RU2199350C1 - Method and device for treating skin diseases distinguished by discharge - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: method involves applying absorbing bandages containing carbon mixture as sorbent. The absorbing bandage is manufactured from porous bandage material composed of viscose - 66%, polyester - 34%. The bandage is covered with sorbing material layer of carbon mixture. The carbon mixture usable as sorbent is composed of generalized graphite and carbon nanocrystals being nanotubes of 1-10 nm in size having bound radicals C, C₂, C₃, C₄, C₅, and/or radicals being one or several bound hexagonals and/or hexagonals having radicals C, C₂, C₃, C₄, C₅, attached to them. Carbon nanocrystals are added to the mixture in the amount of 10% or more. The sorbing bandage is optionally manufacturable as sterile napkin of 10x10 cm in size. EFFECT: enhanced effectiveness of treatment. 3 cl

Description

 The invention relates to medicine, in particular to the field of therapy of purulent-necrotic skin processes.

 The healing of purulent-necrotic wounds occurs most effectively while ensuring timely removal of non-viable tissues and purulent masses. In this case, the repair processes are completed earlier, the physiological mobility of the tissues is preserved, and the formation of gross scars is avoided. In addition, with spontaneous rejection of non-viable tissues, due to the duration of the process, the patient's organism is intoxicated, irreversible changes in the kidneys, myocardium, and liver can develop.

 The treatment of purulent necrotic wounds with the help of solutions of antiseptics and ointment dressings is traditionally used. Known dressings based on synthetic polymeric materials (Gostishchev V.K., Tolstykh P.I. "Dressings for complex necrolytic, antibacterial and drainage actions based on synthetic polymer materials", Abstracts of the All-Union Conference "Modern approaches to the development of effective dressings" Moscow, 1989, pp. 25-35). These methods are based on the use of dressings that do not have high sorption ability, and, therefore, are not effective enough to remove dead tissue and purulent masses.

 There is also a method of treating purulent necrotic wounds with a sorbent and a device that is a dressing with a sorbent (Shin F.E. “Treatment of purulent wounds of soft tissues with an organophilic sorbent with an aerophile and ultraviolet irradiation”, Materials of the dissertation of Candidate of Medical Sciences, Moscow, 1995 ) The substance used does not have a sufficiently high sorption ability.

 An object of the invention is to increase the effectiveness of the treatment of skin diseases characterized by secretions, by increasing the efficiency of removal of non-viable tissues and purulent masses due to the use of material with high sorption ability.

 The problem is solved in that in the method of treating skin diseases characterized by discharge, including the use of sorbent dressings, a carbon mixture consisting of expanded graphite and carbon nanocrystals is used as the sorbent for the sorbent dressing, and the content of carbon nanocrystals in the mixture is at least 10%.

Moreover, nanocrystals are nanotubes 1-10 nm in size with the attached free radicals C, C ₂ , C ₃ , C ₄ , C ₅ and / or radicals in the form of one or more connected hexagons and / or hexagons with radicals attached to them types C, C ₂ , C ₃ , C ₄ and C ₅ .

 The problem is also solved by the fact that in the sorbent dressing, consisting of a dressing material covered with a layer of sorbent material, the dressing material is made porous and has the composition: viscose - 66%, polyester - 34%, and the sorbent material is a carbon mixture consisting of expanded graphite and carbon nanocrystals, and the content of carbon nanocrystals in the mixture is not less than 10%.

Moreover, nanocrystals are nanotubes 1-10 nm in size with the attached free radicals C, C ₂ , C ₃ , C ₄ , C ₅ and / or radicals in the form of one or more connected hexagons and / or hexagons with radicals attached to them types C, C ₂ , C ₃ , C ₄ and C ₅ .

 In particular, the dressing is made in the form of a sterile napkin measuring 10 • 10 cm.

 A method for the treatment of skin diseases characterized by secretions is the use of sorbent dressings. For the treatment of burn wounds, dressings are used in the period of septicotoxemia, which, as is known, is characterized by suppuration and active rejection of scabs, cleansing of wounds and the formation of granulations, for which autodermoplasty was subsequently performed.

 The collecting dressing is made as follows.

 A layer of synthetic non-woven temporary wound dressing DERMASAFE is used as a dressing. It is a thin porous sterile napkin with a size of, for example, 10 • 10 cm of the following composition: Viskose - 66%, Polyester - 34%. A feature of this type of coating is that the synthetic fibers that form it do not swell when saturated with the wound, so the coating does not prevent the free outflow of the wound through the coating towards the sorbent. In turn, the coating reliably keeps sorbent powder from getting into wounds.

Sorbent is a carbon mixture with great reactivity and sorption ability. Such properties of the carbon mixture are due to the presence of carbon nanocrystals in the form of nanotubes 1-10 nm in size with a large disorder and the fact that in the manufacture of a mixture of natural flake graphite, or graphite in the form of a powder, or other graphite-containing raw material, not only crystallites separate into separate packets basal planes, as with the known methods of manufacturing expanded graphite, but also the breaking of interhexagonal covalent bonds. This leads to the formation of energetically stressed atomic carbon compounds. In addition, the resulting carbon mixture is a hydrophobic material, i.e. does not absorb water and does not combine with water (contact angle greater than 90 ^o ).

 The carbon mixture can be obtained by one of the known methods described in patent RU 2163883, publ. 03/10/2001.

In the manufacture of the carbon mixture, the chemical treatment of the initial graphite-containing raw material (natural flake graphite or graphite in the form of a powder) is carried out by halogen-oxygen compounds of the general formula MXOn, where M is one of the chemicals of the series: H, NH ₄ , Na, K; X is one of the chemicals in the series: Cl, Br, J; an = 1-4, with the formation of initiating complexes capable of exothermic explosive decomposition as a result of photochemical, mechanical, thermochemical, sonochemical or direct chemical exposure followed by the initiation of an autocatalytic decomposition process of the compound. The initiating complexes are introduced into the interlayer spaces of graphite, their explosive decomposition is initiated, and not only the van der Waals bonds are broken, but also the covalent bonds, which leads to the formation of a carbon mixture. When the process is carried out under conditions close to normal atmospheric pressure (760 mm Hg) and room temperature (20 ^° C), carbon nanotubes are formed in a ratio sufficient for efficient sorption (at least 10%). The conversion process is carried out in any capacity (vessel, etc.), including the possible without oxygen.

The process of graphite transformation (breaking of van der Waals bonds) is carried out under the influence of microexplosions of explosives introduced into the interlayer spaces of graphite, in this case called initiating complexes. Explosive is in the interlayer space at the molecular level and is chemically initiated before the explosion. As a result of the energies released by the microexplosion, not only the van der Waals bonds, but also the interatomic bonds are broken with the formation of not only nanotubes, but also free radicals C, C ₂ , C ₃ , C ₄ , C ₅ and radicals in the form of hexagons (one or more) with radicals of the form C, C ₂ , C ₃ , C ₄ and C ₅ attached to them, which together provide a high reactivity of the resulting carbon mixture.

The carbon mixture is a substance in the form of fluff and / or dust with a mass content of carbon of 99.4%, bulk density from 0.002 g / cm ³ to 0.01 g / cm ³ , pore sizes up to 40 microns.

 The microstructure of the carbon mixture is a granule having an elongated fibrous structure (similar to a bast) on the surface with a fiber diameter of the order of units or even fractions of a micron.

 The dressings are sterilized by autoclaving along with the rest of the dressing according to standard procedures.

 A preclinical evaluation of the wound healing effect of the carbon mixture was made. Research was conducted at the Center for Extreme Medicine Federal State Unitary Enterprise.

 Morphological study of the biopsy material of the wound surfaces of experimental rats showed that in the treatment of experimental purulent wounds according to the proposed method using a sorbent in the form of a carbon mixture, repair processes in the tissues are activated in comparison with the treatment with traditional methods (antiseptic solutions and ointment dressings), which last 30 days after the start of treatment of wounds, there is a prolongation of inflammatory processes. The use of the proposed sorbent in the treatment of purulent wounds of rats positively affects their healing. Having a large sorption capacity, the drug reduces tissue swelling and leads to early purification of the wound surface from purulent necrotic masses, which in turn provides the opportunity to develop full-fledged granulation tissue and marginal epithelization 5 days earlier than in the comparison group.

 A cytological study of smear prints of wounds of rats treated with the proposed drug indicates the effective influence of the carbon sorbent on the dynamics of acute inflammation.

 Microbiological studies in vitro and in vivo showed that the carbon sorbent effectively affects the degree of microbial contamination of purulent wounds in the experiment, causing the creation of a wound environment that is unfavorable for the active vegetation of the microbial flora.

 Thus, the positive effect of the proposed method of treatment and sorbent dressing on the dynamics of microbial contamination of the wound, clinical manifestations and morphological features of the wound process in laboratory animals with a purulent wound was revealed.

 The impact of the proposed method of treatment and sorbent dressing on the dynamics of clinical manifestations and morphological features of the wound process in laboratory animals with a burn wound was also positively evaluated.

 In rats treated with antiseptics and ointment dressings, a pronounced (25% of normal) decrease in the number of reticulocytes was noted by the end of the 2nd week of observation. Since this decrease occurred against the background of progressive anemia (a decrease in the number of red blood cells by 20% by 28-30 days of treatment), it can be assumed that the regenerative processes of bone marrow hematopoiesis are inhibited. At the same time, reticulocytosis was noted when the burn wounds were closed with a carbon sorbent. Apparently, carbon-containing materials, when applied to wound surfaces due to their high sorption activity, provide an antitoxic effect.

 Characteristic is the dynamics of leukocytosis. In rats of the control group, it was more pronounced and remained at a high level for a long time. The use of a carbon sorbent caused the normalization of leukocytosis much earlier than in the control group.

 Thus, the use of the proposed sorbent in the treatment of experimental burn wounds in rats can significantly reduce the number of deaths in animals and reduce treatment time.

 A clinical study of the proposed method of treatment and sorbent dressing was also conducted. The study was conducted at the Research Institute of Emergency Medicine. I.I. Janelidze.

 A clinical trial was carried out on a group of 8 victims aged 24 to 56 years (5 men and 3 women). The total area of burn wounds in patients of this group ranged from 17% to 64%, and the area of deep burns of grade 4–4 degree burns ranged from 1.5% to 57% of the body surface. In all cases, the use of sorbent dressings was carried out in the period of septicostemia. The terms of application of dressings ranged from 12 to 47 days from the moment of injury. In a number of observations, sorbent dressings were applied to burn wounds of the IIIA degree, capable of self-epithelialization. Dressings were used mainly on wound sites with the most purulent discharge and were fixed in several rounds of bandage.

 Tests have shown that in terms of the main physical parameter (sorption capacity), the proposed sorbent is superior to a gauze multilayer dressing. It is shown that the carbon mixture as a sorbent can be used in medical practice in the treatment of not only burns, but also purulent wounds, fistulas and other situations characterized by significant discharge.

Claims (3)

1. A method of treating skin diseases characterized by discharge, including the use of sorbent dressings, characterized in that the carbon mixture consisting of expanded graphite and carbon nanocrystals, which are nanotubes 1-10 nm in size, are attached to the sorbent dressing free radicals C, C ₂ , C ₃ , C ₄ , C ₅ and / or radicals in the form of one or more connected hexagons and / or hexagons with radicals of the form C, C ₂ , C ₃ , C ₄ and C ₅ attached to them , reason the content of carbon nanocrystals in the mixture is at least 10%. 2. A sorbent dressing, consisting of a dressing material coated with a layer of sorbent material, characterized in that the dressing is porous and has the composition: viscose - 66%, polyester - 34%, and the sorbent material is a carbon mixture consisting of expanded graphite and carbon nanocrystals, which are nanotubes 1-10 nm in size, with attached free radicals C, C ₂ , C ₃ , C ₄ , C ₅ and / or radicals in the form of one or more connected hexagons and / or hexagons with pr and radicals of the form C, C ₂ , C ₃ , C ₄ and C ₅ connected to them, and the content of carbon nanocrystals in the mixture is at least 10%.  3. The sorbent dressing according to claim 2, characterized in that it is made in the form of a sterile towel 10x10 cm in size.