RU2716263C1 - Method of treating wounds and burns - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to surgery, traumatology, combustiology, and can be used for treating wounds and burns. That is ensured by exposure to wounds and burns with a plasma beam using a plasma generator. Air-plasma treatment of the wound surface is performed with a pulse plasma beam of atmospheric pressure with diameter of up to 10 mm. Pulse length makes 300–500 ns. Pulses follow with interval of 20–50 mcs. Scanning speed of plasma beam is 10–20 mm/s at average current of 40–90 mcA. Nanofilm of a coagulated protein of wound exudate is formed on the wound surface.

EFFECT: invention allows accelerating processes of wound and burn healing, reducing rate of complications of wound process and recovering skin in patients.

1 cl, 4 tbl

Description

The invention relates to medicine, namely to surgery, traumatology, combustiology and can be used in the treatment of patients with chronic nonhealing wounds of various etiologies (including varicose veins, diabetic foot syndrome), as well as deep skin burns III degrees.

A known method of exposure to biological tissue by a plasma stream (US Pat. RF No. 2183480 C2, firm Plason), in which the biological tissue is exposed to a stream of electrically neutral thermally equilibrium air plasma. The formed bundle of air plasma is directed to the localization region of the biological tissue to be treated, and then they are brought into direct contact.

Known surgical method for dissecting biological tissues using a plasma stream (US Pat. US No. 3903891), which consists in the formation and maintenance of high-frequency current of cold plasma with a sufficiently small cross-section of the flow (diameter from 0.13 to 0.38 mm). These conditions are created to obtain a narrow contact zone between the plasma and the tissue, followed by the introduction of a stream of this plasma into the tissue to obtain an incision. Inert gas argon is used as a plasma-forming working gas.

A known method of coagulation of biological tissues in the field of surgical incision (US Pat. US No. 3938525, the company Bovie J-Plasma), which consists in the formation and maintenance using direct current of an electrically neutral cold plasma with a sufficiently small cross section of the plasma flow (diameter from 0.127 to 1, 27 mm), providing a narrow contact area between the plasma and the tissue, and the subsequent direction of the plasma flow to biological tissues in the incision region for their coagulation. As the plasma-forming gas in the above method, a gas selected from the group of gases including argon, helium, nitrogen, or a mixture of two or three of these gases is used.

A known method of plasma coagulation of tissues by using a jet of inert gas passing through the zone of a high-frequency discharge formed between two electrodes (US Pat. US No. 4781175, the company Neoplas Tools). A device using the bottom of the electrode, one of which is passive, has a processing zone that is unstable in space, due to the instability of the discharge position, due to the fact that the passive electrode occupies a significant area.

All of the above methods are characterized by a small diameter of the plasma flow, are not able to provide reliable and fast coagulation of sufficiently extensive dissected wound surfaces of biological tissues.

Thus, the above methods have several disadvantages:

1. Low efficiency of plasmatrons in connection with design features; as a result of their work, an intense high-temperature plasma flow is continuously exposed to the wound. This inevitably leads to the short duration of its effect on the wound due to the danger of burns and does not fully provide the possibility of a direct effect on the wound surface of other types of radiation and factors present in the plasma (charged particles, UV, IR radiation).

2. The width of the zone of influence of the plasma beam is units of mm and is limited by the technical characteristics of the plasmatrons, which require the use of expensive inert gases (argon, neon, helium, etc.) with additional equipment as a plasma-forming medium.

3. When using analogues, the generation of a nanofilm layer from coagulated proteins of wound exudate on the wound surface is not ensured, which does not allow to fully optimize the wound process and achieve uncomplicated wound healing.

Closest to the claimed method is a method of treating cells with cold argon plasma (Frequency of cell treatment with cold microwave argon plasma is important for the final outcome / E. Sysolyatina, M. Vasiliev, M. Kurnaeva, I. Kornienko, O. Petrov, V. Fortov. A. Gintsburg, E. Petersen, S. Ermolaeva // J. Phys. D: Appl. Phys. 49 (2016) 294002 (11pp).

The method consists in applying a continuous stream of cold argon plasma to human fibroblasts and keratinocytes using inert gas cylinders (argon).

The disadvantages of the method selected as a prototype:

1. The width of the zone of influence of the plasma flow is wide enough, but does not allow for the rapid processing of extensive wound surfaces.

2. For the implementation of this method of treatment of the wound surface, it is necessary to have expensive additional equipment - cylinders with inert gas (argon) and related additional items of equipment.

3. When treating the wound surface with argon plasma, it is impossible to achieve instant coagulation and, therefore, persistent hemostasis.

4. The presence of a continuous high-temperature plasma flow (the prototype does not have a pulsed mode) does not allow the torch of the resulting plasma to approach the wound surface at a distance less than the length of the torch. As a result, the wound surface is primarily affected by the high temperature (up to 75 ° C) created by the plasma, while the influence of other plasma factors is limited: active oxygen and nitrogen particles, electrons, ions, electromagnetic field, ultraviolet (UV) and infrared radiation (IR ) Also, due to low nitrogen concentrations, it is difficult to treat the wound with nitric oxide, one of the transmitters (regulators) of the normal functioning of blood vessels and the proliferation of cellular elements in the wound.

5. When using the prototype due to the features of its mode of operation (microwave argon plasma) on the wound surface, the generation of nanofilms from coagulated proteins of wound exudate is not ensured, which does not allow to improve the course of the wound process and reduce the frequency of purulent complications.

The objective of the invention is to increase the effectiveness of the treatment of skin defects, accelerate the cleaning process and the timing of the final healing of wounds and burns, reduce the frequency of infection of the wound process, as well as improve the aesthetic characteristics of the scar.

The result of the task is achieved by the fact that the air-plasma treatment of the wound surface is carried out by exposure to a pulsed plasma beam of atmospheric pressure with a diameter of up to 10 mm, a pulse duration of 300-500 ns, following with an interval of 20-50 μs, the scanning speed of the plasma beam 10-20 mm s, with an average current of 40-90 μA and create on the wound surface a nanofilm of a coagulated wound exudate protein.

The pulsed mode allows you to bring the plasma plume closer to the wound surface at a distance shorter than the length of the plume, while it is affected by all types of radiation inherent in the plasma (electromagnetic field, UV radiation, charged particles (electrons and ions) and active neutral particles) and nitric oxide . In the pulsed regime of plasma exposure to the wound surface, bleeding is instantly stopped by evaporation of the liquid fraction to a depth of several microns and a sterile film cover is created without the formation of a scab. Microorganisms present on the wound surface are exposed to pulsed plasma flow and die.

The formed nanofilm of the coagulated wound exudate protein creates the conditions for preventing tissue drying, ensuring regeneration and the course of the wound process in a natural moist environment (table 1).

The formation of a nanofilm of a coagulated wound exudate protein with a thickness of 50-70 nm, which is necessary to accelerate the healing of wounds and burns, occurs when the wound surface is treated with a pulsed plasma beam with a pulse duration of 300-500 ns, followed by an interval of 20-50 μs, with a beam scanning speed of 10- 20 mm, current 40-90 μA.

The inventive method is as follows. The wound surface is treated with a plasma beam; pulsed (with a pulse duration of 300-500 ns, following with an interval of 20-50 μs, and a scanning speed of 10-20 mm / s, with an average current of 40-90 μA, a low-temperature atmospheric pressure plasma, the direct effect of which is accompanied by the formation on the wound, is used the surface of the nanofilm of the coagulated wound exudate protein with a thickness of 50 to 70 nm, while the entire wound surface is treated with low-temperature atmospheric plasma for 20 seconds, the distance between the beam source and the wound surface is 1.5- 2 cm. The formed nanofilm of coagulated wound exudate protein with a thickness of 50 to 70 nm creates the conditions for preventing tissue drying, ensuring regeneration and the course of the wound process in a natural moist environment.

The experimental work was performed on 44 male Wistar-Kyoto rats weighing 230-250 g.

Skin burns of the III degree (ICD-10) were reproduced according to the author's technique. 60 minutes after their reproduction, necrectomy was performed to the fascia proper, followed by treatment with atmospheric low-temperature air plasma and application of local treatment. All animals were divided into 4 groups (11 animals each) taking into account the choice of the method of their local treatment: the first group (control) without treatment, the second wet-drying dressings with antiseptic solutions, the third group dressings with multicomponent antibacterial ointment levomekol, the fourth group -processing of postoperative wounds by the present method.

It was established that the studied local treatment agents had various wound healing effects. The results of a comparative assessment of the terms of the final healing of experimental wounds, depending on the method of treatment, are shown in table 2.

¹ - significantly (p <0.05) compared with the control group (without treatment)

² - significantly (p <0.05) compared with the results of using antiseptic solutions

³ - significantly (p <0.05) but compared with the results of the use of levomecol ointment

It was found that when treating burn wounds with the claimed method, the final healing occurs on the 18th day of observation, which is 49% faster (p <0.05) compared with the group of animals that were not treated. When using dressings with antiseptic solutions and levomecol ointment, defect contraction was noted on days 28 and 24 of the study, respectively. In the control group (without treatment), wound studies independently healed by only 35 days of observation.

Burn wounds are obligately contaminated by a wide range of pathogenic microflora, causing a pronounced inflammatory reaction and, as a consequence, the complicated course of the wound process. During the experiment, cases of the development of purulent inflammation of varying severity were recorded in the observation groups; their frequency, taking into account the method of treatment, is given in table 3.

¹ - significantly (p <0.05) compared with the control group (without treatment)

² - significantly (p <0.05) compared with the results of using antiseptic solutions

³ - significantly (p <0.05) compared with the results of the use of levomecol ointment

The healing of experimental wounds in animals was completed due to its contraction and was accompanied by the formation of a scar, a comparative analysis of the area of which by the end of 35 days of observation is presented in table 4.

¹ - significantly (p <0.05) compared with the control group (without treatment)

² - significantly (p <0.05) compared with the results of using antiseptic solutions

³ - significantly (p <0.05) compared with the results of the use of levomecol ointment

The inventive method is an effective way to treat wounds of various etiologies (trophic, long-healing wounds, complicated forms of varicose veins, diabetic foot syndrome).

The method allows you to speed up the healing process, reduce the overall period of hospitalization, reduce the frequency of complications of the wound process, i.e. improve immediate and long-term treatment results. It allows you to quickly and effectively restore the skin in patients with wounds and burns, it is relatively simple, less traumatic, one-stage (performed during one treatment procedure), easily feasible.

The method allows you to bring the plasma plume close to the wound surface and ensure exposure to all types of inherent low-temperature plasma radiation (charged particles, electrons, ions, electromagnetic field, UV, IR) and nitric oxide. By evaporating the liquid fraction to a depth of a few microns, a sterile nanofilm with a thickness of 50-70 nm is created, impermeable to microorganisms, but selectively permeable to steam and air, ensuring the occurrence of reparative processes in a humid environment. A thin film ensures the course of the wound process in a moderately moist air environment, prevents drying of the wound surface and the formation of zones of secondary necrosis.

The presented method provides a pathogenetically substantiated effect on the wound surface in wounds and burns of the skin of the III degree (ICD 10 revision). Its use allows you to clean the wound from dead tissue, achieve sustained hemostasis over the entire area of the wound and accelerate the process of reparative regeneration and uncomplicated healing.

The introduction of this method in clinical practice will reduce the duration of treatment and rehabilitation of patients with wounds and burns. It makes it possible to significantly increase the effectiveness of their treatment, accelerate healing processes, reduce the overall hospitalization period, and reduce the frequency of complications of the wound process, i.e. improve immediate and long-term treatment results. It is relatively simple, low-traumatic, one-stage (performed in the course of one procedure), easily feasible.

Claims (1)

A method for treating wounds and burns by exposing them to a plasma beam using a plasma generator, characterized in that the air-plasma treatment of the wound surface is performed by a pulsed plasma beam of atmospheric pressure with a diameter of up to 10 mm, pulse duration 300-500 ns, with an interval of 20-50 μs, the scanning speed of the plasma beam 10-20 mm / s, with an average current of 40-90 μA and create on the wound surface a nanofilm of a coagulated wound exudate protein.