RU2772898C1 - Prolonged, water-soluble, polymeric disinfectant for treatment of contact surfaces - Google Patents

Abstract

FIELD: sanitation, hygiene and disinfection.

SUBSTANCE: invention relates to the field of sanitation, hygiene and disinfection and can be used to disinfect various surfaces in office, residential and public buildings. Film-forming disinfectant composition contains the following components, wt.%: alkyldimethylbenzylammonium chloride 0.5; copper sulfate 0.005; zinc sulfate 0.005; water-soluble polymer polyacrylamide 0.05-0.1; medium acidity regulator, which is sodium carbonate, 0.5-1.5; phenylcarbinol 0.05; surfactant С₁₂-С₁₅ Paret-5 0.1; distilled water - the rest.

EFFECT: invention provides prolonged antibacterial action and long bacteriostatic and bactericidal effect.

1 cl, 9 tbl

Description

The invention relates to the field of modern long-acting biocidal compositions based on safe active substances, film-forming components and mild repressors to provide effective hygienic and anti-epidemic measures against infections of bacterial and viral origin in office, residential and public buildings (cultural, recreational, sports, healthcare, education institutions , social security, catering and trade enterprises (restaurants, cafes, canteens, bars, production shops, fast food enterprises, supermarkets, food and industrial markets, etc.)).

Preventive and current disinfection of contact surfaces is an integral part of the work on organizing a safe environment. Processing of contact surfaces should be carried out in socially significant places in order to prevent and suppress the foci of the spread of bacterial and viral infections.

There are various means used to disinfect various contact surfaces for domestic, professional and highly specialized purposes.

Existing traditional disinfectant compositions are active against a large number of types of pathogens of bacterial and viral infections (RU 2476241 C1 "Disinfectant antiseptic", RU 2371917 C1 "Disinfectant composition", RU 2019 104 862 "Emollient local disinfectants", etc. ). The disinfecting effect of traditional biocides is pronounced (efficiency above 99.8% of the population), but short-term, i.e. lasts no more than 10-15 minutes, since volatile organic substances (alcohols, acids, aldehydes) and chemically active compounds (hydrogen peroxide, iodine and its derivatives) are used as disinfectants. Thus, the main disadvantage of traditional biocides is the short duration of their disinfectant action, which leads to an increase in the number of repeated treatments, and, as a result, is one of the reasons for the emergence of resistance (resistance) in infectious agents.

The prototype of film-forming biocides are special medical dressings, the compositions of which are described in patents: RU 2521323 C1 "Means for disinfecting the treatment of the skin", RU 2736859 C1 "Disinfectant gel", etc. The composition of these compositions includes soft biocompatible components, specially used for contact with the skin. The limitation of the use of these compositions lies in the fact that soft biocompatible components cannot maintain sterile conditions on an abiotic surface for a long time.

An analogue of the claimed biocide is the composition described in the patent RU 2736859 C1 ("Disinfectant gel") and intended for the treatment of skin integuments by the type of "artificial leather" or "gloves". EFFECT: biocompatible, hypoallergenic long-acting composition. An analysis of the content of the security document indicates that the technical result is achieved by introducing rheological additives into the composition of the disinfectant: a softener (castor oil), a gelling agent - natural chitosan - and an additional disinfectant agent - silver nanoparticles. The disadvantage of this invention is the narrow specificity of the action - the skin. The limitation of the possibility of using the invention on abiotic surfaces is associated with the possibility of developing non-specific destruction of the natural polymer due to microbiological degradation and, as a result, a general decrease in sterility.

The closest, in fact, prototype of a scientific and operational idea is patent RU 2543345 C2 (“Composition of a polymeric decontaminating (disinfecting) formulation based on potassium fluoride peroxosolvate for obtaining strong and low-permeable films that protect and decontaminate surfaces in hermetically sealed volumes of various objects”). The technical result consists in the creation of film coatings with sporicidal, bactericidal and fungicidal properties. An analysis of the content of the security document indicates that the technical result is achieved due to the fact that a mixture consisting of polyvinyl alcohol, polyvinylpyrrolidone and a plasticizer (glycerin) is used as an organic solvent, which ensures the strength of the formed films. The disadvantage of this invention is the possibility of deactivation of the active disinfectant component as a result of long-term storage due to the chemical instability of the substance itself.

The solution to the problem associated with the short duration of action and the possibility of resistance in microorganisms to drugs was found in the course of experimental activities by the authors of this patent application. The solution found is that to ensure the long-term existence of bacteriostatic and bactericidal effects, active substances and a mild repressor, which provides an abiotic environment for microorganisms, are dispersed in a medium of a biologically stable water-soluble polymer, the rheological properties of which are determined by the presence of surfactants and organic alcohols. The newly developed technical solution makes it possible to significantly increase the duration of the presence of the biocide on the contact surface from 0.5 min to 8.0 hours.

It should be noted that the key task in creating new biocides is to reduce the proportion of antimicrobial reagents in order to prevent the development of resistance (resistance) in pathogenic and opportunistic microorganisms.

Confirmation of the bacteriostatic and bactericidal effect was performed on test cultures of microorganisms using standard protocol procedures: the method of growing in liquid media followed by counting colonies on a solid medium, the diffusion disc method. Cultures of reference and clinical strains of pathogenic and opportunistic bacteria were used as test objects: Escherichia coli ATCC®25922, Klebsiella pneumoniae ATCC®700603, Pseudomonas aeruginosa ATCC®27853, Staphylococcus aureus ATCC®25923 (obtained from the State Collection of Pathogenic Microorganisms GISK named after L.A. Tarasevich (now Federal State Budgetary Institution "NTsESMP" of the Ministry of Health of Russia, Moscow). All selected protocol procedures for the study of antibacterial ability correspond to MUK 4.2.1890-04 "Determination of the sensitivity of microorganisms to antibacterial drugs" and GOST R 58151.1-2018 "Disinfectants General technical requirements".

The possibility of implementing the claimed invention and achieving a technical result is confirmed by the research work of the team of authors (stages P.P.1 - P.P.6.).

P.P.1. Determination of the concentration of traditional antibacterial substances that ensure the termination of the vital activity of microorganisms. It has been established that a mixed solution of ZnSO ₄ , CuSO ₄ and alkyldemethylbenzylammonium chloride achieves the maximum antibacterial efficacy at a concentration of wt. % 0.02, 0.02, and 1.5, respectively.

P.P.2. It differs from P.P.1 in that a medium acidity regulator (sodium carbonate) is introduced into the mixture of disinfectants in amounts of wt. % 0.5-1.5. It was noted that the introduction of an acidity regulator leads to a reduction in the amount of traditional antibacterial components by 1.5-2.0 times (Tables 1 and 2). It has been proven that the required amount of the acidity regulator in the composition of such a biocide should be at least 1.5 wt. %.

P.P.3. Differs from P.P.2. the fact that a water-soluble polymer, polyacrylamide, is added to the developed mixtures in the amount of wt. % 0.05-0.1. It has been established that polyacrylamide causes inhibition of the vital activity of microorganisms due to the fact that, first of all, it is a hard-to-digest source of matter and energy. It has been proven for the first time that the introduction of a water-soluble polymer leads to the possibility of reducing the amount of traditional antimicrobial compounds (Tables 3 and 4). Thus, the authors managed to reduce the concentration of active antibacterial components by 3-4 times compared to the original solution. It has been established that the decrease in the amount of the medium acidity regulator to a value below 1.0 wt. % leads to a deterioration of the disinfectant effect.

P.P.4. Determination of the concentration of a water-soluble polymer required for the formation of thin films on surfaces by the method of fine drop spraying (Table 5). For testing, polymeric biocides of the following composition (wt.%) were prepared: ZnSO ₄ - 0.005, CuSO ₄ - 0.005, alkyldemethylbenzylammonium chloride - 0.5, Na ₂ CO ₃ - 1.0, distilled water - the rest. It has been established that the best spreadability and preservation of the integrity of the films of the developed disinfectant solutions is achieved with a content of polyacrylamide in the amount of 0.075 wt. %. Options for compositions with a content of water-soluble polymer in the amount of 0.05 and 0.1 wt. % do not form an integral coating and do not allow finely drop spraying (for the composition variant with a polyacrylamide content of 0.1 wt. %).

P.P.5. It differs from P.P.4 in that a surfactant and an aromatic organic alcohol are introduced into the composition of the developed polymeric biocide to improve rheological parameters - spreading over the surface. For testing, polymeric biocides of the following composition (wt.%) were prepared: ZnSO ₄ - 0.005, CuSO ₄ - 0.005, alkyldemethylbenzylammonium chloride - 0.5, Na ₂ CO ₃ - 1.0, polyacrylamide - 0.075, distilled water - the rest. The concentration of selected surfactants and alcohols are respectively 0.1 and 1.0 wt. %. It has been established that surfactants (Table 6) and organic alcohols (Table 7) lead to a change in the surface formation energy (surface tension) and spreadability. It has been proven that the best wetting of the surface with a polymeric biocide is achieved by introducing into the composition of the biocide a nonionic surfactant - С ₁₂ -С ₁₅ Paret-5 and an aromatic alcohol - phenylcarbinol in concentrations of 1.5 wt. %.

P.P.6. Determination of the concentration of nonionic surfactant and organic alcohol in the composition of the polymeric biocide. For testing, water-soluble polymeric biocides (WPBs) of the composition used in P.P.5 were taken. It has been established that the best rheological parameters have the variant of a water-soluble polymeric biocide with the composition: ZnSO ₄ - 0.005, CuSO ₄ - 0.005, alkyldemethylbenzylammonium chloride - 0.5, Na ₂ CO ₃ - 1.0, polyacrylamide - 0.075, C ₁₂ -C ₁₅ Paret- 5 - 0.1, phenylcarbinol - 0.05, distilled water - the rest. Aromatic alcohol has been proven to contribute to film thinning in one dimension, while surfactants promote the formation of continuous mono- to decamolecular layers. The advantages of this biocide are due to the increase in the value of the contact angle, due to the balance between the surfactant and aromatic alcohol. This leads to the fact that an optimal ratio is achieved between the drying rate and the subsequent integrity of the polymeric biocidal film formed on the treated surface. In other versions of the water-soluble polymeric biocide, a number of shortcomings were noted, explained by an imbalance between the components that provide the rheological properties of the film. Thus, for VPB containing phenylcarbinol at maximum concentrations of ~ 1.0, the viscosity indices sharply decrease, resulting in a strong spreading of the biocide over the surface, and, consequently, a violation of the integrity of the polymer coating. For VPB containing a minimum amount of C ₁₂ -C ₁₅ Paret-5 ~ 0.05, a decrease in the spreadability index was noted, which also leads to a violation of the integrity of the antibacterial coating on the treated surface.

Comparison of the bacteriostatic and bactericidal effectiveness of the developed water-soluble polymeric biocide with existing analogues (Table 9) shows the advantage of the claimed invention, reflected in the prolongation of the antibacterial action - the duration of disinfection of the treated surface increased by 2-2.5 times, which appears in the absence of visible growth for 5 .0 hours for the proposed invention, unlike existing analogues.

Table 1

Comparison of antibacterial efficiency for variants of developed disinfectants. Growth in aerated environment

Disinfectant solution option, wt. % Test cultures of microorganisms Escherichia coli Klebsiella pneumoniae Pseudomonas aeruginosa Staphylococcus aureus ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
dist water - 98.98 24 cfu/petri 15 cfu/petri 17 cfu/petri 26
CFU/Petri ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.0
dist water - 97.98 4 cfu/petri No growth 2 cfu/petri 5
CFU/Petri ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.5
dist water - 97.48 No growth No growth No growth No growth ZnSO ₄ - 0.02
CuSO _{4 -} - 0.02
alkyldemethylbenzylammonium chloride - 1.5
Na ₂ CO ₃ - 1.0
dist water - 97.46 No growth No growth No growth No growth ZnSO ₄ - 0.02
CuSO ₄ - 0.02
alkyldemethylbenzylammonium chloride - 1.5
Na ₂ CO ₃ - 1.5
dist water - 96.96 No growth No growth No growth No growth

table 2

Comparison of antibacterial efficiency for variants of developed disinfectants. Growth without aeration

Disinfectant solution option, wt. % Test cultures of microorganisms Escherichia coli Klebsiella pneumoniae Pseudomonas aeruginosa Staphylococcus aureus ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
dist water - 98.98 12 cfu/petri 8 cfu/petri 9 cfu/petri 9
CFU/Petri ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.0
dist water - 97.98 3 cfu/petri No growth No growth one
CFU/Petri ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.5
dist water - 97.48 No growth No growth No growth No growth ZnSO ₄ - 0.02
CuSO _{4 -} - 0.02
alkyldemethylbenzylammonium chloride - 1.5
Na ₂ CO ₃ - 1.0
dist water - 97.46 No growth No growth No growth No growth ZnSO ₄ - 0.02
CuSO ₄ - 0.02
alkyldemethylbenzylammonium chloride - 1.5
Na ₂ CO ₃ - 1.5
dist water - 96.96 No growth No growth No growth No growth

Table 3

Comparison of antibacterial efficiency for variants of the developed disinfectants with a water-soluble polymer.

Growth in aerated environment

Disinfectant solution option, wt. % Test cultures of microorganisms Escherichia coli Klebsiella pneumoniae Pseudomonas aeruginosa Staphylococcus aureus polyacrylamide - 0.05
dist water - 99.95 3 cfu/petri 3 cfu/petri 2 cfu/petri 5
CFU/Petri polyacrylamide - 0.1
dist water - 99.90 2 cfu/petri No growth No growth 2
CFU/Petri ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.5
polyacrylamide - 0.05
dist water - 97.43 No growth No growth No growth No growth ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.0
polyacrylamide - 0.05
dist water - 97.93 No growth No growth No growth No growth ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 0.5
polyacrylamide - 0.1
dist water - 98.38 3 cfu/petri 1 cfu/petri No growth 2
CFU/Petri ZnSO ₄ - 0.005
CuSO ₄ - 0.005
alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 1.5
polyacrylamide - 0.05
dist water - 97.94 No growth No growth No growth No growth

Table 3

Continuation

Disinfectant solution option, wt. % Test cultures of microorganisms Escherichia coli Klebsiella pneumoniae Pseudomonas aeruginosa Staphylococcus aureus ZnSO ₄ - 0.005
CuSO ₄ - 0.005
alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 1.0
polyacrylamide - 0.05
dist water - 98.44 No growth No growth No growth No growth ZnSO ₄ - 0.005
CuSO ₄ - 0.005
alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 0.5
polyacrylamide - 0.05
dist water - 98.94 11 cfu/petri 8 cfu/petri 9 cfu/petri 12
CFU/Petri

Table 4

Comparison of antibacterial efficiency for variants of the developed disinfectants with a water-soluble polymer.

Growth without aeration

Disinfectant solution option, wt. % Test cultures of microorganisms Escherichia coli Klebsiella pneumoniae Pseudomonas aeruginosa Staphylococcus aureus polyacrylamide - 0.05
dist water - 99.95 1 cfu/petri No growth one
CFU/Petri 2
CFU/Petri polyacrylamide - 0.1
dist water - 99.90 No growth No growth No growth No growth ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.5
polyacrylamide - 0.05
dist water - 97.43 No growth No growth No growth No growth ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 1.0
polyacrylamide - 0.05
dist water - 97.93 No growth No growth No growth No growth ZnSO ₄ - 0.01
CuSO ₄ - 0.01
alkyldemethylbenzylammonium chloride - 1.0
Na ₂ CO ₃ - 0.5
polyacrylamide - 0.1
dist water - 98.38 1 cfu/petri No growth No growth No growth ZnSO ₄ - 0.005
CuSO ₄ - 0.005
alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 1.5
polyacrylamide - 0.05
dist water - 97.94 No growth No growth No growth No growth

Table 4

Continuation

Disinfectant solution option, wt. % Test cultures of microorganisms Escherichia coli Klebsiella pneumoniae Pseudomonas aeruginosa Staphylococcus aureus ZnSO ₄ - 0.005
CuSO ₄ - 0.005
alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 1.0
polyacrylamide - 0.05
dist water - 98.44 No growth No growth No growth No growth ZnSO ₄ - 0.005
CuSO ₄ - 0.005
alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 0.5
polyacrylamide - 0.05
dist water - 98.94 6 cfu/petri 3 cfu/petri 4 cfu/petri 7
CFU/Petri

Table 5

Comparison of the rheology of a water-soluble polymeric biocide (WPB) with the addition of a water-soluble polymer

Index The concentration of polyacrylamide, wt. % in the biocide composition P.P.4 0.05 0.075 0.1 Drop size when spraying, mm 2.00±0.30 3.00±0.20 5.70±0.50 Film continuity on 75 mm area No Yes Yes Viscosity, mm ² / s 30.00±0.80 52.00±2.10 78.00±3.30 Wetting angles on a glass plate, degrees 37.25±1.04 37.82±1.14 38.54±1.39 Wetting angles on an aluminum plate, degrees 84.21±2.18 84.82±3.56 85.67±3.33

Table 6

Comparison of the rheology of a water-soluble polymeric biocide (WPB) (composition P.P.5) with the addition of surfactants (surfactant concentration 0.1 wt.%)

Surface tension, mN/m Wetting angles on a glass plate, degrees Wetting angles on a metal plate, degree Dialkylammonium methosulfate 39.74±1.49 31.42±1.32 44.25±1.59 α-olefin sulfonate 57.89±2.19 37.89±1.57 51.12±2.20 С ₁₂ -С ₁₅ Paret-5 31.47±1.15 23.16±0.62 41.53±1.70

Table 7

Comparison of the rheology of a water-soluble polymeric biocide (composition P.P.5) with the addition of organic alcohols (alcohol concentration 1.0 wt. %).

Surface tension, mN/m Wetting angles on a glass plate, degrees Wetting angles on a metal plate, degree Pentanol 24.56±0.76 49.78±2.57 63.19±3.09 Hexanol 22.37±0.70 45.32±2.31 59.03±2.77 Phenylcarbinol 21.49±0.59 34.78±1.63 48.12±2.07

Table 8

Comparison of the rheology of a water-soluble polymeric biocide with different levels of nonionic surfactant and aromatic alcohol

Disinfectant solution option, wt. % Surface tension, mN/m Wetting angles on a glass plate, degrees Wetting angles on a metal plate, degree Viscosity, mm ² / s VPB composition P.P.5 - 99.45
С ₁₂ -С ₁₅ Paret-5 - 0.05
Phenylcarbinol - 0.5 30.33±1.28 40.69±1.91 56.30±2.56 51.90±2.53 VPB composition P.P.5 - 98.95
С ₁₂ -С ₁₅ Paret-5 –0.05
Phenylcarbinol - 1.0 26.84±1.10 34.15±1.64 46.12±1.96 31.70±1.32 VPB composition P.P.5 - 99.40
С ₁₂ -С ₁₅ Paret-5 - 0.1
Phenylcarbinol - 0.5 27.78±1.08 26.66±0.91 43.17±1.89 53.60±1.74 VPB composition P.P.5 - 98.90
С ₁₂ -С ₁₅ Paret-5 - 0.1
Phenylcarbinol - 1.0 25.63±0.95 28.45±1.02 44.15±1.84 32.10±1.34

Table 9

Comparison of antibacterial efficacy for the Invention and existing analogues

Disinfectant Efficiency parameters ZnSO ₄ - 0.005
CuSO ₄ - 0.005 alkyldemethylbenzylammonium chloride - 0.5
Na ₂ CO ₃ - 1.0
polyacrylamide - 0.075
С ₁₂ -С ₁₅ Paret-5 - 0.1
phenylcarbinol - 0.05
distilled water - the rest Drying time, min 5-10 Disinfectant effect Test cultures of microorganisms Escherichia coli Escherichia coli Pseudomonas aeruginosa Staphylococcus aureus 0.5 h No growth No growth No growth No growth 1.0 h No growth No growth No growth No growth 2.0 h No growth No growth No growth No growth 5.0 h 1 cfu/petri No growth 1 cfu/petri one
CFU/Petri 8.0 h 7 cfu/petri 3 cfu/petri 2 cfu/petri 5
CFU/Petri EN 2543345 C2 Drying time, min 5-10 Disinfectant effect Test cultures of microorganisms Escherichia coli Escherichia coli Pseudomonas aeruginosa Staphylococcus aureus 0.5 h No growth No growth No growth No growth 1.0 h No growth No growth No growth No growth 2.0 h 5 cfu/petri No growth No growth 8 cfu/petri 5.0 h 11 cfu/petri 13 cfu/petri 9 cfu/petri 21
CFU/Petri 8.0 h 24 cfu/petri 22 cfu/petri 21 cfu/petri 34
CFU/Petri

Table 9

Continuation

Disinfectant Efficiency parameters EN 2736859 C1 Drying time, min 5-10 Disinfectant effect Test cultures of microorganisms Escherichia coli Escherichia coli Pseudomonas aeruginosa Staphylococcus aureus 0.5 h No growth No growth No growth No growth 1.0 h 2 cfu/petri No growth No growth 3 cfu/petri 2.0 h 7 cfu/petri 6 cfu/petri 5 CFU/Petri 8 cfu/petri 5.0 h 15 cfu/petri 19 cfu/petri 13 cfu/petri 33 cfu/petri 8.0 h 31 cfu/petri 28 cfu/petri 26 cfu/petri 42 cfu/petri

Claims (2)

The composition of the film-forming disinfectant composition, characterized in that it contains the following substances, wt.%: alkyldimethylbenzylammonium chloride 0.5 copper sulfate 0.005 zinc sulfate 0.005 water-soluble polymer polyacrylamide 0.05-0.1 acidity regulator, which is sodium carbonate, 0.5-1.5 phenylcarbinol 0.05 surfactant С ₁₂ -С ₁₅ Paret-5 0.1 distilled water rest