RU2425694C1 - Nanostructured bioplastic material - Google Patents

Abstract

FIELD: medicine. ^ SUBSTANCE: in a nanostructured bioplastic material containing a native form of hyaluronic acid, a base is nanostructured hyaluronic acid produced by photochemical cross-link and having a cellular texture in the range of 50 to 100 nm. ^ EFFECT: higher clinical effectiveness of using the bioplastic material ensured by better adhesion and creating the optimal cell migration conditions in a wound. ^ 1 tbl, 1 dwg

Description

The invention relates to medicine, namely to combustiology of plastic surgery, cosmetology, and may find application as a biomaterial for replacing defects in integumentary tissues and stimulating regeneration.

Recently, based on new data obtained by studying the mechanisms of tissue and organ regeneration in order to restore lost functions, tissue engineering and regenerative medicine are developing intensively. The goal of this direction is the creation of de novo organs and tissues, which are achieved through transplantation of cells on carrier matrices.

A carrier matrix or matrix is a synthetic or biological complex that provides mechanical strength to a structure and its spatial 3D orientation. The main criteria for a biocompatible matrix to create a tissue engineering construct should be: the absence of cytotoxicity, the maintenance of adhesion, fixation, proliferation and differentiation of cells placed on its surface, the absence of an inflammatory reaction to the material and an immune response, sufficient mechanical strength in accordance with the purpose, bioresorbability by the usual metabolic pathways .

Known bioplastic material (Patent RU No. 2367476, publ. September 20, 2009), which includes a matrix base, where the native form of hyaluronic acid, which has a fibrous structure and forms an elastic plate, is used as the matrix material, it also contains antimicrobial agents.

However, the use of the above material is ineffective if the matrix cell sizes are too small or too large, because this affects the mechanical strength of the structure, maintaining adhesion, fixation, proliferation and differentiation of cells placed on its surface.

EFFECT: increased clinical efficiency of using bioplastic material by increasing adhesion and creating optimal conditions in the wound for cell migration.

The specified technical result is achieved by the fact that in a nanostructured bioplastic material, which includes the native form of hyaluronic acid, the basis is a nanostructured matrix having a cellular structure in the range from 50 to 100 nm.

As the matrix material, a native form of hyaluronic acid is used, having a fibrous nanostructured structure capable of forming an elastic plate.

Photochemical crosslinking of the filaments of hyaluronic acid forms the basis of a stable spatial framework, that is, a grid with cells, the sizes of which vary from 10 nm to 10 microns, depending on the production conditions. In the initial biomaterial, these nanocytes are filled with water molecules, but they can include molecules of various medicinal substances necessary for the treatment of specific types of skin lesions. Spatial nanocells are formed not only by rare cross-links, but also by spatial convergence of nanowires, where the formation of labile hydrogen bonds is possible. Such an organization of the spatial nanostructure by a combination of stable and labile bonds makes the biomaterial lamellar, allows the cells to adapt to the sizes of the included molecules, and allows relatively free diffusion of oxygen. Biomaterial is able to absorb water from the environment, while increasing the weight and volume of the film.

A nanostructured bioplastic material with a cell of more than 100 nm does not have a given strength and elasticity, it acquires increased fragility and brittleness. This leads to a decrease in the preservation of the structure of the biomaterial during transportation. In the wound, such material thickens due to the absorption of wound fluid, which reduces the aeration of damaged underlying tissues.

Obtaining a material with a cell of less than 50 nm does not allow a sufficient quantity of drugs to be introduced into the bioplastic material. It also reduces the aeration of underlying tissues, worsens cell migration, leads to the attachment of a secondary infection, which generally leads to a delay in healing time.

The drawing shows an image of atomic force microscopy of a nanostructured bioplastic material.

Until now, the full polymerization of hyaluronic acid has been possible only with the use of an additional reagent, which led to its chemical modification. This circumstance is unfavorable, as it leads to sensitization of immunocompetent cells of the body.

To achieve complete polymerization with the formation of an optimal matrix, the authors used a nanotechnological approach that allows you to influence the spatial orientation of hyaluronic acid molecules and obtain a grid with cells whose sizes vary from 10 to 10 microns.

The technology for producing bioplastic material is as follows.

For the production of biomaterial, a three-module production line has been developed: 1) an activation module for the feedstock (hyaluronic acid); 2) a photochemical nanostructuring module, in which nanowires form the basis of a stable spatial framework, that is, a grid with cells whose sizes vary from 50 to 100 nm; 3) sterile packaging module.

In the first module, a solution of hyaluronic acid is prepared in a concentration range of 1-10%. By shaking, a viscous gel mass is formed, which is fed to the second module, where the stage of photochemical nanostructuring of the hyaluronic acid hydrocolloid is carried out to obtain an elastic-elastic material.

The application of the developed nanotechnologies in the production process for the production of biomaterial makes it possible to obtain original bioplastic material with desired bioengineering properties. Unlike the best world analogues (for example, the HYAFF biomaterial of the pharmaceutical group Bristol Meyers Squibb (Conva Tech.)), The proposed biomaterial along with elasticity has high adhesion to wound surfaces of integumentary tissues. This allows you to treat skin lesions (including extensive burns) in a non-dressing way, and due to the transparency of the material, visually monitor the effectiveness of therapy. Nanostructuring of the biomatrix gives high hydrophilicity and provides drainage properties of the biomaterial in the wound, which creates optimal conditions for effective cell migration during the regenerative process. This reduces wound healing time.

Thus, in comparison with the prototype, the developed nanostructured bioplastic material has the following properties (see table):

1. The biomaterial is elastic, it bends easily, can change and maintain its shape.

2. It is easily pierced by a needle and cut with a scalpel.

3. When the biomaterial is wetted with liquid, blood, its volume does not increase, which is especially important when laying the biomaterial on the defect of integumentary tissues.

4. Its surface is smooth; it is a transparent film through which it is possible to visually control the process of laying the biopolymer on the prepared bed.

5. It has high adhesive properties, after laying it literally “sticks” to the tissues of the prepared bed, which provides increased adhesion and creates optimal conditions for cell migration and accelerated healing of skin defects of various etiologies.

A comparison of nanostructured bioplastic material and similar unstructured bioplastic materials is presented in table 1.

Table 1 Parameter Nanostructured bioplastic material Bioplastic material. Patent No. 2367476 Bioplastic material "HYAFF" 1. Receipt Photochemical nanostructuring Freeze drying of the starting material Crosslinked chemically modified forms 2. Optical properties Transparent Opaque Opaque 3. The content of external impurities - - + 4. Drainage properties + - - 5. The ability to hold drugs + - - 6. Adhesion + - - 7. Wound biodegradation time 165 hours (optimal) 3-5 hours Not degrading 8. Cellular compatibility in vitro and support for mitosis of cells. Compatible and supports cell mitosis Compatible, does not support mitosis No 9. Features of application Does not require dressings and additional fixation Requires dressings and extra fixation Requires dressings and extra fixation

The image of atomic force microscopy (AFM) directly proves the nanostructured structure of the bioplastic material. The properties of the bioplastic material indicated in the table are a consequence and indirect confirmation of the nanostructured material.

The developed nanostructured bioplastic material is a unique carrier of transplanted cellular elements, since due to the content of hyaluronic acid and the optimal composition of other trophic substances, the cells in its structure not only retain viability, but are also able to exhibit mitotic activity. On the wound surface, a nanostructured bioplastic material provides natural drainage and creates optimal conditions for the migration of epithelial cells.

The proposed technical solution uses a native (natural) molecule of hyaluronic acid, which is the most specific to the human body and is environmentally friendly, safe and low cost.

An analysis of the results of histological and histochemical studies of the obtained biomaterial indicates that this material is characterized by unique fibroarchitectonics.

The presence of a hyaluronic amorphous matrix in the material provides it with high strength. This fibroarchitectonics is as close as possible to the structure of the intercellular substance of native tissues and can be used by combiologists (treatment of burns, including extensive ones), in the treatment of patients with diabetic foot (ulcerative lesions of the feet in patients with diabetes mellitus), venous trophic ulcers (impaired venous blood flow) , in the plasticity of defects in the tympanic membrane, in the restoration of cellular skin layers after peeling procedures (ultrasound, laser, chemical) and dermabrasion, as well as a cosmetic mask in therapy cosmetic cosmetology in order to “rejuvenate” the skin.

Claims (1)

Nanostructured bioplastic material, including the native form of hyaluronic acid, characterized in that the basis is a nanostructured matrix, which is a nanostructured hyaluronic acid obtained by photochemical cross-linking, having a cellular structure in the range from 50 to 100 nm.

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