EA029103B1 - Biological wound cover - Google Patents

Abstract

The invention relates to medicine, particularly medical biotechnology, and may be applied for producing biological wound covers of prolonged healing action due to silver particles included therein. Technical result is achieved by formation of biological wound cover based on natural material and containing silver, wherein the natural material is collagen-elastin matrix, obtained from bovine peritoneum after elimination of cells followed by impregnation of silver micro particles using a photochemical reaction; the said peritoneum is treated with 0.25, 0.5 or 1% silver nitrate solution and exposed to UV lighting for 10 min. Elimination of donor cells can significantly reduce immunogenicity of the implant, and also can reduce risk of post-implantation inflammation, necrobiosis, or any other degenerative process initiated by recipient's immune system. Impregnation of xenogenic peritoneum with silver can significantly increase sterility and antimicrobial action of the proposed cover. Silver particles are impregnated therein both on tissue surface, and amidst collagen filaments and fibres.

Description

The invention relates to medicine, in particular to medical biotechnology, and can be used to obtain biological wound coatings with a prolonged therapeutic effect due to the silver particles contained therein. The technical result is achieved by creating a biological wound coating based on a material of natural origin containing silver, the material of natural origin being a collagen-elastin matrix obtained by removing cells from the peritoneum of cattle with microscopic silver particles impregnated by photochemical reaction, the peritoneum is treated with 0.25, 0 , 5 or 1% solution of silver nitrate and subjected to ultraviolet irradiation for 10 minutes. Removal of donor cells leads to a significant reduction in the immunogenicity of the implant, and also reduces the risk of post-implantation inflammation, necrobiosis, and other degenerative processes triggered by the recipient's immune system. Impregnation of silver xenobacterium significantly increases the sterility and antimicrobial activity of the proposed coating. At the same time, silver particles are impregnated both on the surface of the fabric and among collagen fibers and fibrils.

029103

The invention relates to medicine, in particular to medical biotechnology, and can be used to obtain biological wound coatings with a prolonged therapeutic effect due to the silver particles contained therein.

Silver is one of the key components actively used in the healing of wounds, burns and trophic ulcers. It has a broad spectrum of antimicrobial action against a significant number of gram-positive and gram-negative bacteria. It has been proven that silver ions have an antibacterial effect against 150 strains of bacteria and simple fungi.

A silver-containing dressing coating of natural origin is known, cellulose material is used as a material of natural origin, which is impregnated with an aqueous solution of 0.25-2.0 wt.% Ά§ΝΘ ₃ and the ratio of cellulosic material: solution Ά§ΝΘ ₃ 1 g per 15-30 ml. The reaction mixture is heated at 85-150 ° C for 1-4 hours. To increase the silver content in an aqueous 0.25-2.0 wt.% Solution Ά§ΝΘ _3, ammonia, glycerin, or a mixture of ammonia and glycerin are added at a concentration of ammonia 0.5–15% by volume, glycerol concentration 20–50 wt%, the ratio of cellulosic material: aqueous solution is 1 g per 15–30 ml, and the reaction mixture is heated at 85150 ° C for 1–4 h (patent Of the Russian Federation No. 2256675 IPC C08B 1/02. A method of obtaining silver-containing cellulosic materials (2005).

A disadvantage of the known wound cover is that it does not rarely cause irritation of the wound surface and allergy due to the products of thermochemical decomposition of chemical reagents and microcrystalline cellulose contained therein and, as a result, has insufficient biological activity to the pathogenic flora.

The objective of the invention is the creation of organic natural wound dressing with high sterility and biological activity to the pathogenic environment.

The technical result is achieved by creating a biological wound dressing (PDU) based on a material of natural origin containing metal particles having biological activity in the pathogenic flora, and cattle-free peritoneum is used as a material of natural origin, and microscopic silver particles that are applied by photochemical reaction.

The novelty and significant difference of the claimed invention is the use of de-celled peritoneum of cattle impregnated with silver.

In the scientific, medical and patent literature similar biological wound coatings have been identified.

Cattle peritoneum is an affordable and cheap material, as it is a by-product of animal slaughter and is not used for food or other purposes. Unlike smaller animals, cattle can produce large sheets of peritoneum, which is convenient in the manufacture of coatings of different formats. The advantage of xenogenic peritoneum is low cost, accessibility, hygroscopicity, bactericidal, elasticity, resistance to mechanical stress, biodegradation.

To reduce the antigenic properties, eliminate possible rejection reactions, increase the shelf life of the biological wound cover, de-agglomeration of the xenogenic peritoneum is performed, leaving the connective tissue framework. Removal of donor cells leads to a significant reduction in the immunogenicity of the implant, and also reduces the risk of post-implantation inflammation, necrobiosis, and other degenerative processes triggered by the recipient's immune system.

Impregnation of silver xenobacterium significantly increases the sterility and biological activity of the proposed coating. The presence of microscopic particles provides a higher activity of silver, and the method of applying silver particles by the photochemical reaction method ensures the sterility of the coating. The desired result of the invention is enhanced by the manifestation of the electrochemical potential between silver particles in the presence of a liquid, for example, wound exudate or medicinal solutions and aerosols. At the same time silver particles are impregnated both on the surface of the fabric and among collagen fibers and fibrils.

In the scientific, medical and patent literature analogues have not been identified.

The invention is as follows. The optimal for use is the parietal peritoneum of the cattle, it is convenient for the production of large sheets of wound coverings of various thicknesses, the peritoneum is thicker in the pelvic region, the peritoneum has a thinner structure on the abdominal wall. The peritoneum is descaled by the detergent-enzymatic method, while the thick peritoneum requires three processing cycles by the detergent-enzymatic method, and for a thin one, one cycle is sufficient.

The prepared collagen-elastin matrix represents layers of de-cellular xenobryushin of cattle with the size of 10x10, 10x15 cm. To enhance the antibacterial activity to the microflora, the collagen-elastin framework was impregnated with silver. To obtain a biological coating — a carrier of silver particles — a method of impregnating silver particles into peritoneum samples by the method of photochemical reaction was applied. Given fotonestabilnost silver nitrate, soaked in the peritoneal structure Ά§ΝΘ ₃ was subjected to ultraviolet irradiation. At the same time, the decay of Ά§ΝΘ ₃ occurred with the result of 1 029103

the division of microscopic silver particles into the peritoneal tissue.

The remaining silver nitrate, which did not react, was removed by repeated washing with sterile distilled water with quality control washing with some chloride (silver nitrate when interacting with chloride ion - forms a white precipitate or dregs in small concentrations).

The mechanism of obtaining collagen-elastin matrix with silver particles.

Samples of the collagen-elastin matrix were washed from the physiological solution with distilled water 3 times, dried between two sheets of filter paper, then immersed in a solution of silver nitrate concentration of 0.25; 0.5; 1.0% for 30 min. After that, the liquids were allowed to drain and the peritoneum samples were straightened on Petri dishes. Then, expanded peritoneum samples were irradiated with ultraviolet light for 10 minutes. Samples of the peritoneum were turned over by the other side and irradiated again. After that, the xeno-peritoneum (CB) samples were washed with distilled water 3 times until the reaction to chlorides was negative (the water after washing should not form turbidity in reaction with sodium or potassium chloride). A sample of an extracellular thick QB of 10X15 cm in size after silver treatment is shown in FIG. one.

Morphological and ultrastructural analysis showed that silver particles were impregnated both on the surface of the fabric and among fibers and collagen fibril in the form of single particles and clusters (Fig. 2, 3).

Measurement of the adsorption activity of samples of CB to silver particles was carried out in the following sequence.

In order to study the adsorption capacity of samples of thick CBs with respect to silver particles, samples of 1 cm ² in size were immersed in 0.25; 0.5 and 1% silver nitrate. Then it was treated with ultraviolet light before visual darkening and subsequent washing. Then drying was carried out at 90 ° C for 2 hours and 4 hours at 100 ° C in order to remove all the water from the sample. After that, the samples were subjected to "wet" burning in concentrated nitric acid. The samples were placed in a Teflon container; in a special autoclave, the 8 \\ a \ ue M ^ 3-2 ppsgo \ uaye autoclave - 5 in 1 ml of concentrated nitric acid at 190 ° С. Then the resulting liquid was adjusted to 50 ml with bidistilled water and then used for analysis.

A standard silver sample (MSO of silver ion No. 0131/2000; 0.1 mg / cm ³ , Russia) was calibrated. The calibration data is presented in FIG. four.

Further, the samples were analyzed on an atomic absorption spectrometer (AAA1uk1 400, Retksh E1teg). According to the results of the analysis, the silver content was calculated on 1 cm ² surface on average. The analysis was performed four times. The data presented in Table. one.

The results of atomic absorption spectrometry showed that the sorption capacity of the peritoneum is not directly dependent on the concentration of the solution in which the exposure takes place. But it can be said that using a 1% solution of Α§ΝΘ ₃ per 1 cm ^2, at least 20 μg of silver precipitates.

Evaluation of the effectiveness of the coating was carried out on the basis of microbiological and clinical observations.

Determination of the antimicrobial activity of PDUs in relation to freshly isolated hospital strains of pathogenic and conditionally pathogenic bacteria was carried out by the disk diffusion method according to the guidelines - MUK 4.2.1890-04 "Determination of the sensitivity of microorganisms to antibacterial studies."

The following freshly isolated clinical strains of microorganisms were used to determine the antimicrobial activity of the BRP: 31yrossosykiteite, 3 aryu1osossikerIergieE. Ezhegossossik Haesayk, Eksyepsoy Soi, Kiteykle11a rpeitosh, Rtoileyk TyaYyk, Asscheyuyastet yaitappy, Rkeitopak aegidskhok, SapFya a1Sasp5.

As the results of studies shown in Table. 2, the zones of growth retardation near the discs from the PDU with silver with the growth of 311й1osossik er1Itsh1Y1K (18 and 19.5 mm) and 3! Aryu1osossikiteiik (18.5 and 19.5 mm) are almost the same. Of the gram-negative microorganisms, the zones of growth inhibition with the growth of Psiiyotopak aytsidsok (18.2 and 16.5 mm) and Exiepsy (17.5 and 16.5 mm) are also almost equal. Zones of growth retardation up to 10 mm are observed with growth of Rtoleik TyAyk and Asscheyu Yastet yaitappy. With the growth of SapFya a1Sapk, growth retardation zones of 14.5 and 15.5 mm are noted.

The difference in the zones of growth inhibition of microorganisms around the discs prepared from wound coatings with a silver concentration of 0.25 and 0.5% is also within the limits of statistical error.

The dynamics of the wound process was controlled by clinical data - relief of inflammation, microbial contamination, engraftment of the skin graft, wound healing.

An example of a specific implementation.

The patient, born in 1955, case history No. 1867, was hospitalized from 03/26/2014 to 04/09/2014. Diagnosis: Giant ulcer of the posterior surface of the right tibia, heel region. Necrosis of the Achilles tendon. Condition after open fracture of the ankles, calcaneus from November 2013

Sick since November 2013: after injury - an open fracture of the ankles, calcaneus to the right. AT

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subsequently appeared an ulcer on the skin of the right leg. He was treated permanently at the place of residence without effect. In recent months, there has been a progression of the disease - the ulcer gradually increases in size and deepens.

Locally: there is an ulcer on the right tibia in the middle and lower third along the back surface to the heel region, sizes up to 15x10 cm, pale, dense granulations, 5,52 cm necrotic tendon fibers on the bottom of the wound. There is marked perifocal hyperemia around the wound. Poor purulent discharge with blue-green staining. On palpation, pain and stiffness of the surrounding tissues is noted. The pulsation of the arteries at all levels is not disturbed. Veins of both lower limbs without magnification.

Bacterial seeding (03/26/14) - Rzeiboshopaz aegidtozae 10 ⁷ CFU.

03/28/14, the operation was performed: surgical treatment of the granulating wound of the right tibia. Transplantation of KB with microparticles of silver. The essence of the operation was the surgical treatment of the granulating surface. To suppress microflora, prevent drying and deepening the wound, prevent infection, a collagen-elastin matrix with silver microparticles is transplanted onto the wound surface. The graft is fixed on the surface of the wound with metal brackets.

In the postoperative period, a decrease in pain. No pus.

Bacterial seeding (03/31/14) - Euillobacter aegenese 10 ³ CFU. 81yriosossiz zargoryucsiz 10 ³ CFU.

When viewed from the wound under the collagen-elastin matrix with flat bright pink granulations. No pus.

04/02/2014, the operation: autodermoplasty wounds of the right leg.

The postoperative period was uneventful. Engraftment of grafts is complete. At discharge wounds no.

During the experimental and clinical studies, the ability of the collagen elastin matrix with silver particles to maintain the optimal microclimate for the wound, reduce the loss of beneficial substances through the wound surface, the effect of reducing bacterial contamination of wounds, burns and trophic ulcers as a result of the action of silver microparticles was confirmed.

Table 1

Sorption capacity of KB in relation to silver

ΑβΝΟ ₃ solution 0.25% 0.5% one% Amount of silver µg / cm ² 7.93 ± 0.09 19.63 ± 0.05 21.82 ± 0.03

table 2

Antimicrobial activity of BRP with silver

View Type of PDU under study Silver 0.25% Silver 0.5% microorganism The number of the experiment (growth inhibition zone m / o in mm) but I II III IV The average I II III IV The average 81Lo1osossiz aigeis nineteen 20 17 18 18.5 20 21 18 nineteen 19.5 81Ay1, ep1 <ZegpisNz 20 17 17 18 AND 20 nineteen nineteen 20 19.5 Eshegossiziz HaesNz ten eleven 15 12 12 ten 12 13 12 11.7 ESSENTIAL SOON 20 sixteen sixteen 18 17.5 18 17 15 sixteen 16.5 Klebsleya rpeitote eleven 13 13 12 12.2 14 14 13 13 13.5 Roelois gshgaNz 7 eight 7 eight 22 7 9 eight eight eight Rezaisotopaz aegifposa 20 18 sixteen nineteen 18.2 18 17 15 sixteen 16.5 Astelobosteer Baitapp eleven 9 9 ten 22 ten eleven eight 9 92 SapsMa a! ysapz 15 14 15 14 14.5 sixteen 15 sixteen 15 15.5

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Claims (2)

CLAIM 1. Biological wound coating based on material of natural origin, containing silver, characterized in that the material of natural origin is a collagen-elastin matrix obtained by removing cells from the peritoneum of cattle with microscopic silver particles impregnated by photochemical reaction. 2. The biological wound coating according to claim 1, characterized in that said peritoneum is treated with 0.25, 0.5 or 1% silver nitrate solution and subjected to ultraviolet irradiation for 10 minutes. A sample of obesecellular thick peritoneum - 10x15 cm in size after treatment with silver solution