RU2254143C2 - Method for sterilizing objects - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves placing object under sterilization into the space between discharge chamber electrodes, filling the space with working gas under known pressure, producing plasma in the chamber with diffuse electrode discharge caused by variable voltage applied to the electrodes. Sterilization effectiveness is stimulated by increasing charged particles concentration in space between electrodes.

EFFECT: high quality of sterilization.

3 cl, 2 dwg

Description

The invention relates to medicine, in particular to methods for treating the surface of bodies, and can be used for sterilization of dimensional heat-sensitive products, in particular, medical instruments.

A known method of sterilization, published in the journal "IEEE Trans. Plasma Sci. ”, Vol. 28, No.l, pp.41-50, 2000, which consists in placing a sterilized object in the interelectrode gap of the discharge chamber, filling the discharge chamber with a working gas of a certain pressure, creating a plasma chamber by forming a diffuse electric discharge, excited by applying voltage to the electrodes changing over time.

The disinfecting effect of the gas-discharge plasma is due to the presence of charged and neutral particles in it, as well as radiation whose energies exceed the binding energies in molecular compounds that form the basis of microbiological cultures to be inactivated. By placing a sterilized object directly in the discharge zone, it is possible to achieve the disinfecting effect of all sterilizing factors. And in this work, the high efficiency of the destruction of vegetative, spore and viral forms of microorganisms is demonstrated. However, in an analogue, atmospheric pressure discharges were studied in the interelectrode gaps of the millimeter range, which is a consequence of a reasonable voltage limitation of no more than 10 ... 20 kV, well mastered from the point of view of safe operation. Thus, the practical application of this method of sterilization is difficult due to the inability to sterilize large objects, which are medical instruments, the dimensions of which reach several tens of millimeters.

Another disadvantage of this method of sterilization is the technological complexity of the process, because to implement this method of sterilization of products requires additional gas equipment to fill the discharge chamber with non-electronegative gas - helium in order to form a diffuse electric discharge.

The closest in physical essence to the proposed method of sterilization of products is the sterilization method published in Pr. [EEE Int. Conf. Plasma Sci., Raleigh, NC.1998, p.183, which consists in placing a sterilized object in the interelectrode gap of the discharge chamber, filling the discharge chamber with a working gas of a certain pressure, creating a plasma chamber by forming a diffuse electric discharge, excited by applying voltage to the electrodes, time-varying.

Helium (or a mixture of helium with air) at atmospheric pressure was used as the working gas. As mentioned above, the disinfecting effect of plasma is due to the presence of charged and neutral particles, as well as radiation. But the conditions for the formation of a discharge are such that the maximum concentration of charged particles is in the zone of lightened conditions for the formation of a discharge — in the zone near the tip electrode (due to non-electronegative gas). Thus, the distribution of sterilization agents, including charged particles, across the interelectrode gap is sharply heterogeneous, that is, an increase in the interelectrode gap to allow placement of a sterilized object in it will lead to a significant decrease in the sterilizing effect of all the above factors (in particular, for charged particles it will sharply their concentration decreases along the length of the gap). The consequence of this fact is the inefficient use of sterilizing plasma factors.

When creating the claimed invention, the problem was solved of ensuring high-quality sterilization of overall objects, in particular, medical instruments.

The technical result consists in increasing the effectiveness of the sterilizing effect of plasma.

The specified technical result is achieved in that, in comparison with the known method of sterilization, which consists in placing the object to be sterilized in the interelectrode gap of the discharge chamber, filling the discharge chamber with a working gas of a certain pressure, creating a plasma chamber by forming a diffuse electric discharge, excited by applying voltage to the electrodes, time-varying in the proposed method of sterilization stimulate the sterilizing effect of the plasma by increasing the concentration radiations of charged particles in the interelectrode gap.

Charged particles are created in the region of a pulse-periodic discharge by applying a sequence of short voltage pulses of a microsecond or less range to the discharge gap; in addition, air is used as the working gas; in addition, the sterilized object is placed directly in the discharge zone.

Diffuse discharge is accompanied by the formation of a plasma in the interelectrode gap, the disinfecting effect of which is due to the presence of charged and neutral particles in it, as well as radiation. It is proposed to increase the effectiveness of the sterilizing effect of plasma (to solve the problem), stimulating it by increasing the concentration of charged particles, as the main sterilizing factor, in the entire volume of the discharge gap.

The possibility of using charged particles as the main sterilizing factor is evidenced by the spatial relationship observed in a number of experiments with the sterilization efficiency and the region of increased discharge current density. As is known, an increased discharge current density is characterized by a brighter glow of the plasma, and the current density is directly determined by the concentration of charged particles in the discharge plasma.

For a detailed study of the dependence of sterilization efficiency on the relative position of the discharge and the test sample, a series of experiments was carried out in which several (from two to four) test samples were located directly on the flat electrode of the chamber without Petri dishes close to each other, so that the axis The most intense part of the discharge glow coincided with one of the samples or with the boundary region between two neighboring samples. The experiments showed that the probability of sterilization of test samples located in the most intense discharge zone is close to unity and exceeds the probability of sterilization of an arbitrarily located sample and, therefore, this fact allows you to affect the efficiency of sterilization.

The increase in the region of increased concentration of charged particles throughout the interelectrode gap will expand the functionality of the sterilization method in the direction of increasing the size of the sterilized objects.

Implementation of the proposed sterilization method (stimulation of the claimed sterilization factor) is possible when creating charged particles in the region of a pulse-periodic discharge by applying a series of short voltage pulses of microsecond or less range with a sharply inhomogeneous distribution of the electric field to the discharge gap. In this case, a sharply inhomogeneous field distribution will contribute to the possibility of increasing the interelectrode gap, and the pulse-periodic nature of the discharge will provide an overstressed discharge mode. As is known, introducing an inhomogeneity of the electric field, i.e. when the electric field near the tip electrode is much higher than the electric field near the plane electrode, it decreases the breakdown voltage in the interelectrode gap and helps to increase the interelectrode gap. The pulse-periodic nature of the discharge contributes to the stability of the combustion of the discharge at significant currents flowing in the interelectrode gap, which ensures the formation of a stable volume region of an increased concentration of charged particles. This distinguishes the claimed sterilization mode from the prototype, where the discharge current is negligible, and therefore, the concentration of charged particles in the discharge gap is low and only works in a small volume. Thus, a method for sterilization of overall products by maximizing the use of charged particles as the main sterilizing factor is proposed. This is possible in a simplified way, by eliminating the supply systems of the interelectrode gap with a non-electronegative working gas if air is used as the working gas.

The most optimal area from the point of view of using the claimed sterilizing agent as the main one is directly the discharge zone. This is established experimentally. Turning to the above experiment, we can confirm the fact that the maximum concentration of charged particles is achieved in the discharge zone. Thus, by locating the object to be sterilized directly in the discharge zone, it is possible to achieve the maximum effect of the plasma generated in this process on the object being sterilized.

Figure 1 schematically shows an experimental setup for sterilizing products.

Figure 2 shows a typical photograph of the appearance of the discharge.

The main elements of the installation (figure 1) are a discharge chamber 5 with an electrode system inside it, a vacuum system 6 (BC) and a power source 7 (IP). The electrode system is formed by a flat metal disk 2, covered with glass 3 with a sterilized object 4 placed on it, and a needle electrode 1.

Typical photographs of the appearance of the discharge with and without test samples in Petri dishes are shown in FIG. 2. The shape of the glow is close to conical, with the exception of the region near the flat electrode, where a zone of weak glow broadened to the diameter of the electrode is observed. The maximum diameter of the region of intense luminescence decreases with increasing pulse repetition rate from a value approximately equal to the interelectrode gap at ~ 300 Hz to 1/3 ... 1/4 of this value at ~ 1.5 kHz.

The sterilization method was carried out as follows:

Sterilization of products (test samples) with reference cultures of microorganisms by low-temperature discharge plasma was carried out in an experimental setup, the main elements of which are a discharge chamber (5) - a sealed glass vessel with a volume of ~ 2.5 liters with an electrode system inside it and a power source. The electrode system, which allows the formation of a diffuse electric discharge, is formed by a flat metal disk (2) with a diameter of 6 ... 10 cm, covered with glass (3), and a needle electrode (1) located at a distance of 5 ... 10 cm from the plane. A power source (7), which generates a pulse-periodic discharge, which ensures the creation of charged particles, a resonant transducer with magnetic pulse compression elements, provided a sequence of alternating polarity voltage pulses with a repetition rate of up to 25 kHz on the interelectrode gap. The pulse duration at the base is ~ 4 μs. Test samples (4) were placed on a flat electrode in or without Petri dishes (Fig. 2), and after lowering the air pressure in the discharge chamber to the working pressure (18-60 Top) by means of a vacuum system (6), they were exposed to a low-temperature diffuse plasma electrical discharge, in which the main sterilizing factor was charged particles with a high concentration in the entire discharge gap.

During processing, the appearance of the discharge was photographically controlled. The result of exposure to reference cultures of low-temperature plasma was determined using standard analysis adopted in medical practice.

Thus, the experiments showed that the effect of a low-temperature plasma of a high-voltage pulse-periodic discharge in air at a pressure of tens of torr ensures the death of all representatives of reference cultures inoculated on the discharge-treated test samples - Escherichia coli and Staphylococcus epidermidis, which proves the increase in the effectiveness of the sterilizing effect plasma with the claimed stimulation mode.

With the initial number of microorganisms ~ 10 ^{8, the} complete sterility of the “wet” and “dry” test samples is achieved after 15 minutes of treatment at an average discharge power of 0.3-0.4 W and 3-4 W, respectively. The temperature of the test samples in all modes of exposure to the discharge plasma does not rise above 40 ° C. The proposed type of gas discharge can serve as the basis for the development of an effective sterilizer of thermolabile materials.

Claims (3)

1. A method of sterilizing products by treating them with low-temperature plasma, which consists in placing a sterilized object in the interelectrode gap of the discharge chamber, filling the discharge chamber with a working gas of a given pressure, creating a plasma chamber by forming a diffuse electric discharge excited by applying a voltage that varies over time characterized in that the concentration of charged particles in the interelectrode gap is increased by feeding to the discharge gap after ovatelnosti voltage short pulses of a microsecond or less range, and as the working gas is air, while a sterilizing object is placed directly in the discharge zone. 2. The method according to claim 1, characterized in that for thermolabile materials, the average discharge power is 0.3 - 4 W, at which the temperature of the test object does not rise above 40 ° C. 3. The method according to claim 1, characterized in that the processing of dimensional heat-sensitive products.

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