RU2804996C1 - Method of three-stage dispersed hydropressive debridement - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to methods of local treatment of wounds, and is intended for sanitation of superficial and deep wounds with a large area of the wound surface. The method is performed in three stages using a modified UGOR-01M device. The first stage is cleaning the surface of the wound with a jet of 0.9% NaCl solution under a pressure of 7 atm at an angle of 90° to the surface of the wound, at a distance of 5 cm from the nozzle of the device to the wound, the duration of treatment is 2 seconds per 1 cm² of the area of the wound surface. The second stage is cleaning the surface of the wound with a jet of 0.5% chlorhexidine solution under a pressure of 7 atm at an angle of 45°, at a distance of 2 cm from the nozzle of the device to the wound, the duration of treatment is 2 seconds per 1 cm² of the area of the wound surface. The third stage is the treatment of the wound surface of the center of the wound to the periphery with a jet of 0.9% NaCl solution under a pressure of 5 atm at a distance of 8 cm from the nozzle of the device to the wound, at an angle of 30° up to 60° to the plane of the wound, the duration of treatment is 5 seconds per 1 cm² of the surface of the wound.

EFFECT: method is easy to perform, does not require any expensive equipment and medicines, provides high-quality sanitation of superficial and deep wounds with a large area of the wound surface, removal of large foreign bodies and necrotic tissues, has a pronounced antiseptic effect in combination with stimulation of regional blood circulation, reduces the time of regeneration of soft tissues.

1 cl, 2 tbl

Description

The method relates to medicine, namely to surgery, and is intended for the sanitation of superficial and deep wounds with a large area of the wound surface.

Treatment of extensive infected open wounds is a difficult task, since high-quality, uniform, one-step cleaning of the entire surface of the wound from both anesthetized tissue and bacterial colonies is difficult. In conditions of a large surface area and disruption of the microvasculature, the delivery of leukocytes to every point on the surface is difficult, while colonies of pathogenic microorganisms quickly grow, forming a bacterial film that makes it difficult to properly treat the wound from the outside. A qualified choice of pressure power and duration of exposure to the sanitation jet is extremely important for the destruction of biofilms on the wound surface.

Today, in medical, in particular in surgical practice, methods for treating purulent wounds are widespread, based on the use of antiseptic solutions of various concentrations, not all of them are indifferent to the body’s own injured tissues and are aggressive only to pathogenic microflora.

There is a known method for the treatment of purulent-inflammatory processes in closed cavities and wound infections [patent RU 2257201]. An aqueous solution of chlorhexidine is used, saturated by bubbling with carbon dioxide, which is fed into the wound with its simultaneous evacuation from the wound along with the wound discharge; In this case, sanitation is carried out in two sessions per day for 10-20 minutes. This method promotes mechanical cleansing of the wound surface, effective microbial decontamination, and improvement of proliferative processes.

However, the method has a narrow range of applications and an insufficient degree of cleaning the wound surface from purulent-necrotic tissue.

There is a known method for complex surgical treatment of diabetic foot syndrome complicated by a purulent-necrotic process [patent RU 2405472]. On the 2nd day after surgery, the wound is sequentially exposed to a jet of 0.06% sodium hypochlorite solution (NaCLO) at a concentration of 800 mg/l, in combination with low-frequency ultrasound for 10-15 minutes, then the wound is isolated from the external environment with using a closed elastic container and also injected with proteolytic enzymes - trypsin and chymotrypsin, 50 mg of each enzyme, dissolved in 200 ml of 0.9% saline solution for 1.5 hours, then over the wound for 3 hours, create a negative pressure of 70-80 mm Hg. with active vacuum aspiration. The method makes it possible to improve the quality of wound cleansing, increase blood flow in the wound walls, and stimulate regenerative processes, however, this method is highly expensive and requires the presence of an installation with ultrasonic waves.

An analogue of the developed method is a two-stage method for treating soft tissue wounds using a device for dispersed treatment of soft tissue wounds “UGOR-01M” [patent RU 2068263; Treatment of wounds / Bulynin V.I., Glukhov A.A., Moshurov I.P. Voronezh, 1998. - P. 188-189]. Dispersed treatment of the wound surface is carried out in two stages. At the first stage, the surface of the wound is cleaned with a jet of 0.9% NaCl solution, with a maximum output pressure of about 5-7 atm, at an acute angle of a distance of 2-5 cm from the nozzle to the treated tissue, for 1-2 seconds per 1 ^cm2 area of the wound surface. At the second stage of dispersed processing, a jet of 0.9% NaCl solution is used with an output pressure of up to 5 atm. Treatment is carried out from a distance of 5-8 cm, lasting 4-5 seconds per 1 cm ² of the wound surface, at an angle of 300-600 to the plane of the wound. The use of the method of dispersed sanitation of wounds makes it possible to speed up the cleansing of the wound from purulent-necrotic tissues and reduce the rigidity of its walls, but this method does not provide the necessary antiseptic effect.

The technical result is ensuring high-quality sanitation of superficial and deep wounds with a large area of the wound surface, removal of large foreign bodies and necrotic tissue, a pronounced antiseptic effect in combination with stimulation of regional blood circulation, reducing the time of soft tissue regeneration.

The method of three-stage dispersed hydropressive debridement of the wound surface was carried out in three stages using the UGOR-01M device.

The first stage ensures the removal of large foreign bodies and necrotic tissues and includes cleaning the wound surface with a jet of 0.9% NaCl solution under a pressure of 7 atm. The treatment was carried out at an angle of 90° to the wound surface, at a distance of 5 cm from the device nozzle to the wound. The duration of treatment was 2 seconds per 1 cm ² of wound surface area.

At the second stage, microbial bodies are removed by cleaning the surface of the wound with a jet of 0.5% chlorhexidine solution under a pressure of 7 atm. The treatment was carried out at an angle of 45°, at a distance of 2 cm from the device nozzle to the wound, for 2 seconds per 1 cm ² of the wound surface area.

The third stage is aimed at thoroughly treating the surface of the wound, performing tissue hydromassage and stimulating regional blood circulation. A jet of 0.9% NaCl solution was used under a pressure of 5 atm. The treatment was carried out at a distance of 8 cm from the device nozzle to the wound, which allows for the creation of a dispersed jet of solution and preservation of the kinetic properties of the flow. The duration of exposure of the liquid jet to the tissue is 5 seconds per 1 cm ² of the wound surface. With this type of exposure, the jet was directed at an angle of 300 to 600 to the plane of the wound, from the center of the wound to the periphery.

Experimental studies were carried out on 36 animals, white rats of the Wistar line, in 3 groups - 1 experimental and 2 control, numbering 12 individuals each, with strict adherence to the norms and rules of humane treatment of animals.

Before the start of the experiment, all animals were put under ether anesthesia, then their limbs were fixed to the ledges of a small operating table for experimental studies on small laboratory animals.

Modeling of purulent wounds was carried out according to the modified method of I.A. Sychennikova [Sychennikov I.A. // Modeling, methods of study and experimental therapy of pathological processes. M., 1974. - P. 69-73]: under general anesthesia (ether anesthesia) on a section of the outer surface of the middle third of the thigh shaved from fur, after treating the skin with an antiseptic solution, a linear skin incision was made with a disposable medical scalpel along the outer surface of the middle third of the thigh, fascia and muscles, cm long. Soft tissues were separated with a clamp. The edges and bottom of the wound were crushed using a Kocher clamp. A gauze swab weighing about 0.5 g with a suspension of a daily culture of Staphylococcus aureus at a dose of 1010 microbial bodies in 1 ml of 0.9% sodium chloride solution was introduced into the wound. After this, adaptation sutures were placed on the skin using silk thread. When macroscopically assessing the dynamics of the wound process on the first day after infection, signs of inflammation were noted: the edges of the wounds were hyperemic, swollen and hardened. On the second day of infection, an increase in hyperemia and swelling of the skin is observed; in the spaces between the sutures, when pressing on the wound, a small amount of serous-purulent exudate is released. On the third day, hyperemia, swelling, tissue infiltration progresses, and copious purulent discharge is noticeable. The sutures were removed by spreading the edges of the wound and removing the gauze swab; at the same time, 1.0-1.5 ml of pus was released. As a result, a purulent wound with an average size of 1.0×0.5 cm was obtained, after which treatment began.

To treat the wound surface in all groups, a modified UGOR-01M device was used.

In the 1st control group, daily one-stage hydropulse sanitation of the wound surface was performed with a 0.9% NaCl solution. A jet of 0.9% NaCl solution was used under a pressure of 7 atm. The treatment was carried out at an angle of 90° to the wound surface, at a distance of 5 cm from the device nozzle to the wound. The duration of treatment was 2 seconds per 1 cm ² of wound surface area.

In the 2nd control group, daily two-stage hydropulse treatment was performed. The first stage is cleaning the surface of the wound with a jet of 0.9% NaCl solution under a pressure of 7 atm. at an angle of 90° to the wound surface, at a distance of 5 cm from the device nozzle to the wound. Treatment duration is 2 seconds per 1 cm ² of wound surface area. The second stage is cleaning the surface of the wound with a jet of 0.5% chlorhexidine solution under a pressure of 7 atm. at an angle of 45°, at a distance of 2 cm from the device nozzle to the wound. Treatment duration is 2 seconds per 1 cm ² of wound surface area.

In the 1st experimental group, a three-stage dispersed hydropressive debridement method was used. The first stage is cleaning the surface of the wound with a jet of 0.9% NaCl solution under a pressure of 7 atm. at an angle of 90° to the wound surface, at a distance of 5 cm from the device nozzle to the wound. Treatment duration is 2 seconds per 1 cm ² of wound surface area. The second stage is cleaning the surface of the wound with a jet of 0.5% chlorhexidine solution under a pressure of 7 atm. at an angle of 45°, at a distance of 2 cm from the device nozzle to the wound. Treatment duration is 2 seconds per 1 cm ² of wound surface area. The third stage is treating the surface of the wound from the center of the wound to the periphery with a stream of 0.9% NaCl solution under a pressure of 5 atm. at a distance of 8 cm from the device nozzle to the wound, at an angle of 300 to 600 to the plane of the wound. Treatment duration is 5 seconds per 1 cm ² of wound surface.

The study of effectiveness was assessed using objective indicators: necrolysis, hyperemia, edema, appearance of granulations (Table 1); and planimetric indicators: wound area and the rate of its decrease during the day (Table 2).

When using three-stage dispersed hydropressive debridement, there was a reduction in the duration of hyperemia by 1.4 times, edema by 1.5 times, and the appearance of granulations by 1.9 times in comparison with the 1st control group.

When assessing the dynamics of changes in the area of the wound surface in the control and experimental groups, a decrease in the wound surface on the 7th day after the start of the use of three-stage dispersed hydropressive debridement was noted by 1.8 times in comparison with the 1st control group.

Morphological analysis was also carried out. On days 1, 3, 5 and 7 after the start of treatment, material was collected for histological examination. For microscopic examination of inflammatory changes, immunohistochemical staining of tryptase TK (ab2378, dilution 1:2000) was performed. On the first day after the start of treatment, no significant differences were observed in the control and experimental groups. However, already on day 3, a two-fold decrease in the number of mast cells in the field of view of tissue from the wound area was noted in the first experimental group compared to the control group. The result obtained demonstrates the relief of inflammatory changes and the absence of infection in the wound.

Claims (1)

A method of three-stage dispersed hydropressive debridement, using a modified device "UGOR-01M", including the stage of removing large foreign bodies and necrotic tissues from the surface of the wound with a stream of 0.9% NaCl solution under a pressure of 7 atm at an angle of 90° to its surface of the wound, at a distance from the device nozzle to the wound 5 cm, the duration of treatment was 2 seconds per 1 cm ² area of the wound surface, the stage of removing microbial bodies and cleaning the wound surface with a jet of 0.5% chlorhexidine solution under a pressure of 7 atm, at an angle of 45° at a distance of 2 cm from device nozzles to the wound, for 2 seconds per 1 cm ² area of the wound surface, characterized in that additionally hydromassage of tissues and stimulation of regional blood circulation are carried out with a jet of 0.9% NaCl solution under a pressure of 5 atm, a distance of 8 cm from the device nozzle to the surface of the wound , the duration of exposure of the liquid jet to the tissue is 5 seconds per 1 cm ² of the wound surface, the direction of the jet is at an angle from 30° to 60° to the plane of the wound, the movement of the jet is from the center of the wound to the periphery.