RU2034534C1 - Method and device for applying antiseptic protection coating - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: solution having 1-50% by mass of a fiber- generating polymer, an aseptic substance and a solvent are brought to the skin area to be protected as at least one jet. The coating is created in an electrostatic field of 1-5 kV intensity. The given method is put into effect by means of a device having a reservoir filled with the solution, a microcompressor connected with the reservoir cavity by means of a tube not reaching the level of the solution in the reservoir, a pressure-tight cover with a forming head having a capillary which one end is connected to a siphon drain tube penetrating the cover and entering the reservoir cavity. The other end is free, being outside the forming head. The device has a high voltage electric power supply source with one terminal connected to the capillary and the other one connected to earth. The forming head cavity of the device may be connected with the reservoir cavity through a branch pipe not reaching the surface of the solution in the reservoir cavity and the free end of the capillary is fixed allowing a clearance with respect to the forming head wall. EFFECT: reliable protection of skin surface area against dust particles and microorganisms. 2 dwg, 3 cl

Description

 The invention relates to medicine, and more specifically relates to a method for applying a protective aseptic coating and device for its implementation, which can be widely used for applying dressings, plasters in medical institutions, in veterinary hospitals and other industries where gas-permeable coatings are required, but not permeable to microorganisms and dust.

 A known method of applying aseptic, therapeutic and protective coatings on the external integument and damage to the body by bandaging, as well as gluing these coatings with an adhesive patch or medical glue. However, this method is not applicable in the case of increased soreness and slight injuries to damaged surfaces, for example in the case of severe burns, extensive abrasions and the like.

 Widely used in medical practice is a coating method by spraying solutions of film-forming substances containing pharmaceutical preparations, for example, from aerosol cans, from which liquid is supplied under the action of the pressure of a gaseous medium created in this canister.

 However, with this method, the formation of a protective and therapeutic coating occurs during the drying process of the droplets of the solution lying on the damaged surface, which does not exclude the irritating effect of the solvent until it dries. In addition, the coatings obtained by this method are continuous and prevent normal gas exchange of the surface to be protected, which is also unacceptable in some cases. The tight fit of these coatings to the surface to be protected makes their subsequent removal difficult in case of increased soreness of the surfaces to be protected.

Methods for applying coatings by air spraying liquid materials onto grounded products or surfaces in an electrostatic field are widely used in technology, while the resulting highly dispersed aerosols moving in an electrostatic field are deposited on grounded surfaces and form a continuous film coating. To obtain highly dispersed aerosols, air flows are supplied under high pressure or the liquid is saturated with some gas inert to it before spraying [1]
In devices implementing such coating methods, in addition to a high voltage source connected to the electrode, a container for the sprayed material and a pressure source, spray heads with an electrode placed in it in the form of a nozzle or capillary and an axial channel covering the electrode for supplying air flow are used [ 2]
However, such devices are bulky and require powerful sources to create air flows, which virtually eliminates their use in medical practice. In addition, such spraying of materials leads to the formation of a continuous film coating, which is characterized by the above-described disadvantages, which practically excludes the use of them as protective aseptic or therapeutic coatings.

 The basis of the present invention is the creation of such a method of applying a protective aseptic coating and such a device for its implementation, which will provide atraumatic coating, as well as its desired moisture and gas permeability, which in turn will create favorable conditions for the healing of damage on the outer surface.

 The problem is solved in that in the method of applying a protective aseptic coating by applying a mixture of a solvent and an aseptic preparation to the surface to be protected, a solution of a polymer fiber-forming composition containing an aseptic preparation is used as a mixture, from which a coating layer of a microfiber or porous structure is formed directly on the surface to be protected. thickness, while the polymer fiber-forming composition is contained in the solution in an amount of 1-50 wt. moreover, a solution of the polymer composition is supplied in the form of at least one jet.

 The microfibrous or porous structure of the coating layer from the stream of the solution of the polymer composition is formed in an electrostatic field with a strength of 1 to 5 kV / cm.

 The problem is also solved by the fact that in a device for applying a protective aseptic coating containing a forming head with a capillary placed in its hollow body, a container for a solution applied to a grounded surface, a high voltage source, one of the poles of which is connected to the electrode to supply voltage to the applied solution, the microcompressor communicated by the hose with the container, according to the invention, the container is mounted on the housing of the forming head, hermetically connected to it and contains two nozzles, o Institute of which is connected to the microcompressor, the open end of the sleeve connected to the capillary, placed in the vessel located below the level of solution therein. The tank is equipped with an additional nozzle, one end of which is placed in the cavity of the body of the forming head, and the other end is placed in the tank above the level of the solution in it.

 Thanks to this method, the formed coating has a porous structure, which is moisture and gas permeable, which favorably affects the healing of the damaged surface. In addition, the supplied jet of the polymer fiber-forming composition is drawn into a thin thread under the influence of an electrostatic field, the pressure of which is practically not felt when laying on the damaged surface during layer formation, since during the movement of the thread from the capillary to the surface to be protected, the thread dries from the solvent and the surface to be protected reaches a fiber with a diameter of 0.1-10 microns, which ensures the non-invasiveness of the coating and creates a structure that is impervious to dust and microorganisms. Moreover, this coating structure allows you to submit through its pores an additional amount of the required drug.

 The possibility of supplying a polymer fiber-forming composition in the form of a jet drawn into a thread, rather than spraying it, eliminated the formation of a continuous film and the need to use air flows supplied under pressure towards the damaged surface, which in general can serve as a source of delivery of microorganisms and dust to it. In addition, the elimination of the need to use air flows supplied under pressure, greatly simplified the design of the device, allowing to implement the proposed method, and significantly simplified the design of the forming head. As a result, the device for applying a protective aseptic coating is small-sized, convenient and reliable in operation.

 In FIG. 1 shows a schematic general view of the proposed device for applying a protective aseptic coating; in FIG. 2 embodiment of the installation capacity.

 The proposed method for applying an aseptic protective coating is that the protective coating is formed from a solution of a known polymer composition capable of fiber formation, for example, high molecular weight polystyrene, perchlorovinyl, rhizol and so on, and containing aseptic, for example, iodine, diamond greens, preparations.

 Moreover, the polymer fiber-forming composition is contained in the solution in an amount of 1-50 wt. which depends on the properties of the polymer to fiber formation, its interaction with drugs, the type of lesion in the protected area, and so on. So, for example, when using high molecular weight polystyrene or high molecular weight methyl methacrylate as the polymer fiber-forming composition, each of them is contained in a solution of 1-2 wt. cellulose acetate and perchlorovinyl 5-20 wt. risol (without additives) 30-50 wt. or from a composition comprising rhizol and polyvinyl butyral 5 wt.

 Ethyl alcohol or other medically approved solvents may be used as a solvent for aseptic agents.

 Such a solution of the polymer composition is supplied in the form of one or several jets, of which a coating layer of a microfiber or porous structure of a given thickness is formed on the surface to be protected in an electrostatic field of strength from 1 to 5 kV / cm, and the coating thickness depends on the type and size of surface damage. The jets of the solution of the polymer composition can be fed continuously or intermittently through a capillary or extruded through a die to form a fiber-forming or porous structure, which depends directly on the area of use of the proposed method and the type of coating applied.

 To apply a protective aseptic coating of a microfiber or porous structure, a device is used that contains a forming head 1, a container 2 for a solution 4 of a polymer fiber-forming composition containing an aseptic preparation, a high voltage source 5, one of the poles of which is connected to the electrode for voltage supply, applied to the grounded surface 3 on the applied solution, the microcompressor 6, communicated by a hose 7 with a capacity of 2. The second pole of the high voltage source 5 is grounded. The forming head 1 comprises a hollow body 8, in which a capillary 9 is placed, which serves as an electrode and is connected to a high voltage source 5 by a current lead 10, and a solution located in a container under pressure is supplied through the capillary 9. The tank 2 is mounted on the housing 8 of the forming head 1 and is hermetically connected to it by means of a known detachable assembly 11, which allows, if necessary, to change the tanks with different composition of applied solutions.

 The container has a cover 12 in which the nozzles 13 and 14 are installed, while the nozzle 13 is connected to the hose 7 of the microcompressor 6. For compactness of the device, the hose 7 passes through the housing 8 of the forming head 1. The nozzle 14 is connected to the capillary 9, and the open end of the nozzle 14 is placed in the vessel below the level of the solution 4 located therein. The open end of the nozzle 13 can also be located below the level of the solution in the vessel, as shown in FIG. 2.

 In accordance with an embodiment of the device, an additional nozzle 15 is installed in the lid of the container 2, one end of which is placed in the cavity of the housing 8 of the forming head 1, and the other end is placed in the container 2 above the level of the solution contained in it, which allows solvent vapor released in the container 2 , from the solution pass through an additional pipe 15 and accumulate in the cavity of the housing 8 and exit the cavity towards the surface to be protected through the annular gap 16 between the housing 8 and the capillary 9 and thereby Cleaning the capillary. When forming a protective coating of several jets of the solution, the latter is supplied from several forming heads or devices.

 The work of the proposed device is as follows. For coating, the patient and the device are connected by a common wire 17 for grounding and the spray device is brought to a distance of 100-300 mm to the protected surface 3, connected to a voltage source and a microcompressor. Under the pressure developed by the microcompressor 6, a solution of one of these fiber-forming polymers and an aseptic preparation enters through a pipe 14 to a capillary 9, to which a voltage of 10-100 kilovolts from a high-voltage generator 5 is supplied.

 In the electrostatic field arising between the capillary 9 and the surface to be protected 3, the solution supplied in the form of a jet is drawn into a thin charged thread 18, which, under the action of electrostatic attraction, is transported to the protected surface 3. During the movement of the thread 18 from the capillary 9 to the surface 3 of the patient the thread dries from the solvent and the surface to be protected 3 reaches microfiber with a diameter of 0.1-10 microns. Such a fiber does not produce a traumatic effect and eliminates the penetration of solvent on the protected surface. In this case, the fibers lying on the affected surface under the influence of the same charge of the electrostatic field and mutual repulsion are randomly distributed over the surface, forming a coating of a given thickness.

 The small diameter of the fibers forms a structure that is impermeable to microorganisms and harmful dust, but does not impede the gas exchange of the protected surface or the penetration of moisture.

 The high speed of fiber formation allows you to get a protective coating for 2-20 minutes After that, the device is disconnected from the power source and microcompressor and discharged from the patient. The therapeutic effect is achieved by introducing aseptic drugs into the solution and simultaneously forming negative air ions in the process. The electric current of the process is 1-20 mA, is completely safe and is not felt by the patient. The applied protective coating is retained on the surface due to the electrostatic field created during the coating formation process.

PRI me R. Artificial nutrient media with microorganisms were applied to the surface of human skin by application. A protective coating of a microfiber structure 1 mm thick from a solution having a viscosity of 1 PZ, electrical conductivity of 2˙10 ^-5 Ohm / cm and containing, by weight, was applied to these applications by the proposed method. rhizol 5% polyvinyl butyral 5% iodine 1% ethanol (solvent) the rest.

 The antimicrobial properties of the applied protective coating were studied on three strains of bacteria (staphylococci, salmonella and esherichia), three strains of mold fungi (penicillas, aspergillus and mucor) and four strains of imperfect fungi (candida, trichophyton, epidermophyton and microsporon). The protective coating was retained on the skin surface for 24 hours.

 The test results showed that the applied protective coating has antimicrobial properties (suppression of the reproduction of almost all used strains was observed) and does not cause a biological skin-irritating effect.

 Thus, the proposed method of applying a protective coating can be widely used to protect and treat people and animals from surface microbial processes (suppuration, fungal infections, and so on), especially with dermatomycoses, which constitute an urgent medical problem.

Claims (3)

 1. The method of applying a protective aseptic coating by applying to the skin a solution of an aseptic preparation, characterized in that the solution further comprises a fiber-forming polymer in an amount of 1 to 50 wt. the solution itself is supplied in the form of at least one jet, and the coating is formed in an electrostatic field with a strength of 1 5 kV / cm.  2. A device for applying a protective aseptic coating containing a container filled with a solution, a pressure source, an airtight cover, a hollow forming head with a capillary installed on it, one end of which is connected to a siphon tube passed through the cover into the container, and the other is made free, characterized the fact that the device is equipped with a source of high electrical voltage, one of the poles of which is connected to the capillary and the other is grounded, the free end of the capillary is brought out of the limits of the forming ovki, and the pressure source is made in the form of a microcompressor connected to the cavity of the tank by means of a tube not reaching the level of the solution in the tank.  3. The device according to claim 2, characterized in that the cavity of the forming head is connected to the cavity of the tank by means of a pipe that does not reach the level of the solution in the tank, and the free end of the capillary is installed with a gap relative to the wall of the forming head.

Images