RU2223789C2 - Method for cleaning and sterilizing non-metal materials and instruments - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves placing instruments in sterilization chamber filled with electric conducting medium and exposing to electric current treatment. The electric current is supplied from power supply source via electrodes mounted in the chamber. The materials and instruments are positioned in immediate vicinity of electrodes, microplasmatic discharge being produced at least on one of the electrodes. Electric current action is exerted in indirect way, that is, the instrument under treatment is not electrically connected to the power supply source. Electrodes manufactured from valve metals. Microplasmatic discharges are produced under voltage reaching 1000 V in pulsating mode with current density not exceeding 500 A/dm² or sinusoid profile of master voltage pattern under current density not exceeding 50 A/dm². EFFECT: enhanced effectiveness of sterilization; retained physical and chemical properties of materials treated. 10 cl, 2 tbl

Description

 The invention relates to the sterilization of non-metallic materials and tools in medicine and can be used in the food, chemical and biotechnological industries.

 Known methods consisting in washing the tool and materials with catholyte and anolyte obtained by electrochemical activation of aqueous solutions [Bahir V.M. et al. Electrochemical activation of aqueous solutions and its technical application in the food industry., Tbilisi: GruzNIINTI, 1988, p. 81].

 The disadvantage of these methods is the duration of sterilization and their insufficiently high efficiency.

 A known method of cleaning and sterilizing medical instruments [Ru, 2126691, C1, 1999], in which the instruments are placed in a sterilization chamber filled with a liquid conductive medium, and exposed to electric current by using the instrument as one of the electrodes, and a microplasma discharge is generated on the counter electrode. .

 The disadvantages of the prototype include the impossibility of processing non-metallic materials and tools, as well as the inability to process combined tools, i.e. metal tools containing non-metallic elements, since the processed tool is used as one of the electrodes, which would lead to the loss of such properties by non-metallic elements, like elasticity and strength.

As a prototype, the method of sterilization of surgical instruments and materials using an electric field created in an electrically conductive medium at a current density of 1 to 10 mA / cm ² , a temperature of 15-20 ^o C for 10-30 min [SU, 392944 A, 1973 ].

 Sterilization occurs only due to the influence of the parameters of the electric field on the processed material, while there is no effective and quick destruction of microorganisms.

 The present invention solves the problem of developing an effective and rapid method of sterilization of non-metallic and metallic, containing non-metallic elements, medical instruments and other materials while maintaining their physical and chemical properties.

 The problem is solved in that, as in the known method of cleaning and sterilizing medical devices and instruments, the products and instruments are placed in a sterilization chamber filled with an electrically conductive medium and are indirectly exposed to an electric current that is supplied from a power source through electrodes placed in the chamber, without electroconductive contact of materials and tools with electrodes.

 What is new is that the materials and tools being processed are placed in the immediate vicinity of the electrodes, and microplasma discharges are generated at least on one of the electrodes.

 In addition, microplasma discharges are generated on electrodes made of valve metals, mainly aluminum, titanium, zirconium or their alloys.

 In addition, microplasma discharges are generated on electrodes made of valve metals, mainly aluminum, titanium, zirconium or their alloys with an oxide coating on their surface.

 In addition, the processed tool is a metal tool containing non-metallic elements.

 In addition, non-toxic aqueous solutions with a concentration of not more than 50 g / l are used as a liquid conductive medium.

In addition, microplasma discharges are generated at voltages up to 1000 V using a pulsed mode with a current density of up to 500 A / dm ² or a mode with a sinusoidal shape of the reference voltage at a current density of up to 50 A / dm ² .

 In addition, to intensify the cleaning and sterilization process, mixing (circulation) of the solution is additionally performed.

In addition, the sterilization process is carried out at a temperature not exceeding 40 ^o C.

 In addition, cleaning and sterilization are carried out for 120 s.

 In addition, preliminary processing of materials and tools is carried out in order to remove protein, fat and mechanical impurities, as well as reduce the level of initial contamination by microorganisms.

 Non-metallic medical instruments or materials placed in a solution (and this is an environment in which microplasma reactions are possible), which also contains electrodes on which microplasma discharges are generated under certain conditions, are subjected to complex physical and chemical effects. Microplasma discharges contribute to the formation of high-pressure pulses, shock waves and hydrodynamic flows in the solution and, accordingly, around the workpiece, which contribute to the cleaning of the processed products. The breakdown occurs with the formation of light radiation from the discharge channel of a low-temperature plasma, ionization and dissociation of molecules occur, ultraviolet and ultrasonic radiation, and a pulsed electromagnetic field are generated. Low-temperature plasma is able to inactivate various microorganisms: bacteria (including spore forms), viruses, fungi and organics.

 With such a complex effect, coagulation, aggregation and mass transfer of organic and inorganic pollutants occurs, the medium is activated to form peroxides, hydroxyl radicals, atomic hydrogen, oxygen, ozone with the development of redox processes.

 In the electrode regions of the electrodes, the solution is acidified and made alkaline by the products of electrochemical activation of aqueous solutions of electrolytes. An acidic medium is formed (which, in addition, can be saturated with active chlorine), and with strong antibacterial properties, and alkaline - less antibacterial, but with pronounced detergent properties.

 Under the influence of physical and chemical factors, the object is subjected to effective electro-hydraulic treatment, in which the shells and membranes of microorganisms are destroyed, causing their death, and the external and internal surfaces are cleaned of contaminants.

 The evolved gas leads to the circulation of the electrolyte near the surface of the electrode, and this leads to sterilization of the entire volume of the solution.

 The listed impact factors make it possible to combine the processes of cleaning and sterilizing the surface of processed objects.

 To carry out the sterilization process in microplasma mode, the values of current density and duration of current pulses are selected experimentally.

 To intensify the cleaning and sterilization process, mixing (circulation) of the solution can be additionally applied.

 The invention is further illustrated by examples of its specific implementation.

Under the same conditions, rubber tubes with a diameter of 10 mm, a length of 10 cm and a cotton cloth measuring 10x10 cm were subjected to processing
For the preparation of sterilized products, preliminary, so-called pre-sterilization cleaning was carried out to ensure the removal of protein, fatty, mechanical impurities from them and to reduce the level of initial contamination by microorganisms.

 Then the objects were completely immersed in a chamber filled with an aqueous electrolyte solution, namely, non-toxic solutions of the compounds shown in table. 1 and 2. Objects were immersed in the immediate vicinity of the electrodes.

 To conduct the process in a pulsed mode, a pulsed power supply was used with a pulse frequency of 50 Hz and an output voltage of up to 1000 V.

 To conduct the process on an alternating sinusoidal current, a power source with a frequency of 50 Hz and an output voltage of up to 700 V was used.

 In the table. Figure 1 shows the modes of the sterilization process using a sinusoidal reference voltage depending on the selected medium (the “-” sign indicates the absence of a microplasma process on the electrodes, the “*” sign indicates the presence of a microplasma process on the electrodes). Used electrodes made of aluminum D-16T. The sterilization time in all examples did not exceed 120 s.

 In the table. Figure 2 shows the possible sterilization modes when using the pulsed microplasma process and depending on the selected medium (non-toxic aqueous solutions). Used electrodes made of VT1-00 titanium alloy. The sterilization time in all examples did not exceed 120 seconds.

 Processed by the present method, the objects were tested for sterility in the scientific and production association NPO "Virion" in Tomsk according to VFS 42-1844-88 "Test for sterility". As a result of the tests, conclusions are drawn about the effectiveness of the proposed method for sterilization of medical non-metallic instruments and materials.

 The proposed method can sterilize objects from textiles (surgical sutures, dressings, gowns, sheets, etc.), as well as products from polymeric materials: rubber and plastic (hoses, tubes, catheters, bougie, artificial vessels, alloplastic materials, etc. .d.), glass products.

 During sterilization, the above materials do not lose their basic properties, such as, for example, elasticity and strength.

Claims (10)

1. A method of cleaning and sterilizing non-metallic materials and tools, in which materials and tools are placed in a sterilization chamber filled with an electrically conductive medium, and are indirectly exposed to an electric current that is supplied from a power source through electrodes placed in the chamber, without electrically conductive contact of materials and instruments with electrodes, characterized in that the processed materials and tools are placed in the immediate vicinity of the electrodes, and, at least, on one of the ele Trodena generate microplasma discharges. 2. The method according to claim 1, characterized in that the microplasma discharge is generated on electrodes made of valve metals, mainly aluminum, titanium, zirconium or their alloys. 3. The method according to claim 1, characterized in that the microplasma discharge is generated on electrodes made of valve metals, mainly aluminum, titanium, zirconium or their alloys with an oxide coating on their surface. 4. The method according to any one of claims 1 to 3, characterized in that the tool to be processed is a metal tool containing non-metallic elements. 5. The method according to any one of claims 1 to 4, characterized in that aqueous non-toxic solutions with a concentration of not more than 50 g / l are used as the electrically conductive medium. 6. The method according to any one of claims 1 to 5, characterized in that the microplasma discharges are generated at voltages up to 1000 V using a pulsed mode with a current density of up to 500 A / dm ² or a mode with a sinusoidal shape of the reference voltage at a current density of up to 50 A / dm ² . 7. The method according to any one of claims 1 to 6, characterized in that for the intensification of the process circulate the electrically conductive medium. 8. The method according to any one of claims 1 to 7, characterized in that the temperature of the electrolyte is not more than 40 ° C. 9. The method according to any one of claims 1 to 8, characterized in that the cleaning and sterilization is carried out for 120 s. 10. The method according to any one of claims 1 to 9, characterized in that they carry out preliminary processing of materials and tools in order to remove protein, fat and mechanical impurities, as well as reduce the level of initial contamination by microorganisms.

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