RU2773465C1 - Disinfectant for disinformation using a hot fog generator - Google Patents

Abstract

FIELD: medical microbiology.

SUBSTANCE: invention relates to the field of medical microbiology, infectology and disinfectology. The disinfectant contains clorcept 25, triamine and aquad MSV-50 at the following ratios of components, wt.%: clorcept 25 (tablet weight 4.0 g, active chlorine weight in a tablet 1.6 g) 0.015; triamine 0.3; arcvad MSV-50 (49-52% active substance) 0.3; water is the rest.

EFFECT: resulting disinfectant is environmentally friendly and has biocidal activity against vegetative and spore-forming microorganisms when applied in the form of an aerosol using a hot mist generator at low concentrations of active ingredients.

1 cl, 1 dwg, 2 tbl, 2 ex

Description

The invention relates to the field of medical microbiology, infectology and disinfectology and can be used to obtain a disinfectant with high bactericidal and sporicidal activity when applied using a hot mist generator that ensures uniform distribution of disinfectant solution particles in the air space and on the surface of environmental objects.

Microorganisms have occupied and continue to occupy a leading place among environmental factors potentially dangerous to humans, which since January 2020 include coronavirus, which caused an infectious disease recognized as a pandemic [Vorobiev A.A., Gintsburg A.L., Bondarenko V.M. World of microbes // Bulletin of the Russian Academy of Medical Sciences. - 2000. - No. 11. - S.11-14; Vorobyov A.A. Modern problems of microbiological safety // Bulletin of the Russian Academy of Medical Sciences. - 2002. - No. 10. - P.9-12; Supotnitsky M.V. New coronavirus SARS-CoV-2 in the aspect of global epidemiology of coronavirus infection. - 2020. - V. 4, No. 1. - S.32-65.]. At the beginning of the 21st century, mortality from infectious diseases accounted for 25% of all deaths in the world. Infectious diseases claim more than 13 million lives each year, with 1,500 deaths worldwide every hour. From 60 to 80% of deaths are registered from the so-called “unmanaged” infections, which until September 2020 included coronavirus infection due to the lack of a vaccine.

Numerous experiments have established that microorganisms belonging to different phylogenetic groups have unequal resistance to external influences. The survival of many microorganisms in various conditions, the ability to persist and multiply for a long time in a wide range of temperatures and pH on various environmental objects is an indispensable condition for their preservation as a biological species in nature. Therefore, in the arsenal of methods for the prevention of infectious diseases, one of the key is disinfection [Shandala M.G. Assessment of the state and tasks of improving domestic disinfection technologies // Disinfection business. - 2013. - No. 2. - S. 20-28]. At the same time, it should be emphasized that the effectiveness of disinfection prevention of infectious pathology largely depends on the resistance of pathogens to disinfectants. This problem has become of concern to both clinicians and disinfectologists in recent years, since it turned out that the resistance of bacteria to disinfectants to a certain extent correlates with their antibiotic resistance [Luchinin D.N., Rotov K.A., Spiridonov V.A., Viktorov G.V. The main mechanisms of resistance of microorganisms to antiseptics and disinfectants // Disinfection business. - 2014. - No. 1. - P.24-30], [Tumanov A.S., Gurin K.I., Pogorelsky I.V., Lundovskikh I.A., Gavrilov K.N., Menukhova B.C. et al. Study of resistance to disinfectants of bacteria with antibiotic resistance // Disinfection business. - 2016. - No. 2. - S.17-27]. In the fight against drugs, bacteria "activated" natural genetic mechanisms for the formation of resistance. New generations of microbes have appeared that are not affected by even the strongest drugs. The problem is exacerbated by the fact that antibiotic-resistant bacteria, in turn, have a certain degree of resistance to disinfectants. The causative agents of infectious diseases with multidrug resistance, according to the European Center for Disease Prevention and Control, annually claim the lives of up to 25 thousand people. According to WHO forecasts, in 20 years all microorganisms will acquire resistance to antibacterial drugs [Antimicrobial resistance: global report on surveillance. World Health Organization - 2014: WHO Press, World Health Organization, 20 Avenue Appia, 1211. Geneva, 27, Switzerland].

The problem of multiresistant bacteria requires an urgent solution, since antibiotic-resistant strains of microorganisms isolated in medical organizations often become resistant to disinfectants [Saperkin N.V. Comprehensive characteristics of the sensitivity of pathogens of various infections to chlorine-containing disinfectants. Abstract of diss.cand. honey. Sciences. - Nizhny Novgorod: Publishing House of the Nizhny Novgorod State Medical University. Academy, 2010. - 26 p.], [Sergevnin V.I. Acquired resistance of causative agents of nosocomial purulent-septic infections to disinfectants and antibiotics. Electronic resource https://cyberleninka.ru/article/priobretennaya-ustoychivost-vozbyditeley-vnutribolnichnyh-gnouno-septicheskih-infectsiy-k-dezinfitsiruyuschim-sredstvam-i (accessed 10/8/2020)]. However, it should be recognized that resistance to antibacterial drugs and disinfectants is not always obvious. Most likely, the development of resistance of bacteria to disinfectants is a consequence of their adaptation to low concentrations used for a long period of the same disinfectants.

Disinfectants themselves, being biocidal agents, are not "obligately selective" for pathogens. They can adversely affect not only them, but also the human body, as well as the components of ecosystems [Sokolova N.F. Modern problems of organization and implementation of disinfection measures in healthcare facilities in order to prevent nosocomial infections // Disinfection business. - 2005. - No. 4. - S.31-39]. In this regard, it is obvious that disinfectants that are promising for use in disinfection technologies should have high biocidal activity against a wide range of microorganisms, which is provided by chemical compounds called active substances. The specific properties of active substances determine the peculiarity of the antimicrobial action of disinfectants, which they include, namely, the spectrum of antimicrobial action - bactericidal, virucidal, sporicidal, fungicidal, etc., as well as a certain toxicity, allergenicity and environmental safety [Sokolova N.F. Methodological support for assessing the effectiveness and safety of disinfectants // Disinfection business. - 2011. - No. 3. - S.56-58].

So far, the most common method of disinfecting the surfaces of objects and premises is chemical, mainly because its use is much more accessible than the use of an effective and cheap physical method. In addition, many items that deteriorate when exposed to high temperatures can be treated with chemical disinfectants without damage. The chemical method of disinfection consists in the use of various chemicals that cause the death of microorganisms on the surface and inside objects and objects of the environment, as well as in the air and various organic substrates (pus, sputum, feces, etc.) [Vashkov V.I. Means and methods of sterilization used in medicine. M.: Medicine, 1973. - 368 p.]. However, such methods of treatment as wiping and irrigation used for disinfection require a lot of time and physical effort of the personnel, as well as a significant consumption of disinfectants. Along with this, the possibility of secondary contamination of decontaminated objects remains, and the scope of the preparations is limited, since only surface treatment is possible. Wet methods allow you to apply the disinfectant only to accessible surfaces. At the same time, due to capillary phenomena and surface tension, the disinfectant does not penetrate into microcracks located on the surface - the main niche of pathogenic microflora. Thus, when wiping or irrigation, the required completeness of contact of the disinfectant with the source of microbial contamination is not achieved, and the exact dosage of the drug is also not provided [Golubkova A.A., Platonova T.A., Smirnova S.S. Modern cleaning technologies in medical organizations from the standpoint of epidemiological safety, hygienic expediency and economic efficiency // Disinfection business. - 2016. - No. 2. - S. 7-11].

The problem of air disinfection remains unresolved. Ultraviolet germicidal lamps widely used for these purposes have a number of disadvantages. So, there is data on the dependence of the efficiency of ultraviolet lamps on voltage fluctuations in the network. During the operation of the lamps, the intensity of the bactericidal flux decreases, therefore, after 1/3 of the nominal service life of the lamps, it is necessary to increase the irradiation, for which the operating time of the room irradiators must be recorded. Lamp life is affected by the number of times the lamp is turned on (each time the lamp is turned on, the lamp life is reduced by 2 hours). As the air temperature drops, electrode sputtering increases, which shortens the lamp life. It is necessary to periodically clean the surface of the reflector and the lamp bulb from dust, since even a small layer of dust significantly reduces the yield of the bactericidal flux. Ultraviolet rays do not have penetrating power. In addition, when using bactericidal lamps, a large amount of ozone is released into the air, which has an irritating effect on the mucous membranes of the upper respiratory tract and eyes. Ultraviolet radiation is a destructive factor for all types of coatings without exception: paint, plastic, artificial and natural leather, vinyl, fabrics [Guidelines for the use of the aerosol disinfection method in medical organizations. MP 3.5.1.01103. Approved 09/28/2015 by the head of the Federal Service of Rospotrebnadzor].

A more rational and modern way of disinfection is the use of disinfectant solutions in the form of aerosols [Riest, P. Introduction to aerosol science / Per. from English. - M.: Mir, 1987. - 278 p.]. The essence of aerosol disinfection lies in the fact that aqueous solutions of chemicals are sprayed with the help of generators to a misty state - an aerosol with a particle size of 5 to 50 microns. The aerosol fills the entire volume of the room or other treated object and stays in the air for 3-4 hours. This allows the disinfectant contained in the aerosol to penetrate into all small surface defects due to adhesion and thermal precipitation and thereby ensure its uniform and complete coverage, process the air in which microorganisms migrate in space due to convection currents.

To obtain aerosols, equipment of varying degrees of complexity is used - from the so-called "hydraulic consoles" and "quasars" to complex remote-controlled equipment that makes it possible to obtain aerosols of disinfectants by dispersion, condensation and thermomechanical methods.

In practical disinfectology and microbiology, various bactericidal aerosols were studied, such as hexylresorcinol, triethylene glycol, formaldehyde, formalin-creolin and formalin-xylonaphthol mixtures, preparations based on coniferous oils, phagogen and euphagol, preparations of coniferal, the complex English preparation "Ibcol" (4 parts triethylene glycol and 6 parts of 4% chlorinated xylenol), the Czech preparation "Pesteril", which includes perotic acid, hydrogen peroxide, sulfuric acid and a stabilizer. The list of studied bactericidal aerosols also includes chloramine, hexochlorobenzene, pentachlorophenol, hexachlorophenol, methoxychlor, anthracene, sodium hypochlorite, a mixture of chloroxylenol with triethylene glycol, beta-propiolactone, hexylresorcinol, resorcinol ether, hydrogen peroxide mixed with lactic acid and a surfactant - sulfonic acid [Yarnykh B.C. Aerosols in veterinary medicine. - M.: Kolos, 1972. - 352 p.; Medvedev N.P. Biological and technological foundations of an environmentally safe system for aerosol disinfection of objects of veterinary supervision: Ph.D. dis. Dr. Biol. Sciences. - M., 2001. - 47 p.].

A relatively new alternative disinfection system is based on the use of hydrogen peroxide in the vapor phase. This system provides low temperature processing and eliminates many of the potential operator health risks associated with decontaminants such as formaldehyde and ethylene oxide [Peroxigen compounds, in disinfection, sterilization and preservation. 5th ed. Block S. (ed.). Lippincott, Williams & Wilkins. Philadelphia, PA. - 2001. - P. 185-204; Hydrogen peroxide, chemical substances in Threshold limit values for chemical substances and physical agents and biological exposure indices. American conference of Governmental industrial hygenists (ACGIH). - Cincinnati, 2001. - P. 68.]. The authors of these developments believe that the hydroxyl radical contained in the disinfectant, which is a powerful oxidizing agent, has microbicidal activity, manifested in its action on lipids, membranes, DNA and other essential components of the cell. Hydrogen peroxide vapor is unstable and decomposes into non-toxic constituents water and oxygen.

In parallel, a number of researchers [More F., Perkinson R. Gold gas sterilization using H2O2. - US Patent, 1979. - Bui. 4. - P. 169], [Joslyn LJ Gaseous chemical sterilization in disinfection, sterilization and preservation. 5th ed. Block S. (ed.). Lippincott, Williams & Wilkins. Philadelphia, PA. - 2001. - P. 344] demonstrated the sporicidal nature of vaporous hydrogen peroxide (VHP - vaporized hygrogen peroxide) at fairly low concentrations (from 0.5 to 10 mg⋅l ^-1 ) in a very wide temperature range (4-80°C).

Two types of devices are used to generate fine aerosols. The first type are fog generators, which break the liquid into small particles (7-10 microns). The principle of operation of the generator is based on the effect of a strong air medium and turbulence forces on a liquid jet, or the disk principle of dispersion.

The second type are aerosol thermal generators - hot fog generators. The principle of operation of the hot fog generator is that the working solution of the disinfectant is injected into a stream of hot gas moving at high speed. In this case, the disinfectant solution is first broken into small drops, which evaporate almost instantly due to the high temperature of the gas. The cooling effect caused by the expansion of the gas and its contact with relatively cold ambient air leads to condensation of moisture in the form of droplets from 20 to 30 microns. These droplets form a dense cloud, commonly referred to as fog, which is propelled away from its point of origin by the velocity of the gas escaping from the outlet end of the resonator [DEZTRADE. Principles of operation of hot fog generators: advantages and disadvantages. http://diztrade.ru/info/prinsip-raboty-generatorov-goryachegotumana/].

The advantages of hot mist disinfection treatment are:

- high productivity in units of area with a small consumption of the working solution of a disinfectant (5-8 l * ha ^-1 ),

- saving time compared to conventional spraying.

- aerosol treatment with working solutions of a disinfectant on an aqueous or oil basis without loss of activity of the active substance,

- the speed and efficiency of the distribution of the active substance in the composition of the working solution of the disinfectant,

- high efficiency of decontamination even in hard-to-reach places, in the smallest cracks and crevices,

- deep penetration of the disinfectant during disinfection in rooms up to 150 ^m2 .

In terms of essential features, the closest to the proposed invention are a 6% hydrogen peroxide solution and a complex disinfectant concentrate, including silver-containing hydrogen peroxide and complexing agents [RF Patent No. 2361619. Disinfectant concentrate]. In addition to the complexity of the concentrate preparation process and practical use, the disinfectant concentrate itself was tested only on Escherichia coli, which is highly sensitive to many disinfectants. The description of the invention does not say anything about the possibility of studying the activity of the disinfectant concentrate. Humidity is a critical factor in the success of decontamination with peroxide disinfectants. The decontamination zone must be conditioned so that the relative humidity does not exceed 30%. This level ensures that the air can contain a sufficient concentration of hydrogen peroxide to successfully sterilize the target area.

The objective of the invention is to develop an environmentally friendly disinfectant with biocidal activity against vegetative and spore-forming microorganisms when used using a hot mist generator at low concentrations of active ingredients.

The technical result that can be achieved when using the proposed disinfectant as an object of the invention is that its high biocidal activity against vegetative and spore-forming microorganisms is achieved by transferring the disinfectant using a hot fog generator into the state of an aerosol that is active in small quantities on microorganisms suspended in the air or contaminating the surfaces of objects in the form of individual cells or their accumulations in droplets of organic solutions or dried particles protected by a thin colloidal film. In this case, the bactericidal effect of the aerosol is ensured not only by the contact of its particles with the microflora, but also by the diffusion of the vapors of the disinfectant solution into the bacterial cell. Vapors of the disinfectant solution condense on the bacterial cell, which serves as the condensation nucleus, and interact with it. That is why the effective action of the aerosol is manifested in the air at minimal concentrations of the disinfectant.

This task is achieved by the fact that the inventive disinfectant contains Clorsept 25, triamine and aquad MSV-50 in the following ratio, wt. %:

clorcept 25 (tablet weight 4.0 g, mass of active chlorine in a tablet 1.6 g) 0.015 triamine 0.3 arcvad MSV-50 (49-52% active substance) 0.3 water rest.

The claimed composition of the disinfectant contains clorcept 25 - sodium salt of dichloroisocyanuric acid [Instruction No. 25/08 for the use of the disinfectant "Clorcept". - M.: 2008. Approved. Director General of Samarovo LLC I.P. Chuev on December 29, 2018]. In terms of acute toxicity, Clorsept 25 belongs to the 3rd class of moderately hazardous compounds, according to GOST 12.1.007-76.

The second component of the disinfectant is the tertiary ammonium compound triamine (N,N-bis-(3-aminopropyl)dodecylamine). Tertiary ammonium compounds have low toxicity, have surface-active properties that provide increased antimicrobial activity in the compositions [Pogorelsky I.P., Gurin K.I., Lundovskikh I.A. Experimental assessment of the activity of the disinfectant triamine: microbiological, electron-microscopic and analytical aspects of the study // Disinfection business. - 2013. - No. 3. - S.33-38.]. Triamine is compatible with other biocides, does not cause corrosion of metals [Instruction for use (No. 002/2015 of 2015). Producer OOO NPK Alfa, Russia]. In terms of acute toxicity, it belongs to moderately dangerous compounds (LD ₅₀ when administered orally to white rats 200-2000 mg⋅kg ^-1 ).

The third component is arcvad MSV-50 - alkyldimethylbenzyl ammonium chloride, a clear colorless liquid containing 49-52% of a cationic quaternary ammonium compound with a C ₁₂ -C ₁₆ alkyl chain. Manufacturer - Akzo Nobel Surface Chtmistry AB (Sweden) [Arquad MSV-50. http://izomernn.ru/alkildimetilberizilammonij-chlorid/?yclid=5607992490439247624]. Arquad MCB-50 has minimal toxicity (LD ₅₀ when administered orally to white rats 795 mg⋅kg ^-1 ).

It is used for bactericidal treatment of air circulation systems in medical organizations.

These components combined in the composition of the disinfectant in a certain ratio as a result of a synergistic effect on the bacterial cell, manifested by an increase in the antibacterial properties of the composite disinfectant in the form of destruction of cell walls and cytoplasmic membranes.

To confirm the possibility of carrying out the invention and achieve the specified technical result, a disinfectant is prepared and its bactericidal activity is tested against spores of the anthrax microbe Bacillus anthracis of the vaccine strain STI-1 and the clinical isolate of Staphylococcus aureus KM as test microorganisms that have, respectively, high and medium resistance to disinfectants.

The assessment of the bactericidal and sporicidal action of the proposed disinfectant is carried out using a hot fog generator TN-130 [Instruction for the operation of a hot fog generator TN-130 with automatic start (manufactured in Korea) // Agrovetser-vis LLC, 2017. - 15 p. ]. The disinfectant working solution is injected into the hot, high-velocity gas stream. The temperature of the aerosol in the generator set at 70°C. Microbial cultures of Staphylococcus aureus and spores of Bacillus anthracis STI-1 are applied to test objects 5×5 cm in size made of steel, brass and slate. The biological concentration of Staphylococcus aureus staphylococci and Bacillus anthracis STI-1 spores applied to test objects is (1.4-1.8)⋅10 ⁶ CFU. After drying, the test objects are contaminated with cultures of staphylococci and spores of bacilli, treated once with a hot mist of a disinfectant, and washed with sterile cotton-gauze swabs from the treated surfaces of the test objects after 1.3 and 5 minutes. Test objects contaminated with microorganisms and spores without treatment with hot fog serve as control in the experiments. A universal neutralizer containing Tween-80 (3%), saponin (3%), histidine (0.1%), cysteine (0.1%), sodium thiosulfate (1%) is used as a disinfectant neutralizer in experiments, eliminating the effect of a chemical agent on bacteria and spores, but not killing or inhibiting the growth of microorganisms [Methods of laboratory research and testing of disinfectants to evaluate their effectiveness and safety. Guideline 4.2.2643-10. Approved 01.06. 2010 Head of the Federal Service of Rospotrebnadzor]. The selected samples (experimental and control) after neutralization are sown on a dense nutrient medium in Petri dishes to count the grown colonies and determine the number of viable microorganisms.

The structure of Bacillus anthracis STI-1 spores is studied using a JEOL JEM transmission electron microscope (Japan) at an accelerating voltage of 200 kV. Statistical processing of the results of the determination is carried out according to the Kerber method in the modification of I.P. Ashmarin and A.A. Vorobiev [Ashmarin I.P., Vorobyov A.A. Statistical methods in microbiological research. - L.: Medgiz, 1962. - 280 p.].

The possibility of carrying out the claimed invention is shown in the following examples.

Example 1. Prepare a 6% solution of hydrogen peroxide according to GOST 177-88.

A culture of staphylococcus Staphylococcus aureus KM is grown for 24 hours at a temperature of 37°C, after which a bacterial suspension is prepared in an isotonic sodium chloride solution at a concentration of (1.8±0.5)⋅10 ⁶ bacterial cells per 1 ml.

A suspension of spores of Bacillus anthracis vaccine strain STI-1 is prepared in an isotonic solution of sodium chloride, for which this solution is injected into an opened ampoule with a lyophilized spore culture (manufacturer - Branch of the Federal State Budgetary Institution "48 Central Research Institute" of the Ministry of Defense of Russia) until a suspension with a concentration of spores (1, 7±0.6)⋅10 ⁶ in 1 ml. Suspensions of staphylococci and spores of anthrax bacilli are applied to the surface of test objects made of steel, brass and slate. After drying the microbial cultures, the test objects are divided into experimental and control samples. The prototypes are processed for 1 min using a hot fog generator TN-130 based on a 6% hydrogen peroxide solution; consumption of hydrogen peroxide 80-85 ml⋅m ^-2 ; the distance from the sprayer to the test objects is 2 m. Neutralization of the disinfectant is carried out using a universal neutralizer. Sampling of bacterial cultures from the surface of the selected control and experimental test objects is carried out after 1, 3 and 5 minutes. Sowing of selected samples - control and experimental (after exposure to a disinfectant) is carried out on dense nutrient media in Petri dishes, examined after 24 hours of incubation of crops for the presence or absence of growth of microorganisms. Based on the results obtained, a judgment is made on the disinfecting effectiveness of a 6% hydrogen peroxide solution.

The study of the bactericidal effect of hot fog based on a 6% hydrogen peroxide solution at a spraying time of 30 s leads to a significant reduction in the number of viable tested microorganisms: at an exposure of 5 minutes, only tens and hundreds of microorganisms remain viable. An exception is the experiment with brass test objects: after 5 minutes of exposure, thousands of tested microorganisms remain viable (Table 1). Obviously, in those places of the brass test objects where the surviving microorganisms remained, there was an accumulation of copper ions in an increased amount, sufficient for the catalytic splitting of hydrogen peroxide and a local decrease in the biocidal effect of the disinfectant.

Example 2. Prepare the inventive disinfectant in the following ratio, wt. %:

clorcept 25 (tablet weight 4.0 g, mass of active chlorine in a tablet 1.6 g) 0.015 triamine 0.3 arcvad MSV-50 (49-52% active substance) 0.3 water rest.

A culture of staphylococcus Staphylococcus aureus KM is grown for 24 hours at a temperature of 37°C, after which a bacterial suspension is prepared in an isotonic sodium chloride solution at a concentration of (1.8±0.5)⋅10 ⁶ bacterial cells per 1 ml.

Suspension of spores of Bacillus anthracis vaccine strain STI-1 is prepared in an isotonic solution of sodium chloride, for which this solution is injected into an opened ampoule with a lyophilized spore culture (manufacturer - Branch of the Federal State Budgetary Institution "48 Central Research Institute" of the Ministry of Defense of Russia) until a suspension with a concentration of spores (1, 7±0.6)⋅10 ⁶ in 1 ml. Suspensions of staphylococci and spores of anthrax bacilli are applied to the surface of test objects made of steel, brass and slate. After drying the microbial cultures, the test objects are divided into experimental and control samples. The prototypes are processed for 30 seconds using a hot fog generator TN-130 based on the inventive disinfectant; disinfectant consumption 75-80 ml⋅m ^-2 ; the distance from the sprayer to the test objects is -2 m. Neutralization of the disinfectant is carried out using a universal neutralizer. Sampling of bacterial cultures from the surface of the selected control and experimental test objects is carried out after 1, 3 and 5 minutes. Sowing of selected samples - control and experimental (after exposure to a disinfectant) is carried out on dense nutrient media in Petri dishes, examined after 24 hours of incubation of crops for the presence or absence of growth of microorganisms. Based on the results obtained, a judgment is made about the effectiveness of the proposed disinfectant.

The study of the bactericidal action of hot fog based on the proposed disinfectant at a spray time of 30 s leads to the death of all bacteria Staphylococcus aureus KM and spores of Bacillus anthracis vaccine strain STI-1, including those exposed to the action of hot fog on brass test objects: viable microorganisms on surfaces of dense nutrient media were not revealed during sowing of experimental samples. The results of monitoring the sporicidal action of the proposed disinfectant on the spores of Bacillus anthracis STI-1 are also evaluated according to the electron microscopic examination of the spores. Changes in the structure of spores under the influence of a disinfectant are shown in Fig., where A - spores before contact with a disinfectant, B - after contact with a disinfectant for 5 minutes. As shown in Fig., native spores have a structure natural for spores with a smooth, clear surface of the cortex, electron-optical density is not changed. After exposure to the spores of the disinfectant, the spores lost their natural shape, which led, while maintaining the electron-optical density, to the formation of spore agglomerates with a loss of their viability, and this was confirmed by the bacteriological method (Table 2).

The claimed disinfectant provides a high level of bactericidal and sporicidal activity in the composition of hot mist at a low concentration of components in the working solution.

Claims (2)

A disinfectant with biocidal activity against vegetative and spore-forming microorganisms when used in the form of an aerosol formed by a hot fog generator, characterized in that it contains clorcept 25, triamine and aquad MSV-50 in the following ratios, wt.%: clorcept 25 (tablet weight 4.0 g, mass of active chlorine in a tablet 1.6 g) 0.015 triamine 0.3 arcvad MSV-50 (49-52% active substance) 0.3 water rest.

Images