RU2574759C2 - Method for obtaining biocidal composition - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: in method for obtaining biocidal composition realised is mixing of solvent, water-soluble polyelectrolyte (PE) and salt, with water being used as solvent, and as PE - mixture of cationic PE solution and water anionic PE solution, taken in ratio, at which content of charged units of anionic PE constitutes from 3 to 30 % of content of charged units of cationic PE with the total initial PE concentration from 0.1 to 20 wt %, and as salt used is at least one water-soluble salt, selected from the group, including alkali metal or ammonium salt, or mixture of such salt with calcium or magnesium salt with salt concentration from 0.01 to 6.0 wt %, with salt or salt water solution being mixed with water solution of at least one of PE.

EFFECT: increase of biocidal activity of composition.

1 tbl, 7 ex

Description

The invention relates to methods for producing biocidal compositions, which can be used to create coatings with biocidal properties, for example, on polymers, glasses, metals, paper, building materials, etc.

A known method of obtaining a biocidal composition by mixing the polymer with metallic silver or its salt (A.J. Taylor, G. A. F. Roberts, F. A. Wood, Powders having contact biocidal properties a polymer and silver. UK patent No. GB 2381749 A).

A known method for producing a biocidal composition by mixing water, a water-soluble polymer, a low molecular weight biocidal preparation (chlorhexidine and its salt) and a surfactant (KP Ananthapadmanabhan, KK Chan, DA Grinstead, CK Vincent, AU Gengler, Ultramild antibacterial cleaning composition for frequent use, U.S. Patent No. 6,045,817).

Closest to the claimed is a known method for producing a biocidal composition by mixing a solvent (nitromethane), a water-soluble polyelectrolyte (N-alkylated poly-4-vinylpyridine) and a salt (silver para-toluenesulfonate) (V. Sambhy, MM MacBride, BR Peterson and A. Sen, Silver bromide nanoparticle / polymer composites: Dual action tunable antimicrobial materials, J. Am. Chem. Soc., 128 (2006) 9798-9808) - prototype.

The disadvantage of this method is the relatively low biocidal activity of the composition obtained with its help.

The objective of the invention is to develop a method for producing a biocidal composition devoid of the above drawback, and expanding the arsenal of technical means that can be used as a method for producing a biocidal composition.

The technical result of the invention is to increase the biocidal activity of the composition.

Previously, experiments were conducted with various polyelectrolytes (PE), solvents and salts, as a result of which it was found that the specified technical result is achieved by the fact that in the known method for producing a biocidal composition by mixing a solvent, water-soluble PE and salt, water is used as a solvent, as PE, use a mixture of an aqueous solution of cationic PE and an aqueous solution of anionic PE, taken in a ratio in which the content of charged units of anionic PE is from 3 to 30% t content of cationic charged units of PE at a total initial concentration of PE from 0.1 to 20 wt. %, and as a salt use at least one water-soluble salt selected from the group comprising an alkali metal or ammonium salt, or a mixture of such a salt with a calcium or magnesium salt, at a salt concentration of from 0.01 to 6.0 wt. %, wherein the salt or aqueous salt solution is mixed with an aqueous solution of at least one of PE.

In the proposed technical solution, it is advisable to use distilled water. When using other water, for example, tap, well, etc., it is necessary to take into account the concentration of salts dissolved in water. A mixture of dry cationic PE and anionic PE or a mixture of a suspension of these components in organic media cannot be used in the proposed technical solution.

As the cationic PE, any cationic water-soluble polymer can be used, for example, such as polyhexamethylene guanidinium chloride (PHMHC), polydemethyl diallylammonium chloride (PDMDAAX), N-alkylated poly-4-vinylpyridine, etc. The counterion of the cationic PE used can be any.

As the anionic PE, any water-soluble anionic PE containing alkali metal or ammonium counterions, for example, the sodium salt of carboxymethyl cellulose (sodium CMC), the salt of polyacrylic acid, the salt of polymethacrylic acid, etc., can be used.

In this case, the molecular weight of cationic PE and anionic PE can vary within wide limits, for example, from one to several thousand kilodaltons (kDa). Water-insoluble polymers cannot be used in this technical solution.

The optimal ratio between the charged units of cationic PE and anionic PE, the optimal concentration of water-soluble salt and the optimal total concentration of PE were established experimentally. A list of used water-soluble salts was also experimentally established. Water-insoluble salts cannot be used in this technical solution.

When the content of water-soluble salt is lower than stated, the composition becomes inhomogeneous, which leads to the formation of a coating that is heterogeneous in properties on the treated surface. With a higher than stated salt content, the composition also becomes inhomogeneous.

With a lower than stated content of anionic PE units, the stability of the applied coating is impaired. With a larger than stated content of anionic PE units, the biocidal properties of the composition deteriorate.

At a lower than stated total initial concentration of cationic PE and anionic PE, the biocidal activity of the composition decreases. With a larger than stated total initial PE concentration, there is no increase in the biocidal activity of the composition. At the same time, the viscosity of the resulting composition increases, which complicates the work in it.

Salt or an aqueous salt solution must be mixed with an aqueous solution of at least one of PE. For example, the salt can be mixed with an aqueous solution of cationic PE, or with an aqueous solution of anionic PE, or with aqueous solutions of each of PE. Mixing aqueous solutions of cationic PE and anionic PE in the absence of salt results in an inhomogeneous product that cannot be used in this technical solution.

The mass proportion between the initial anionic and cationic PE can be determined by calculation, based on their total initial concentration, the required ratio of oppositely charged PE units and the molecular weight of the charged units of cationic PE and anionic PE. We give an example of calculating the mass proportion for a mixture of cationic polyelectrolyte PDMDAAH with a molecular mass of a charged unit of 162 daltons (Da) and anionic PE, a sodium salt of polyacrylic acid (sodium-PAA) with a molecular mass of a charged unit of 94 Da, in a ratio at which the content of anionic units of PE accounts for 25% of the content of cationic PE units. To obtain this mixture, it is necessary to take sodium PAA and PDMDAAH in the ratio (0.25 × 94) / 162, respectively, that is, 23.5 / 162. Thus, the mass content of sodium PAA will be 23.5 / (23.5 + 162) = 23.5 / 185.5 = 0.127, or 12.7% of the total initial mass of PE, and the content of PDMDAAH will be 87.3 % of the total initial mass of PE. It follows that, for example, to obtain 10,000 g of a composition with a 5% total initial PE concentration, it is necessary to take sodium PAA in the amount of 500 × 0.127 = 63.5 g and PDMDAAH in the amount of 500-63.5 = 436.5 g .

When implementing the proposed method in the system, a product spontaneously forms — an interpolyelectrolyte complex, the structure and composition of which cannot be precisely determined.

Examples of the preparation of the claimed composition are given below. In all examples, the verification of the biocidal properties of the composition is carried out in accordance with regulatory documents: “Methods of testing disinfectants to assess their effectiveness and safety”, Moscow, 1998 and “Normative indicators of safety and effective disinfection of agents to be controlled during mandatory certification No. 01 -12 / 75-97. " Glass and ceramics seeded with test microorganisms are used as test objects.

The bacteria Staphylococcus aureus, Escherichia coli, Candida albicans and Trichophyton gypseum and Mycobacterium B ₅ fungi are used as test microorganisms. The biocidal composition is evenly distributed on the surface of glass or ceramic plates with a spatula. After drying the plates in air for 60 minutes, cultures of microorganisms with a seeding density of (2.1 ± 0.3) × 10 ⁵ colonies of forming units (CFU) / cm ² are applied on their surface. After keeping the samples for 60 min, the number of microorganisms N (CFU) / cm ^{2 is} counted.

The advantages of the claimed method for producing the biocidal composition are illustrated by the following examples.

Example 1

In three beakers, various solutions are prepared in distilled water. In a first beaker, 127.06 g of cationic PDMDAAH polyelectrolyte is dissolved in 500 g of water. In a second beaker, a solution of 72.94 g of anionic PE sodium-CMC in 270 g of water is prepared. A mixture of 0.05 g of CaCl ₂ and 0.05 g of NaCl in 29.9 g of water is dissolved in a third beaker. The contents of the third glass are poured with stirring into the second glass, after which the resulting mixture is transferred to the first glass and mixed. Upon receipt of the composition, the total initial concentration of PE is 20.0 wt. %, PE are taken in a ratio in which the content of anionic PE units is 25% of the content of cationic PE units, and the salt concentration is 0.01 wt. %

Obtain 1.000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Example 2

1740 g of K ₂ SO _{4 are} mixed with 7.000 g of a solution of anionic PE potassium salt of polyacrylic acid in distilled water containing 0.19 g of polymer. Then, the resulting solution is mixed with 1260 g of an aqueous solution of cationic PE poly-N-ethyl-4-vinylpyridinium chloride (PVP-chlorine) containing 9.81 g of polymer. Moreover, the total initial concentration of PE is 0.1 wt. %, PE are taken in a ratio at which the content of anionic PE units is 3% of the content of cationic PE units and the salt concentration is 17.4 wt. %

Obtain 10,000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Example 3

0.05 g of MgCl ₂ and 0.10 g of NH ₄ Cl are mixed with 300.0 g of a solution of anionic PE ammonium salt of polyacrylic acid in distilled water containing 26.2 g of polymer. Then, 699.85 g of an aqueous solution of cationic polyelectrolyte PHMHC containing 173.8 g of polymer is added to the resulting solution. Moreover, the total initial concentration of PE is 20.0 wt. %, PE are taken in a ratio at which the content of anionic PE units is 30% of the content of cationic PE units, and the salt concentration is 0.015 wt. %

Obtain 1.000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Example 4

10.0 g of Na ₂ SO _{4 are} mixed with 300.0 g of a solution of anionic PE sodium salt of polyacrylic acid in distilled water containing 8.08 g of polymer. Then, the resulting solution was added to 690 g of an aqueous solution of cationic PE poly-N-ethyl-4-vinylpyridinium bromide containing 91.92 g of polymer and 4.2 g of Na ₂ SO ₄ . Moreover, the total initial concentration of PE is 10.0 wt. %, PE are taken in a ratio in which the content of anionic PE units is 20% of the content of cationic PE units, and the salt concentration is 1.42 wt. %

Obtain 1.000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Example 5

3.85 g of KCl and 2.00 g of NaCl are mixed with 800 g of a solution of cationic polyelectrolyte PDMDAAH in distilled water containing 136.35 g of polymer. Then, the resulting solution was mixed with 194.15 g of an aqueous solution of anionic PE sodium salt of polymethacrylic acid containing 13.65 g of polymer. Moreover, the total initial concentration of PE is 15.0 wt. %, PE are taken in a ratio in which the content of anionic PE units is 15% of the content of cationic PE units, and the salt concentration is 0.585 wt. %

Obtain 1.000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Example 6

0.50 g of NH ₄ Cl and 0.04 g of KCl are mixed with 100.0 g of a solution of anionic PE - potassium salt of polymethacrylic acid in distilled water containing 6.8 g of polymer. Then, the resulting solution is added to 899.46 g of an aqueous solution of cationic PVP-chlorine polyelectrolyte containing 93.2 g of polymer. Moreover, the total initial concentration of PE is 10.0 wt. %, PE are taken in a ratio in which the content of anionic PE units is 10% of the content of cationic PE units, and the salt concentration is 0.054 wt. %

Obtain 1.000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Example 7

1.19 g of NH ₄ Cl are mixed with 100.0 g of a solution of anionic PE ammonium salt of polymethacrylic acid in distilled water containing 1.55 g of polymer. Then the resulting solution is mixed with 898.81 g of an aqueous solution of cationic polyelectrolyte PDMDAAH containing 48.45 g of polymer. In this case, the total initial concentration of PE is 5.0 wt. %, PE are taken in a ratio in which the content of anionic PE units is 5% of the content of cationic PE units, and the salt concentration is 0.119 wt. %

Obtain 1.000 g of a homogeneous composition, the biocidal properties of which are shown in the table.

Thus, from the above examples it is indeed evident that the proposed method makes it possible to obtain compositions whose biocidal properties are 3-5 times higher than the biocidal properties of the known composition described in the prototype. The biocidal activity of the obtained compositions remains for a long time (months).

Table. The effectiveness of the disinfection of surfaces contaminated with bacteria and fungi, biocidal compositions obtained using the proposed method (examples 1-7), and the composition obtained using the method described in the prototype

Claims (1)

A method of producing a biocidal composition by mixing a solvent, a water-soluble polyelectrolyte and salt, characterized in that water is used as a solvent, a mixture of an aqueous solution of a cationic polyelectrolyte and an aqueous solution of an anionic polyelectrolyte, taken in a ratio in which the content of charged units of the anionic polyelectrolyte is used, is used as a polyelectrolyte from 3 to 30% of the content of charged units of the cationic polyelectrolyte with a total initial concentration of polyelectrolytes from 0.1 to 2 0 wt.%, And as a salt use at least one water-soluble salt selected from the group comprising an alkali metal or ammonium salt, or a mixture of such a salt with a calcium or magnesium salt at a salt concentration of from 0.01 to 6.0 wt. %, wherein a salt or an aqueous salt solution is mixed with an aqueous solution of at least one of the polyelectrolytes.