction bentonite:solution, as 1: (10-40).

EFFECT: production of agent with higher anti-infective efficiency using simple and cheap methods and materials.

7 cl, 6 ex

Description

The invention relates to veterinary medicine and medicine, in particular to antimicrobial materials (preparations) and methods for their preparation, having biocompatibility with body fluids and tissues of an animal or human.

The antimicrobial effects of metals such as Ag, Au, Pt, Pd, Cu, and Zn are widely known in medical practice and veterinary medicine (see H.E., Morton. Pseudomonas in Disinfection, Sterilization and Preservation, ed. SS Block, Lea and Febider 1977 and N. Grier Silver and Its Compounds in Disinfection, Sterilization and Preservation, ed. SS Block, Lea and Febiger, 1977).

Soluble inorganic and organic silver salts are used to prevent and treat microbial infections. Although these compounds are effective as soluble salts, they do not provide long-term protection because they are lost due to leaching or complexation of free silver ions. To solve this problem, these compounds must be renewed at short intervals. Repeated use is not always practicable, especially in cases where permanent or implanted medical devices are used.

To solve the problem of slowing down the process of release of silver ions, various technical solutions are proposed, including:

silver-containing complex compounds with low solubility (see US patent No. 2785153). This technical solution proposes a protein and colloidal silver-containing compound for the manufacture of a cream. However, the effectiveness of the known compounds due to problems associated with adhesion, abrasion resistance and shelf life during storage is limited by its scope, mainly in the form of a cosmetic product;

antimicrobial metallic coatings of silver applied to the surface to be treated, for example, by ion beam deposition. However, these coatings that are resistant to solutions do not provide a sufficient antimicrobial effect on them, which indicates the ineffective activation of the release of silver ions in solution.

From the technical solution according to patent RU 2131269 (WO 94046003/14), publ. 06/10/1999 it follows that the solution to the technical problem of increasing the activation of the release of silver ions and other antimicrobial metals (Au, Pt, Pd, Cu, Sn, Sb, Bi and Zn) in solutions can be realized by the presence of these metals in the crystal lattice significant linear, point defects, leading to surface irregularities and structural inhomogeneities at the nanometer level. Applicants offer various modified antimicrobial materials and methods for their preparation, in particular:

material containing at least a metal from the group of Ag, Au, Pt, Pd, Jr, Cu, Sn, Sb, Bi, Zn, or their alloy, or their compound and made in the form of nanocrystalline powder, the production process of which is carried out by the method cold machining (grinding, crushing, grinding) at a temperature below the temperature of recrystallization. The resulting antimicrobial powder can be part of creams, gels based on polar solvents (alcohol, water), paints, and also in bioinert materials (polymers, ceramics, etc.) intended for the manufacture of medical devices that interact with body fluids and tissues of an animal or person.

However, to obtain the specified antimicrobial material, it is necessary to develop special modes of machining, including temperature, which makes manufacturing technology more expensive. The resulting material is not a ready-to-use medicine, because the anticipated therapeutic or surgical activity of the antimicrobial effect of this material is realized only when the latter is used as an additive to other components or materials of antimicrobial action, as well as when special antimicrobial agents contain stabilizing agents that prevent oxidation of Ag clusters.

However, from the analysis of the prior art it follows that the effectiveness of antimicrobial activity in the ionic activation of Ag ⁺ , Cu ⁺ , Zn ⁺ does not depend on oxidative processes that occur as a result of storage of antimicrobial drugs and their use in interaction with wound and burn tissues of animals and person.

When analyzing the prior art, it was also found that other types of promising pharmaceutical raw materials for the pharmaceutical industry include natural minerals, for example zeolite, bentonite (in particular, montmorillonite), on the basis of which various therapeutic preparations have been developed, including:

bentonite with iodine (iodobent);

ointment bases containing bentonite and silver particles, capable of absorbing microbial and tissue toxins and not drying to the burn wound, providing access to the antibacterial component (patent RU No. 2233652);

bentonite gels with extracts or infusions of herbs used in medical cosmetics and providing a whitening, enveloping and adsorbing effect. The use of such gels (masks) does not cause allergic reactions and is effective in the treatment of juvenile acne, skin inflammation, sunburn;

bentonite pastes based on colloidal fractions of bentonite in the production of all kinds of pastes, creams, lipsticks and other cosmetics.

The possibilities of using natural minerals as one of the components in the products of the pharmaceutical and cosmetic industries are not technologically limited. In particular, bentonite and zeolite are widely used in the production of detergents, cleaning, bleaching powders, liquids and pastes, emulsions, stable suspensions, anti-corrosion compounds for coating automobiles, as part of technological additives to technical oils for machines and mechanisms. The widespread use of natural minerals is explained by their sorption activity with respect to liquids and metal cations, due to the fact that the structural structure of the crystal lattice of these minerals is characterized by the presence of adsorption zones formed between "packets" of negatively charged aluminum-oxygen, silicon-oxygen compounds.

Traditionally, in the manufacture of pharmaceutical and cosmetic products, the compounding technology of dispersed powders of natural minerals with metal-containing components, mainly silver and copper, is used to improve the immunostimulating, antioxidant and anti-inflammatory properties of drugs (see US Pat. RU No. 2233652; Prince Velhover ES, Romashov FN et al. "The use of copper and its salts in therapeutic prevention. Methodological recommendations." M: Patrice Lumumba University of Peoples' Friendship, 1982). However, as noted above, the presence of dispersed powdered metal-containing components in known preparations is effective in the presence in the antimicrobial compositions of special additives — stabilizers that prevent oxidation of Ag clusters (see, for example, patent RU No. 2233652), which makes the manufacturing process more expensive and limits their use on wound and burn tissues.

When analyzing the prior art relating to pharmaceutical and cosmetic compositions, which include natural minerals and metal-containing components, the technical solution according to patent RU No. 2245151, according to which a method for producing an antimicrobial preparation comprising modifying an inorganic mineral with aluminum-oxygen and silicon-oxygen compounds with a solution of inorganic silver salts.

As a natural mineral, the zeolite of the Kholinsky deposit is used, containing aluminum-oxygen (Al ₂ O ₃ ), silicon-oxygen (SiO ₂ ) compounds, as well as metal compounds Ti, Mn, Mo, Cu, Zn, Pb, Sn, Be, Sr, Ba.

Significant disadvantages of the resulting drug are:

silver nitrate (AgNO ₃ ) is traditionally used to obtain inorganic drugs containing silver. Modification of zeolite with an aqueous solution of silver nitrate and a drying regime leads to the formation of various salts in the resulting preparation on the external surfaces of zeolite particles, in particular sodium nitrate (NaNO ₃ ), as well as nitrogen oxides (NO _x ), which, when interacting with infected wounds, are irritating effect on the skin;

characteristic of crystalline natural zeolite structure is the presence of adsorption-pore cavities Limited penetration ability, and therefore formed by the thermal decomposition of silver nitrate (AgNO _3), silver ions (Ag ⁺⁾ are placed, preferably, on the outer surfaces of the dispersed zeolite particles. When interacting with solutions and tissues of a living organism, the ion exchange process at a surface arrangement of silver is accelerated, which reduces the prolonged effect of ion exchange during the processing of solutions and tissues of living organisms;

the above features of the crystalline structure of natural zeolites, characterized by reduced penetration of adsorption pore cavities, reduce the effectiveness of using the known drug for antimicrobial treatment of zones with deep violations of the integrity of the skin or mucous membrane.

The closest technical solution to the claimed is an antimicrobial composition, the method of preparation of which consists in the modification of an inorganic mineral with silicon and aluminum compounds, namely Na-form bentonite with inorganic metal salts in a polar solvent, in the subsequent exposure of bentonite in a salt solution, in the removal of modified bentonite from a solution followed by drying at a temperature not exceeding 100 ° C (see application JP 2000281516 (MATSUSHITA ELECTRIC IND CO LTD), publ. 10.10.2000).

In this technical solution for obtaining antimicrobial unlike previously given patent №2245151 use natural mineral bentonite in Na-form shape (montmorillonite), which is modified complex inorganic salt, in particular K (Ag (S ₂ O ₃₎ in a polar solvent (water), which, when using the drug, leads to a decrease in its irritating effect on the skin, to an improvement in the biocompatibility of the drug with the tissues of a living organism, and to an improvement in the absorption of wound exudate.

However, to obtain an antimicrobial preparation (application EPO № JP 1990081127) use expensive silver salt that increases the cost and complicates the process of producing an antimicrobial drug, wherein at modification of bentonite complex salt K (Ag (S ₂ O ₃₎ basically holds the ion exchange between cations K ^{+ of the} named salt on Na ⁺ bentonite cations, and in this case, Ag ⁺ ions are still bound in the salt complex, which reduces their antimicrobial activity in wound and burn treatment zones.

Given these circumstances, the applicant was faced with the task of manufacturing a less expensive, biocompatible, effective therapeutically ready-to-use antimicrobial preparation of inorganic origin, ensuring the achievement of a technical result to improve antimicrobial effectiveness with prolonged action of the drug on the treated areas of a living organism.

To solve this problem, a method for producing an antimicrobial preparation is proposed, which consists in modifying an inorganic mineral with silicon and aluminum-oxygen compounds, namely Na-form bentonite, inorganic metal salts in a polar solvent, in the subsequent exposure of bentonite in a salt solution, in removing the modified bentonite from the solution followed by drying at a temperature not higher than 100 ° C, while the invention before modification bentonite enriched by ions of Na ⁺ by treating it with 3-10% water solution m of sodium chloride, followed by washing and filtering the resulting semi-finished product, which is then modified with a 10-20% solution of inorganic metal salts, which are used as silver nitrate or copper sulfate, the modified bentonite is exposed to the indicated salt solutions for 12-24 hours, and then purification of the modified bentonite from sodium salts by washing and filtering it and, after drying, the resulting preparation is crushed to a particle size of 20-150 nm, while the treatment of the inorganic mineral GOVERNMENTAL produce solutions with a ratio, parts by weight - bentonite: solution as 1: (10-40).

According to the invention, the exposure of bentonite during enrichment with Na ⁺ ions and its modification with a solution of inorganic salts of silver nitrate or copper sulfate is carried out at a temperature of 60-90 ° C.

According to the invention, water or a water-alcohol solution is used as the polar solvent.

According to the invention, to obtain an antimicrobial preparation, a mixture of dispersed bentonite powders with silver ions and copper ions is used in the following ratio, parts by weight:

dispersed bentonite powder with copper ions: dispersed bentonite powder with silver ions as 1: (3-4).

According to the invention, to obtain an antimicrobial preparation, dispersed bentonite powder with silver or copper ions or a mixture of dispersed bentonite powders with silver and copper ions are used when compounding them in polar solvents in the following weight ratio:

dispersed powder or mixture of powders: polar solvent as 1: (5-10).

According to the invention, a dispersed bentonite powder with silver ions or copper ions or a mixture of dispersed bentonite powders with silver ions and copper ions is used to obtain an antimicrobial preparation when compounding them in a 0.5-2% alcohol solution of a block copolymer of polydimethylsiloxane and polyurethane having a viscosity at 110 ° C from 10,000 to 45,000 Pa · s in the following ratio, wt.h:

dispersed powder: the specified solution as 1: (100-200).

According to the invention, bentonite of the Sarigyukh deposit (Armenia) is used as Na-form bentonite.

When implementing the claimed technical solution, it is possible to create an effective biocompatible therapeutically ready-to-use antimicrobial preparation of inorganic origin with improved antimicrobial effectiveness with prolonged action of the drug on the treated areas of a living organism, which is explained by:

using for preparation of a preparation of a natural mineral in the form of bentonite of Na-form, the structural structure of the crystal lattice of which is characterized by a layer-by-layer arrangement of “packets” of negatively charged aluminum-oxygen and silicon-oxygen compounds, the volume of the “inter-packet” space of which has a high sorption activity to solutions and to the ion-exchange reaction of cations one metal to cations of other metals in the presence of solutions containing cations of a metal substituent in the "inter-packet" space;

preliminary enrichment of Na-form bentonite with Na ⁺ ions, which ensures the activation of bentonite due to an increase in its exchange capacity due to an increase in the total amount of Na ⁺ ions capable of further ion exchange during the next technological operation. As a result, in subsequent ion exchange reactions by modifying bentonite with solutions of silver nitrate salts (AgNO ₃ ) or copper sulfate (CuSO ₄ ), the density of Ag ⁺ ions or Cu ⁺ ions increases, mainly in the inter-packet space of aluminum-oxygen and silicon-oxygen compounds of bentonite.

Processes of activation of bentonite clays due to their preliminary enrichment (technological treatment by salt solutions) ions of the respective metals, in particular ions of Na ^+, are used in the dewatering of the pulp dewatering sludge in the processes of separation of fluid / solids during clarification of waste water, clarification of water with waste containing ink and during fixation of pitch (in paper production processes), as well as upon receipt of bentonite for granulating iron ore or for applications for processing other minerals;

obtaining dispersion particles of the preparation after purification of the modified semi-finished product, and each dispersion particle of the preparation has a layered structure formation with silver or copper ions both on the outer surfaces of the layers and on the inner ones in the “inter-packet” space zone. The high specific surface of the particles and the high density in them of the quantitative content of Ag ⁺ ions or Cu ⁺ ions provide a large contact area with the bacterial environment and increase the effectiveness of antimicrobial effects on pathogenic microflora;

the manufacture of an antimicrobial preparation in the form of a mixture of dispersed bentonite powders with silver and copper ions;

using an alcohol solution of silicone compounds for the manufacture of an antimicrobial preparation.

In the analysis of the prior art, no technical solutions with a combination of features corresponding to the claimed technical solution and realizing the above-described result of the prolonged action of the antimicrobial activity of the medicinal product with effective protection of the treated areas of the living organism from toxicity were found.

The above analysis of the prior art indicates that the claimed technical solution meets the criteria of "novelty", "inventive step".

The claimed technical solution can be industrially implemented as a therapeutically ready-to-use product intended, for example, for the antimicrobial treatment of wound, burn, ulcer areas of the skin, for the treatment of mucous surfaces of the oral cavity, for prophylactic and prolonged antimicrobial treatment of medical devices, for example, surgical purpose.

The invention is illustrated by recommendations regarding the choice of raw materials for the manufacture of an antimicrobial preparation, examples of the preparation of antimicrobial preparations and test results obtained according to the invention of the drug.

To obtain an antimicrobial drug, ready-to-use medical and laboratory equipment, as well as commercial products, in particular:

bentonite (montmorillonite) of the Na form, for example, of the Sarigyukh deposit (Armenia); silver nitrate (AgNO ₃ ); copper sulfate (CuSO ₄ ); sodium chloride (NaCl); distilled water; alcohol, preferably isopropanol. These solvents, respectively water and alcohol, belong to the class of polar solvents.

Penta-1009 preparation - a block copolymer of polydimethylsiloxane and polyurethane related to thermoplastic silicone and combining organic and inorganic components - rigid and elastic blocks. Commodity modifications of the drug have a viscosity at 110 ° C from 10,000 to 45,000 Pa · s. Penta-1009 is a transparent material with a high degree of light transmission (without yellowness), which does not contain fillers, plasticizers and other additives. It has high adhesion to various materials (can be used as an adhesive) and high mechanical strength, including when heated. It does not contain volatile substances, is stable and stable during storage for unlimited time. Allows dyeing and recycling. Thanks to the block structure, Penta-1009 is combined with organic polymers and is used to modify textile material, forming a water-repellent breathable layer on textile fiber.

Preferably, the use of the drug Penta-1009 G having a viscosity at 110 ° C from 10,000 to 20,000 Pa · s.

The inventive method of obtaining antimicrobial material based on the use of the above components, the prescribed technological methods and modes of its implementation, the given weight ratio of the components provides a therapeutic drug with an effective prolonging effect on various colonies of bacteriological impurities and organisms characteristic of the treatment of various infected wounds, including long unhealed, not responding to treatment by known means. The resulting preparation is non-toxic, does not cause allergies, has no contraindications and has high decongestant, sorption, ion-exchange and anti-inflammatory properties.

The implementation of the method when changing the components used according to the invention, technological methods and modes of its implementation, a given weight ratio of the components will lead to a deterioration in the operational properties of the preparation made according to the invention or to an increase in the cost of the process for its preparation.

The implementation of the method is illustrated by the following specific examples of its implementation:

Example 1

Bentonite (montmorillonite) Na-forms in an amount of 5 g were poured with a 5% aqueous NaCl solution, kept in this solution for 15 hours, thereby additionally enriching bentonite with sodium ions, then was washed repeatedly to remove chlorine ions and then filtered through a filter " white ribbon. " The resulting semi-finished product was dried and modified with a 15% aqueous solution of silver nitrate (under red light). The modification process was carried out by exposure to a solution for 20 hours. The modification process was carried out at elevated temperature, preferably at 60 ° C. The obtained modified semi-finished product was repeatedly washed to remove sodium salts, filtered and dried at a temperature of 70-80 ° C. The consumption of aqueous solutions for processing 5 g of bentonite was: bentonite: aqueous solution as 1:20. After drying, the product was subjected to dispersion grinding using a mill and mortar. Electron microscopy of particles showed particle size dispersion from 30 to 100 nm. A therapeutic product ready for use is obtained. Useful yield 4.8 g.

Example 2

The same materials, techniques and modes as in example 1, but the modification of bentonite enriched in sodium ions is carried out using a 15% aqueous solution of copper sulfate. Useful yield 4.8 g.

Example 3

Obtained in examples 1 and 2, the finished products were mixed at a ratio of their parts by weight: product (example 1): product (example 2) as 4: 1.

Example 4

Obtained according to example 1, the finished product was mixed with alcohol (isopropanol) in the ratio, parts by weight: product (example 1): alcohol as 1: 5;

Example 5

Obtained in example 3, the finished product was mixed with a 0.75% alcohol solution of Penta-1009 in the ratio, parts by weight: product (example 3): alcohol solution as 1: 200. Upon receipt of the antimicrobial preparation, an alcohol solution of Penta-1009 G was used. The preparation obtained according to Example 5 has a nanogel structure.

To conduct evaluation tests of the preparation obtained according to the invention, the preparation was made according to control example 6:

Example 6

Dispersed zeolite powder of the Kholinsky deposit (5 g) was modified with a 15% aqueous solution of silver nitrate, followed by filtration and drying. Yield 4, 7 g.

Assessment tests were carried out using the instructions "Control the sterility of dressings" RD64-051-87.

Based on the procedure described in the instructions, the tests were carried out in sterile conditions using sterilized equipment and materials. The known sterility control technique refers to standard methods for determining microorganisms on the treated surfaces of gauze, tissue bandages, napkins, etc., on metal and silicone surfaces of medical equipment, etc.

In accordance with the instructions for testing were used:

Petri dishes (PE) treated with sterilized meat-peptone broth (MPB) with a pH of 7.2-7.4. The thickness of the layer of chilled MPB is 2-3 mm;

preparations obtained in accordance with examples 1-4.6;

sterilized gauze-cotton swabs (samples). The number of test samples treated with the preparations according to examples 1-4, 6 corresponds to the number of microscopic studies to determine Staphylococcus aureus or / and Candida utilis yeast cells on the processed materials. The studies were carried out on the 4th, 8th, 14th and 30th day of exposure under normal conditions of gauze-cotton samples placed in Petri dishes treated with MPB. Before holding the test samples under normal conditions, they were treated with the obtained preparations in examples 1-4, 6. To process the samples with powdery preparations obtained in examples 1-3 and 6, 0.03 g of the drug per 1 cm ^{2 was used} . The treatment of the test sample with the preparation obtained according to example 4 was carried out by impregnation of a gauze swab.

Microscopic examination of samples treated with the preparations according to examples 1-4,6, it was found:

the absence of colonies of microorganisms Staphylococcus aureus and Candida utilis on the surface of the studied samples treated with the preparations according to examples 1, 3 on days 4, 6, 8 and 14;

the absence of colonies of Staphylococcus aureus microorganisms on the surface of the test samples treated with the preparation of Example 2 on day 8, and Candida utilis microorganisms on day 6;

the presence of colonies of microorganisms Staphylococcus aureus and Candida utilis on the surface of the test samples treated with the preparation of example 6, on the 4th day.

The preparation obtained in Example 5 (under sterile conditions) was applied to the treated silicone surface of a medical device (sample) with the formation of a firmly held film on it with a thickness of 0.5-1.0 mm. Then, a 1.5–2 mm layer of a nutrient medium (MPB) was applied to the treated sample surface. Exposure of the sample was carried out under normal conditions for 30 days. The presence of colonies of microorganisms Staphylococcus aureus and Candida utilis on the surface of the test sample on day 30 was not detected. Studies have shown that surface treatment of medical devices with a nano-gel composition (according to the invention) has a high prolonging effect.

Additionally, for studies, a preparation was prepared according to the method of Example 1, but in which a 15% aqueous-alcoholic solution of silver nitrate with a water content of 40 wt.% Was used as a modifying solution. The results of the study of the drug showed results similar to the studies of the drug according to example 1 of its receipt. The use of an aqueous-alcoholic solution of silver nitrate to enrich sodium bentonite for modification contributes to an additional antiseptic treatment of the resulting product. The efficiency of ion exchange during the modification of bentonite is optimal at 40-50 wt.% The water content in the water-alcohol solution, taking into account the preparation regimes of the preparation specified by the invention.

Thus, the conducted studies generally confirm the high efficiency of antimicrobial activity with the prolonged action of the claimed invention in relation to colonies of microorganisms Staphylococcus aureus and Candida utilis, which indicates the advisability of using the invention:

for antimicrobial treatment of wound, burn, ulcer areas of the skin, for the treatment of mucous surfaces of the oral cavity without toxic treatment zones;

for processing products from medical polymers in contact with the tissues of living organisms.

Claims (7)

1. A method of obtaining an antimicrobial preparation, which consists in modifying an inorganic mineral with silicon and aluminum-oxygen compounds, namely, Na-form bentonite, inorganic metal salts in a polar solvent, in the subsequent exposure of bentonite in a salt solution, in the removal of modified bentonite from the solution, followed by drying at a temperature not higher than 100 ° C, characterized in that before the modification of bentonite enriched by ions of Na ⁺ by treating it with 3-10% water solution of sodium chloride with subsequent washing and f by pouring the obtained semi-finished product, which is then modified with a 10-20% solution of inorganic metal salts, which are used as silver nitrate or copper sulfate, the modified bentonite is exposed to the indicated salt solutions for 12-24 hours, and then the modified bentonite is purified from sodium salts by washing and filtering it, and after drying, the resulting preparation is crushed to a particle size of 20-150 nm, while the inorganic mineral is treated with these solutions at a ratio of, parts by weight : bentonite: solution, as 1: (10-40). 2. The method of obtaining the antimicrobial preparation according to claim 1, characterized in that the exposure of bentonite when enriched with Na ⁺ ions and its modification with a solution of inorganic salts of silver nitrate or copper sulfate is carried out at a temperature of 60-90 ° C. 3. The method of producing the antimicrobial preparation according to claim 1, characterized in that water or a water-alcohol solution are used as the polar solvent. 4. The method of obtaining the antimicrobial preparation according to claim 1, characterized in that to obtain the antimicrobial preparation, a mixture of dispersed bentonite powders with silver ions and copper ions is used in the following ratio, parts by weight: dispersion powder of bentonite with copper ions: dispersion powder of bentonite with silver ions, as 1: (3-4). 5. The method of producing the antimicrobial preparation according to claim 1 or 3, characterized in that for the preparation of the antimicrobial preparation, dispersed bentonite powder with silver or copper ions or a mixture of dispersed bentonite powders with silver and copper ions are used when compounding them in polar solvents in the following weight ratio including: dispersed powder or mixture of powders: polar solvent, as 1: (5-10). 6. The method of producing an antimicrobial preparation according to claim 1 or 3, characterized in that to obtain an antimicrobial preparation, a dispersed bentonite powder with silver ions or copper ions or a mixture of dispersed bentonite powders with silver ions and copper ions are used when compounding them in 0.5- A 2% alcohol solution of a block copolymer of polydimethylsiloxane and polyurethane having a viscosity at 110 ° C from 10,000 to 45,000 Pa · s in the following ratio by weight: dispersed powder: said solution, as 1: (100-200). 7. The method of producing the antimicrobial preparation according to claim 1, characterized in that bentonite of the Sarigyukh deposit (Armenia) is used as Na-form bentonite.