RU2159130C1 - Method for inactivating microorganisms on the surface of instruments, equipment and products of medical application - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves treating instrument surfaces with perhydrate of barium fluoride cleaned from barium fluoride sediment. The perhydrate of barium fluoride is packed into double-layer polymer packages. The internal package is manufactured from nonwoven water-proof material. EFFECT: accelerated surface treatment procedure. 3 tbl

Description

 The invention relates to the field of microbiology, medicine, veterinary sanitation, food, microbiological and other industries where it is possible to operate devices, equipment and medical devices under microbial contamination and there is a need for their disinfection and decontamination processing, especially the surfaces of work units.

 Known methods of inactivation of microorganisms on various surfaces with solutions of chemical compounds. Most often, solutions of chlorine-containing compounds and hydrogen peroxide or its derivatives of various concentrations are used. But since hydrogen peroxide is a more environmentally friendly compound, the use of disinfectants based on it is preferable. As derivatives of hydrogen peroxide, solutions of peracids, in particular peracetic acid, super formic acid and others, are recommended for use (V. Vashkov "Antimicrobial agents and disinfection methods" M., 1977, p. 49).

 A significant disadvantage of hydrogen peroxide and peracids is their state of aggregation, which causes a number of inconveniences during storage and transportation over long distances. In addition, peracids have high corrosivity and toxicity.

 The closest analogue in technical essence and the achieved effect is the "Method of inactivation of microorganisms on the surface of instruments and equipment" (see AS 1659055, MKI A 61 L 2/16). Where the inactivation of microorganisms on the surface of devices and equipment is carried out with a solution of barium fluoride peroxohydrate, while after dissolving it in water, a solution containing hydrogen peroxide is filtered off from the precipitate of barium fluoride.

 The disadvantage of the above method is that the process of preparing a disinfectant solution is time-consuming, complicated and expensive, since the operation of filtering a solution containing hydrogen peroxide and barium fluoride requires complex and expensive equipment.

 The technical result of the present invention is to reduce the time of surface treatment due to the rapid preparation of the solution, increasing the efficiency of the method due to the simplicity of the method and due to the absence of the need for complex equipment, improving the quality of surface treatment and improving environmental safety.

 The technical result is achieved by the fact that barium fluoride peroxohydrate is packaged in double polymer packaging, while the inner packaging is made of non-woven permeable material, which is removed and immersed directly in water before preparing the solution.

 Significant differences of the proposed technical solution compared to existing methods of surface treatment with peroxohydrate solutions is that immersion in packages of barium fluoride peroxide in water allows you to quickly prepare a working solution and eliminates the solution filtration operation, i.e., releases the solution from barium fluoride precipitate and eliminates use of necessary filtering equipment. Barium fluoride peroxohydrate, which is in the package, gives up hydrogen peroxide when immersed in water, and the solid carrier remains all in the package. With this preparation, the decontamination solution is purely environmentally friendly without the slightest admixture of a solid carrier, capable of changing the characteristics removed from the operating units of the devices. Consequently, there will be no sediment on the treated surfaces. The fact that only hydrogen peroxide passes into the solution, the solid carrier (barium fluoride) does not go into the solution, but the carrier can be reused to prepare a new batch of solid form of hydrogen peroxide. Solid media can be reused. Therefore, this affects the increase in the efficiency of the obtained solid forms of hydrogen peroxide, which in turn increases the efficiency of decontamination processing of both working units of devices, equipment and medical devices, and all surfaces in general.

 In addition, efficiency is enhanced by the longer availability of instruments and equipment, since the components of solid carriers are not deposited on the surfaces of the work units.

 And also the efficiency of the method is increased by increasing the expressness of the method, since the process of preparing the decontamination solution is much faster, since the operations of mixing, settling the solution with a solid carrier and filtering it are excluded.

 The ecological purity of decontaminating surface treatment of instruments and equipment is achieved due to the fact that when hydrogen barium fluoride peroxohydrate interacts with water, only hydrogen peroxide passes into the solution, while in the prototype barium fluoride insoluble does not go into solution, therefore, before disinfection measures necessary solution filtration.

The method is as follows. Barium fluoride peroxohydrate (BaF ₂ · 2H ₂ O) is a white crystalline powder with a molecular weight of 243.37, containing 27.94% hydrogen peroxide. When interacting with water, barium fluoride peroxohydrate releases almost all hydrogen peroxide into the solution for 15 minutes, while barium fluoride remains completely in the package as a precipitate, then the package with barium fluoride is removed from the solution and barium fluoride can be sent to the manufacturer for reuse in the preparation of a new batch of barium fluoride peroxohydrate.

 To determine the sporocidal activity of barium fluoride peroxohydrate, the second-order decontamination kinetics constant was determined in a known manner both for the compound as a whole and for the soluble fraction.

Example 1. To 20 ml of a suspension of Bac. antracoides, pcs. 250; n • 10 ⁷ cp / ml was added a portion of barium fluoride peroxohydrate. The resulting mixture was continuously stirred on a magnetic stirrer for several hours, periodically (every 30 minutes) 1 ml of the mixture was taken in 1 ml of a neutralizer - 10.0% sodium triosulfate solution. The neutralized sample was triturated and plated 1 ml of each dilution (in the first experiment) or the last two dilutions (in subsequent exposures). After 18 ... 24-hour incubation at 28 ... 37 ^o C, the number of viable spores was taken into account, the results were logarithmized, a table of coefficients for solving the least squares regression equation was calculated.

 According to the results of statistical processing of a series of experiments to check the sporocidal activity of barium fluoride peroxohydrate, the following data were obtained: decontamination kinetics constant K '' = 0.1556 ± 0.0075, significant interval G = 0.0283, coefficient of variation V = 18.18%.

 Table 1 shows the second-order decontamination kinetics constants for hydrogen peroxide, barium fluoride peroxohydrate, and potassium fluoride peroxohydrate. The data indicate that the sporicidal activity of barium and potassium fluoride peroxohydrates is almost equal.

 Therefore, both compounds can be used for the disinfection and decontamination of surfaces, devices, equipment, medical devices, etc.

Example 2. A portion of barium fluoride peroxohydrate, equal to 10.435 g, was placed in a package of nonwoven material and dropped into 30 ml of distilled water at room temperature, the water was periodically stirred. Then the package was removed from the water and the amount of hydrogen peroxide transferred to the solution was determined by the iodometric method. The amount of hydrogen peroxide in the solution was 10%. A clear, clear solution was added to the Bac spore suspension. anthracoides, pcs. 250, n • 10 ⁷ cp / ml in a 1: 1 ratio.

Conclusion:
Taking into account the values of the experimental second-order inactivation kinetics K '' constants for hydrogen peroxide, barium fluoride peroxohydrate, and potassium fluoride peroxohydrate, one can judge about the higher sporocidal activity of barium fluoride peroxohydrate, which in our opinion is explained by the synergistic effect of the presence of minimal amounts of fluorine and barium ions due to the solubility of barium fluorides (0.161 g per 100 g of water) / Chem. encyclical. M., 1988, v. 1 /.

Example 3. Metal test strips contaminated with a Bac spore suspension. antracoides, n • 10 ⁷ sp / ml. 0.25 ml of suspension was applied to each test surface. Barium fluoride peroxohydrate solutions were decontaminated by immersion, irrigation, and wiping. Contaminated test surfaces were immersed in a solution of barium fluoride peroxohydrate or irrigated with a solution of barium fluoride peroxohydrate using an OG-3-0.5 Rosinka sprayer. Part of the contaminated test surfaces was wiped with a swab dipped in a solution of barium fluoride peroxohydrate. After certain exposures, three parallel test surfaces were removed, the residues of the active substance were neutralized and placed in sterile Petri dishes followed by pouring MPA and incubated at 37 ^o C. The results were taken into account after 1 and 7 days.

 The experimental results are presented in table 2.

 From the data presented in table 2, it follows that reliable results of surface decontamination with solutions of barium fluoride peroxohydrate were obtained using the immersion and rubbing method after 1.5 hours, using the irrigation method for 2 hours.

 The time given to achieve the effect of the complete decontamination of test surfaces in practice will be much less, since the stability of the contaminating microflora of real surfaces is much lower than the stability of test microorganisms, which indicates the safety margin of the obtained experimental data.

 For decontamination processing of devices, equipment and disinfection of medical devices, the choice of chemical disinfection agents is determined primarily by the main operational feature, i.e. the largest inactivation kinetics constant. However, the corrosion rate of the treated surfaces plays a rather important role in the final selection of a chemical disinfection agent.

 Example 4. Test surfaces of various alloys were treated with a solution of barium fluoride peroxohydrate according to a known method. Table 3 shows comparative data on the corrosion resistance of the main technological materials to the action of the resulting solutions of barium fluoride peroxyhydrate, potassium fluoride peroxohydrate and hydrogen peroxide.

 The depth indicators of the corrosion rate given in table 3 characterize the stability of steel and aluminum alloy, as they are very resistant.

 Example 5. Along with corrosion activity, a very important characteristic of chemical disinfectants is the stability of working solutions prepared on the basis of powder. The stability of barium fluoride peroxohydrate powder was determined by changing the content of hydrogen peroxide by the iodometric method, and it was found that, subject to storage conditions, the drug is stable.

When stored in polymer containers, aqueous solutions of barium fluoride peroxohydrate have a decomposition coefficient of β = 0.00107 day ^-1 , and when stored in transparent glass containers, β = 0.0231 day ^-1 .

The use of the proposed method of inactivation of microorganisms on the surface of devices, equipment and medical devices revealed the following advantages arising from the distinguishing features:
- reducing surface treatment time by reducing the time for the operation of filtering working solutions;
- cost reduction due to the lack of unnecessary technological operations, as well as due to the repeated use of a solid hydrogen carrier;
- improving the quality of decontamination and disinfection through the use of a chemical disinfection and decontamination agent that is environmentally friendly and highly active against a wide range of microorganisms;
- reducing the cost of removing the consequences of disinfection and decontamination processing from the working surfaces of devices, equipment and medical equipment products.

 - an increase in the life of instruments, equipment and medical devices due to the low values of the activity of materials damaging to materials (depth indicator of corrosion rate).

 The raw materials for the production of barium fluoride peroxohydrate are components produced by enterprises of the chemical industry of the Russian Federation.

 The material for the manufacture of special packaging for barium fluoride peroxohydrate is non-woven materials, which are also produced in Russia.

Claims (1)

 A method of inactivating microorganisms on the surface of devices, equipment and medical devices, including surface treatment with a disinfecting and / or decontamination solution of barium fluoride peroxohydrate, freed from barium fluoride precipitate, characterized in that barium fluoride peroxohydrate is Packed in double polymer packaging, while the inner packaging is made from non-woven water-permeable material and before preparation of the solution is removed and immersed directly in water.

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