RU2660369C1 - Disinfectant - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to medical microbiology, infectology and disinfectology, and is intended for decontamination of surfaces of medical, sanitary, microbiological equipment. Disinfectant contains hydrogen peroxide, dimethyl sulfoxide (dimexidum), triamine – N,N-bis(3-aminopropyl)dodecylamine and water. Components are used in claimed amounts.

EFFECT: use of the invention provides bactericidal and sporicidal activity against bacteria and spores at low concentrations of components included in the disinfectant.

1 cl, 2 dwg, 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 sporocidal activity, intended for decontamination of surfaces of medical, sanitary, microbiological equipment, as well as hydrophobic substances.

To date, there is a well-founded idea that it is necessary to use new disinfectological technologies in practical health care [Shandala MG The place and role of non-immunological methods in the prevention of infectious diseases // Disinfection business. - 2012. - No. 4. - S.23-28]. It is important to emphasize that the effectiveness of disinfectological prophylaxis of infectious pathology to a certain extent depends on the resistance of pathogens to disinfectants. Disinfectants themselves, being biocidal agents, are not “obligatory selective” for pathogenic microorganisms. They can adversely affect not only them, but also on the human body, as well as on the components of ecosystems [Sokolova N.F. Modern problems of the organization and conduct of disinfection measures in health facilities for the prevention of nosocomial infections // Disinfection business. - 2005. - No. 4. - S.31-39]. In this regard, it can be argued that disinfectants, promising for use in disinfectological technologies, must have high biocidal activity against a wide range of microorganisms, low toxicity, lack of allergenicity, and also be characterized by environmental safety [Sokolova N.F. Methodological support for assessing the effectiveness and safety of disinfectants // Disinfection business. - 2011. - No. 3. - S. 56-58].

Currently, among the most widely used disinfectants based on chlorine, hydrogen peroxide, aldehydes, quaternary and tertiary ammonium compounds, the latter attract the close attention of specialists in the field of disinfectology due to the high biocidal activity against many types of microorganisms, as well as other high operational characteristics [Panteleeva L. G. Modern antimicrobial disinfectants. The main results and prospects for the development of new tools // Disinfection business. - 2005. - No. 2. - S. 49-56].

Tertiary ammonium compounds, having in one molecule hydrophobic and hydrophilic groups, are capable of adsorbing on the interface and lowering surface tension. In prokaryotic and eukaryotic cells, such a interface is the cell membrane. Under the influence of tertiary ammonium compounds with surface-active properties, the permeability of cell membranes is disrupted. A consequence of the indicated effect of tertiary ammonium compounds on microbial cells is a different degree of destruction, manifested either by microbostasis or cell death [Group of disinfectants // www.alfamedtyumen.ru/index.php?option=com_content&view=ar-ticle&id+201:ewgrt&catid=61: 2011-02-09-17-39-138 & / temid + 227]. Given these properties, tertiary ammonium compounds are often introduced into the composition of disinfectant compositions to give them wetting properties, which in some cases leads to an increase in the antimicrobial effect.

The following disinfectants were created on the basis of an alkylamine (triamine) of the formula N, N-bis (aminopropyl) dodecylamine: Optimax [Didenko L.V., Kardash G.G., Konstantinova N.D. et al. Study of the mechanism of action that prevents the development of resistance to the Optimax drug in clinical isolates of Escherichia coli and Staphylococcus aureus // http: www.isen.ru/ru/nau_st_optimax-max.php? PHPSESSID = 57ea], Trilox [ Instruction No. 9/07 on the use of Trilox disinfectants for disinfection and pre-sterilization cleaning in medical institutions, infectious foci, pharmaceutical and biotechnological enterprises engaged in the production of non-sterile medicines in rooms of cleanliness classes C and D. M .: 2007. - Approved. The General Director of MK VITA-PUL LLC A.V. Belyakov May 21, 2008], Mistral [Instruction No. 6/08 on the use of Mistral disinfectants MK VITA-PUL LLC, Russia preventive facilities. - M .: 2008. - Approved. The General Director of LLC MK VITA-PUL A.V. Belyakov September 22, 2008]. Their activity against bacteria (including Mucobacterium tuberculosis), viruses and fungi Candida, Trichofiton, Aspergillus was shown. At the same time, the characteristics of the Optimax, Trilox, and Mistral disinfectants do not contain information on their activity against spore forms of bacteria and the actual spore, but there is double information about triamine N, N-bis (aminopropyl) dodecylamine , which does not allow to qualify this tool as sporocidal. It is only noted that some additives can enhance the antibacterial activity of triamine.

Thus, due to the ambiguity of the judgment on the sporocidal properties of the triamine, it seemed appropriate to develop a disinfectant composition with improved performance on the basis of the triamine. It is important that microorganisms do not form resistance to the disinfectant composition.

The invention is known [RF patent No. 2187460. Disinfectant Concentrate], intended for the disinfection of drinking water, drinking water supply pipes, water supply networks and structures after major repairs, swimming pool water. The disinfectant concentrate is based on hydrogen peroxide, a soluble silver salt, aliphatic alcohols. Directly as a disinfectant in medical and infectological practice, the claimed subject matter was not proposed.

Known disinfectants "Deconex 50 FF", Catamine AB, Alaminal, Sterrilium, Mezafin [RF patent No. 2145238. Disinfectant]. These funds showed insufficient efficiency even at high concentrations of working solutions and prolonged exposure.

Disinfectant patented [RF Patent No. 2286145. Disinfectant] based on alkyldimethylbenzylammonium chloride, glutaraldehyde, benzotriazole, hydrogen peroxide and monohydroxy alcohol, as well as a disinfectant [RF patent No. 2395962. Disinfectant], which includes alkyldimethylbenzylammonium chloride, hydrogen peroxides, ethyl alcohol, glutaraldehyde, sulfanol, perfluorodecalin. The use of these patented multicomponent disinfectants with a wide antibacterial agent is unsafe for operating personnel. This is due to the fact that a pronounced bactericidal effect is achieved at high concentrations of working solutions (hydrogen peroxide 5%, ethyl alcohol 5%, etc.), which implies the observance of certain safety measures. The inclusion in the composition of the latter disinfectant perfluorodecalin as a means with a gas transport function is hardly justified at such high concentrations of alkyl dimethylbenzylammonium chloride (10%), hydrogen peroxide and ethyl alcohol.

Closest to the proposed combination of essential features is the invention [RF patent No. 2361619. Disinfectant concentrate] based on hydrogen peroxide, soluble silver salt, complexing agent, acidity regulator, dimethyl sulfoxide. The object of the invention is a disinfectant concentrate intended for disinfection of surfaces, drinking water, drinking and technical water supply systems, swimming pool water, and wastewater. When used at the work site, the concentrate is diluted with water to the required working concentration. The inventors note that hydrogen peroxide in the presence of heavy metal cations becomes unstable and can actively decompose. Therefore, the determination of the stability of metal-containing solutions of hydrogen peroxide is a mandatory controlled parameter of the process. The addition of dimethyl sulfoxide leads to an increase in the stability of silver-containing concentrates. In addition, to obtain stable concentrates based on silver-containing hydrogen peroxide, they include complexing agents (citric or tartaric acid, thiosulfates, thiourea, etc.), which convert the silver cations of its nitric acid salt into strong complex compounds. These technological procedures complicate the process of preparation of concentrates, which limits their use in medical institutions. In addition, the effectiveness of the disinfectant concentrate was tested only on E. coli as a test culture, which is highly sensitive to any of the ingredients of the prescription of the disinfectant concentrate. About the possible use of other test strains of microorganisms, as well as spores of microorganisms, nothing is said in the description of the invention.

The objective of the invention is the development of a disinfectant with biocidal activity against vegetative and spore-forming microorganisms that contaminate the surfaces of medical, microbiological, sanitary equipment, preserving antimicrobial and sporocidal activity at low concentrations of active substances, which has environmental and operational safety.

The technical result that can be obtained using the proposed disinfectant is that high antimicrobial activity against vegetative and spore-forming microorganisms is achieved at low concentrations of working solutions, short exposure during processing, maintaining environmental and operational safety.

This object is achieved in that the claimed disinfectant contains hydrogen peroxide, dimethyl sulfoxide (dimexide), alkylamine (triamine) of the formula N, N-bis (aminopropyl) dodecylamine in the following ratio of components, mass. %:

hydrogen peroxide 1,0 triamine 0.05 dimethyl sulfoxide 0.15 water rest

pH 4.9-5.1

The claimed composition contains hydrogen peroxide according to GOST 10929-76, an aqueous solution of a triamine of the formula N, N-bis (aminopropyl) dodecylamine (approved for use for disinfection and pre-sterilization treatment in medical institutions, infectious foci, at the enterprises of the pharmaceutical and biotechnological industries according to the production of non-sterile medicines in rooms of cleanliness classes C and D), dimethyl sulfoxide (approved for medical use (FS 42-2980-98) under the brand name Dimexidum).

The high bactericidal and sporocidal activity of the claimed drug is associated with the inclusion of hydrogen peroxide, traditionally used as a disinfectant, triamine, which has surface-active properties and the ability to disrupt the permeability of the cell membrane, as well as dimethyl sulfoxide (dimexide), which forms complexes with almost all metals and transcending various biological membranes.

To confirm the possibility of carrying out the invention and achieve the technical result, a disinfectant is prepared and its microbicidal activity is tested for Bacillus cereus ATCC 10702 bacilli (vegetative form) and Bacillus anthracis bacillus strain STI-1 in spore form. B. cereus ATCC 10702 bacilli and B. anthracis spores strain STI-1 are taken as test objects as the most resistant to disinfecting agents [Methods for studying and evaluating the sporicidal activity of disinfecting and sterilizing agents // MU 3.5.2435-09. Rospotrebnadzor of Russia. - Approved. 01/20/2009].

Evaluation of the bactericidal and sporocidal action of the disinfectant is carried out by the suspension method [Methods of laboratory research and testing of disinfectants to assess their effectiveness and safety: Guideline P 4.2.2643-10: Approved. Head of the Federal Service for Supervision of Consumer Rights Protection and Human Well-being, Chief State Sanitary Doctor of the Russian Federation 06/01/2010]. The final concentration of bacteria of the test strain and spores in the solution of the disinfectant is 1 КО10 ⁸ CFU / spor⋅ml ^-1 . At the end of the exposure, the test suspensions are plated in successive tenfold dilutions of the suspensions in a solid nutrient medium to count the grown colonies and determine the number of viable microorganisms.

The structure of the bacilli of the test strains of B. cereus ATCC 10702 and the spores of B. anthracis strain STI-1 were studied using a JEOL JEM transmission electron microscope (Japan) at an accelerating voltage of 200 kV.

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

Example 1

Prepare a disinfectant in the following quantitative ratio of components, mass. %:

hydrogen peroxide 1,0 triamine 0.05 dimethyl sulfoxide 0.15 water rest

pH 4.9-5.1

A culture of B. cereus ATCC 10702 bacilli (vegetative form) is grown for 48 hours at 37 ° C, after which a bacterial suspension is prepared on an isotonic solution of sodium chloride at a concentration of 1 × ^{10 9} bacterial cells in 1 ml. The prepared suspension of bacilli is introduced into a vial with a disinfectant to a final concentration of 1⋅10 ⁸ CFU / spor⋅ml-1. Sampling is carried out after 15, 30 and 60 minutes. Sowing of samples taken after exposure to a disinfectant on solid nutrient media is viewed after 48 hours of incubation at 37 ° C. The results of the control of the bactericidal action of the disinfectant are assessed by the presence or absence of growth of B. cereus ATCC 10702 bacilli on solid nutrient media in Petri dishes, as well as by electron microscopic examination of the bacilli. A change in the structure of B. cereus ATCC 10702 bacterial cells under the influence of a disinfectant is shown in FIG. 1: A - initial culture, × 1200; B - culture after contact with a disinfectant for 15 minutes, × 6000; B - culture after contact with a disinfectant for 30 minutes, × 10000; G - culture after contact with a disinfectant for 30 minutes, × 50,000.

A study of the bactericidal action of the disinfectant showed that with a 10-minute exposure, about 8% of the bacilli remain viable, and with a 20-minute exposure, the bacilli cannot be detected by the bacteriological method. As shown in FIG. 1, the viable dividing cell of B. cereus ATCC 10702 bacilli has a clear layered structure, characteristic "polar caps". The cytoplasm of cells has an average optical density. Cell division occurs by constriction and violations of this process have not been identified.

Under the influence of a disinfectant, there is a violation of the integrity of the cell wall and cytoplasmic membrane. Fragments of these structures of microbial cells seem to come off by the hydrophilic and hydrophobic groups of the triamine, which is a component of the disinfectant. With a 30-minute exposure, the microbial cell of B. cereus 10702 acquires a pronounced "serration" on the surface and enhanced electron-optical density and looks completely unviable.

Example 2

Prepare a disinfectant in the following quantitative ratio of components, mass. %:

hydrogen peroxide 1,0 triamine 0.05 dimethyl sulfoxide 0.15 water rest

pH 4.9-5.1

A spore suspension of B. anthracis strain STI-1 is obtained by rehydration of the vaccine strain spore lyophilized in ampoules in an isotonic sodium chloride solution. Spore suspension is added to vials with a disinfectant to a final concentration of 1-10 ⁸ CFU / sporml ^-1 . Sampling is carried out after 10, 20 and 30 minutes. Sowing of samples taken after exposure to a disinfectant on solid nutrient media is viewed after 48 hours of incubation at 37 ° C. The results of the control of the sporocidal action of the disinfectant are assessed by the presence or absence of growth of the bacilli of the vaccine strain B. anthracis STI-1 on solid nutrient media in Petri dishes, as well as according to electron microscopic examination of spores. A change in the structure of B. anthracis STI-1 spores under the influence of a disinfectant is shown in FIG. 2: A - disputes before contact with a disinfectant, × 2500; B - disputes after contact with a disinfectant for 10 minutes, × 10000; B - disputes after contact with a disinfectant for 20 minutes, × 6000; G - destruction of spores after contact with a disinfectant for 20 minutes, × 60,000.

The study of the sporocidal action of the disinfectant showed that after a 10-minute exposure, none of the spores exhibited in the population sprouted, i.e. was not viable. As shown in FIG. 2, native spores of B. anthracis STI-1 have a natural structure for spores with distinct cortex, spore membrane, and sporoplasm. Sporoplasm has an average optical density, the cortex and spore membrane are clearly separated. After 10 minutes of contact with a disinfecting solution, agglomeration of spores is observed with a violation of their structure and a significant increase in electron-optical density.

After a 20-minute exposure, an increase in agglomeration of spores with exfoliation of the cortex and membrane is noted, and the high electron-optical density of the sporoplasm is maintained. At a large magnification (× 6000) of spores located separately, the cortex and spore membrane ruptures and the exit of the sporoplasm to the outside are clearly visible, the remaining sporoplasm retains a high electron-optical density. Visible damage to spores indicates their loss of viability.

The claimed disinfectant provides a high level of bactericidal and sporocidal activity at a low concentration of the working solution.

Claims (2)

A disinfectant containing hydrogen peroxide and dimethyl sulfoxide (dimexide), characterized in that it further contains triamine - N, N-bis (3-aminopropyl) dodecylamine in the following ratio, wt. %: hydrogen peroxide 1,0 triamine 0.05 dimethyl sulfoxide 0.15 water rest

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