RU2198685C1 - Medicinal polymeric gel material and curative preparations made upon its basis - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: the innovation deals with synthetic polymeric gel material of medicinal indication and curative products based upon this material, particularly, binding means for treating wounds, skin lesions including thermal ones (burns, frostbites); trophic ulcers of different etiology (diabetic, venous, posttraumatic and others); for applications in oncological patients after irradiation; moreover, this material could be used in cosmetology. Polymeric gel material is an organoinorganic hybrid - product of combination of siliconcontaining product and water-soluble synthetic organic polymer into integrated structure. Material is obtained due to structurally-chemical transformations in aqueous polymeric solutions at addition of either sols of polysilicic acid and alkaline agents (for example, ammonium hydroxide) or different ethers of orthosilicates both in combination with each other and individually similar to the well-known methods. Developed material as a single matrix, as a rule, is absolutely transparent and possesses high elastic properties. Matrix could be either soft, of average density or solid. Material is nontoxic, biocompatible, could modulate the surface of any shape and fill any cavity, it could, also, be the foundation to immobilize biologically active additives, enzymes, medicinal and cellular forms. Gel material suggested could be applied either individually or upon any foundation, for example, tricot or polymeric netting. EFFECT: higher efficiency. 8 cl, 3 ex, 2 tbl

Description

 The invention relates to medicine, namely to synthetic polymer gel materials for medical purposes and to therapeutic agents based on it, in particular to dressings for the treatment of wounds, skin lesions, including thermal (burns, frostbite); trophic ulcers of various etiologies (diabetic, venous, post-traumatic, etc.); for applying applications to cancer patients after irradiation; in addition, to drainage materials, semipermeable membranes; also this material can be used in cosmetology.

 There is a whole class of combined lesions, including those associated with exposure to chemical, mechanical, thermal factors, as well as ionizing radiation. Features of wound healing are determined by quantitative, but not qualitative differences, and in all cases, the same cellular elements that determine the dynamics of the wound process (inflammation, proliferation of granulation tissue and epithelization) take part in the wound healing process. Marked violations of local homeostasis, microcirculation, the presence of necrotic tissue and the inevitable bacterial contamination of wounds cause a more pronounced inflammatory reaction, the development of various forms of wound infection, which leads to a protracted course of the wound process. The healing of such wounds is usually stretched for a longer time than with mechanical trauma and occurs according to the option of secondary tension.

 Unlike conventional sorption dressings (gauze, cotton-gauze, non-woven materials, polymer sponges), which establish a dynamic balance of microflora concentration at the wound-dressing border, biologically active gel dressings provide a plasticizing effect on wound tissues, soften necrotic formations diffuse under them, facilitating the mechanical removal of non-viable tissues, and prevent the development of infection on the surface of the wound under the scab. They create a moist environment on the wound that is optimal for the normal course of regeneration processes. Due to the cooling effect of the gel dressings and, accordingly, lowering the local temperature of the underlying tissues, conditions are created that prevent the development of pyogenic infection in the wound. Hydrogel contributes to the elimination of exudate, the suppression of microflora.

 Currently known methods of treating skin lesions, such as burns and wounds by applying various gel preparations with therapeutic activity (RU 2157243 C1, publ. 10.10.2000, EP 0055397 A, publ. 07.07.1982, WO 96 / 33748 A, publ. 10/31/1996). The structural basis (matrix) of these preparations is most often linear water-soluble polymers (poly-N-vinylpyrrolidone, polyethylene glycol, polyvinyl alcohol, polyacrylamide) and / or natural (alginates, collagen) polymers. They are used either in the form of a solution or in the form of a chemically cross-linked gel (due to the formation of covalent or ionic bonds). The former do not have sufficient strength to use them as a dressing without supporting tissue or mesh, and obtaining others in the form of hydrogel preparations is a rather complicated operation involving toxic starting components that make it difficult to introduce physiologically active substances into the hydrogel matrix. These drugs often cause a local allergic reaction or do not have sufficient air vapor permeability, which exacerbates the pathological process.

 The objective of the present invention is to provide a universal polymer gel medical material, which makes it possible to easily immobilize various drug substances into the network structure by the method of its preparation and physicochemical properties. Synthetic films based on the proposed material are intended to create an optimal healing environment in the wound, as well as to absorb exudate in an amount sufficient to prevent its accumulation, but not so much that the wound dries.

 The present invention provides an improved biocompatible polymer gel material, which can be used to treat various mechanical, chemical, thermal damage to the skin, trophic ulcers of various etiologies, as well as in combination with appropriate hemostatic agents (e.g. thrombin) to stop capillary bleeding, as well as for closing donor skin with dermoplasty.

 The polymer gel material is an organo-inorganic hybrid - the product of combining a silicon-containing product and a water-soluble synthetic organic polymer into an integrated structure. The material is obtained by structural-chemical transformations in aqueous solutions of polymers by adding to them either sols of polysilicic acid and alkaline agents (for example, sodium or ammonium hydroxides) or various esters of orthosilicates, both in combination with each other and independently by analogy with lime methods (1,2), in contrast to which the present material has improved physical and mechanical properties.

The formation of transparent hydrogel matrices with controlled sorption and physico-mechanical characteristics is facilitated by multiple hydrogen bonds between the functional groups of the macromolecules of the organic polymer and the silicon-containing product, resulting from the processes of structure formation under mild conditions. Gelation does not require chemical reactions involving toxic crosslinking agents, the use of extraneous ions (e.g., Ca ²⁺ ) and high pH values that are very different from physiological ones. It is significant that the introduction of the necessary medicinal substances can be carried out directly at the stage of gel formation or absorb them with the finished material from the solution. The prolonged release of drug substances (diffusion characteristics of the gel material) is regulated by a change in the nature, concentration, molecular weight of the polymer and the ratio between the components.

 At least one of the synthetic water-soluble polymers, for example poly-K-vinylpyrrolidone (PVP), poly-M-vinylcaprolactam (PVCL), polyvinyl alcohol (PVA), hydroxypropyl cellulose (OPC), etc. can be used as an organic component. Silicon-containing precursors can be various esters of orthosilicates, for example tetramethoxysilane (TMOS), or sols of polysilicic acid, for example Sialite-30. Table 1 and 2 provide specific examples indicating the ingredients used and their ratio.

 The created material in the form of a single matrix, as a rule, is absolutely transparent, has good elastic properties. The matrix can be soft, medium density and hard depending on the quantitative characteristics of the number of gel nodes, which are determined by the nature of the components and their concentration. The concept of gel knots promises areas of both physical interweaving of macromolecules with each other, as well as points of interaction between organic and inorganic polymers by means of the formation of hydrogen bonds. Table 1 shows the quantitative and qualitative characteristics of this material.

The elastic properties of the hydrogel are ensured by the organic component, and inorganic - gives strength. Hydrogel can be obtained with a water content of 40 to 90 wt. % Depending on its composition and degree of hydration, the sorption capacity varies from 5 to 15 g of _water / g of the _{dry composite} , and the vapor permeability is from 4.5 to 7.0 mg / cm ² • h. The hydrogel is well fixed to the skin around the wound; it is easily and painlessly replaced during dressings.

 The material presented is quite strong (elastic modulus is 0.05 ÷ 0.25 MPa), resistant to alkaline (up to pH = 9.5), acidic media and boiling water. Medical tests in vivo and in vitro showed that this gel does not have antigenic activity, does not form strong compounds with blood proteins, and can absorb large amounts of wound exudate and pus.

 The resulting material is non-toxic, biocompatible, able to simulate the surface of any shape and perform any cavity, and can also be the basis for the immobilization of biologically active additives, enzymes, dosage forms and cell forms. The gel material can be used alone or applied to any atraumatic mesh substrate, for example, knitted or polymer mesh.

 This medical gel material does not interfere with microcirculation and blood circulation of the skin. It does not interfere with oxygen transport, helps maintain optimal water and temperature balance, as well as acid-base balance. It has a barrier function against known microorganisms, provides rapid skin regeneration without the formation of a hypertrophic or keloid scar. Provides accessibility of wounds for examination, atraumatic when changing. The described material can also serve as a coating for donor sites, contributing to their rapid healing.

 On the other hand, a hydrogel is a structure that allows connective tissues to grow, including nerves. And depending on what is included in the gel, it is possible to prevent tissue scarring and promote nerve growth. For example, adding laminin, an extracellular matrix protein, can stimulate the growth of certain types of cells and inhibit the growth of others.

 EXAMPLE 1. Patient 3. 47 years old, as a result of a household injury, received a burn of the inner thigh area of about 25 square meters. cm I-II degree of severity. After the initial surgical treatment, a hydrogel film with filler miramistin was applied to the burn surface. Control examination and dressings were performed on an outpatient basis once every 3 days. Against the background of the treatment, fast epithelization of the burn surface without scar formation was recorded. It was noted that the dressings, some of which were performed by the patient himself, were not accompanied by pain.

 EXAMPLE 2. Patient K., 56 years old, due to an extensive trophic ulcer of the right lower leg, underwent autodermoplasty, in which a graft was taken from the outer surface of the thigh. As a result, an extensive skin defect with an area of up to 30 square meters was formed. see. The donor zone was closed with a hydrogel film with chlorhexidine. Rapid epithelization of the donor site without scar formation was noted. The film was easily removed during dressing and the procedure was not accompanied by damage to the neoepithelium. Despite the high degree of sensitization of the patient to other wound dressings and ointments, no reaction to the hydrogel film was detected.

 EXAMPLE 3. A patient - a man of 65 years old, suffers from diabetes mellitus, diabetic angio-and polyneuropathy. As a result, against the background of chronic venous insufficiency, an extensive mixed (venous and diabetic) trophic ulcer with dimensions of 6.5x8.5 cm and a depth of 1 cm formed on the lower leg. Dressings with conventional wound coverings caused a pronounced pain syndrome. A gel film infused with eplan was applied. The ability of the film to easily model the profile of the limb and good filling of the ulcerous defect with a wound cover was noted. Repeated dressings were painless, and the patient could perform them on his own.

 The material has good contact with the wound surface, hemostatic, atraumatic, promotes regeneration, maintains an optimal balance of moisture, gases and temperature, biocompatible, non-toxic, flexible and elastic, durable, easy to use. The essential properties of the proposed material are its ability to protect the wound from infection from the outside, the possibility of being on the wound for a long time, and therefore reducing the need for frequent dressing changes. The material provides optimal conditions for the development of regenerative processes in the wound.

Literature
1. I.A. Averochkina, I.M. Papisov, V.N. Matvienko "Structure formation in aqueous solutions of polysilicic acid sols and certain polymers": g. "High molecular weight compounds." Ser. A, 1993, v. 35, 12, p. 1986-1990.

 2. Toki M, Chow T Y, Ohnaka T, Samura H, Saegusa T (1992) Polym. Bull 29: 653.

Claims (9)

 1. Medical polymer gel material based on water-soluble synthetic polymers and organosilicon substances obtained by structural-chemical transformations in aqueous solutions of polymers by adding to them either sols of polysilicic acid and alkaline agents, or various esters of orthosilicates, both in combination with each other, and on your own.  2. The medical polymer gel material according to claim 1, characterized in that it further comprises biologically active substances.  3. The medical polymer gel material according to claim 2, characterized in that it contains an antiseptic and / or antibiotic and / or antimicrobial agents as a biologically active substance.  4. Medical polymer gel material according to claims 2 and 3, characterized in that it contains a hemostatic agent as a biologically active substance.  5. Medical polymer gel material according to claims 2 to 4, characterized in that it contains proteolytic enzymes as a biologically active substance.  6. The medical polymer gel material according to claim 2, characterized in that it contains miramistin or eplan as a biologically active substance.  7. Medical polymer gel material according to claims 1 to 6, characterized in that it has perforation.  8. Medical polymer gel material according to claims 1 to 6, characterized in that it further comprises a mesh substrate.  9. Medical polymer gel material according to claims 1 to 8, characterized in that it is a dressing.

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