RU2257230C2 - Material for plastic operations - Google Patents

Abstract

FIELD: general surgery methods and facilities.

SUBSTANCE: material for various genesis, localization, and configuration defect grafting is made from thin (up to 100 mcm in diameter) titanium nickelid wire weaved into porous-permeable structure according to knitted-fabric and textile technology or by felting. Thanks to plasticity of titanium nickelid and quasiplasticity of woven structure, effective plasticity of material is many times superior to that in nonwoven porous sheet materials and meets requirements of congruent disposition of materials in organs and tissues to be operated.

EFFECT: increased plasticity of grafting material.

7 dwg

Description

The invention relates to medicine, specifically to a surgical technique for plastic surgery and covering wounds.

Tissue plastic surgery is the general name for surgical methods for restoring the shape or function of individual organs. This is done by moving (transplanting) the tissues or implanting the materials that replace them. Here, the term "material" does not refer to a substance, but to a semi-finished product made from it, the original material for the production of a particular implant from it.

Functionally similar to plastic surgery is the covering of tissues, such as wounds, gaping holes, to protect against infection and / or tissue repair. In this role, the technical means used (materials for plastics) must satisfy a number of necessary conditions, such as:

1. Biocompatibility. A minimal reaction of rejection of a foreign object by the body is desirable.

2. Adequate physical and mechanical characteristics: ductility and elasticity, cyclic resistance to bending deformations, possibly lower specific gravity, material thickness in a local version.

3. Adhesiveness (impregnation with body fluids) and moisture retention in a sheltered volume.

4. Corrosion resistance.

5. Convenience of sterilization.

These and other important properties of these materials have recently been successfully implemented thanks to the intensive development of materials science and materials technology. A significant step in this direction was the development of materials with a porous permeable structure, which helps optimize the interaction of the material with living tissue. For medical purposes, various biocompatible chemical compounds are used.

Porous metallic (tantalum, titanium, alloys based on it, niobium, etc.), porous non-metallic (ceramics, glasses, polymers), natural (hydroxyapatite) materials with regular (knitwear or textile texture) and irregular ("gimp" or “felt”) by structures [1].

Materials for plastic with a regular structure are conditionally classified as porous, since the dimensions of the individual structural elements and the distances between them in the fabric (textile) and knitted (knitted) designs are comparable with the statistical pore sizes in irregular porous materials. Dressings such as gauze bandages can also be attributed to porous materials that have long been widely used to cover wounds.

Known materials for plastics and covering fabrics [1] in the form of knitted or woven nets of highly plastic wire from various bioinert metals and alloys: tungsten, molybdenum, nichrome, corrosion-resistant carbon steel, and more recently, preferably titanium.

The combination of plasticity of the fiber material, viscoelastic deformation due to changes in the loop structure and a wide section of quasi-plastic deformation during the flow and partial destruction of the contact nodes between the fibers determines the high plasticity of the material as a whole, which is necessary when manipulating it in specific and cramped conditions of a surgical operation.

The disadvantage of these materials is the low integration ability with body tissues, high inflammatory reactivity and the possibility of rejection.

Known monolithic material for plastics and covering fabrics from a porous permeable alloy based on titanium nickelide, made in the form of a sheet of thin profile [2]. This material is used and has shown its positive properties as a technical tool in plastic surgery on various tissues. In the specified analogue, it is used for plastic surgery of bone defects of the upper and middle areas of the skeleton of the face. The pore space of the implant during operation is filled with tissue fluids and living tissues of the body, and the metal matrix enters into a complex interaction with them, including mechanical, electrochemical, etc.

In terms of tissue remodeling dynamics, titanium nickelide surpasses currently known medical materials, which is recognized in Russian and world surgical practice.

Adopted by the similarity of the main feature - the source material - for the prototype, the proposed material for plastic has disadvantages.

The rigid structure of the material makes it difficult to form congruent with the tissue being replaced or the space being filled. The fragility of the material increases the risk of insolvency of the operation.

The technical result of the invention is an increase in plastic ability with congruent tissue replacement.

The specified technical result is achieved by the fact that in the material for plastics and covering fabrics with a porous structure made of superelastic titanium nickelide, the structure of the material is formed by filamentary fibers with a transverse size of 10-100 μm, spaced at intervals not exceeding 3 mm.

Knitted shape of the material structure is preferred.

The preferred textile form is the structure of the material.

An irregular shape of the gimp type is preferred.

It is preferable to make the fibers of the material in the form of one or a complex of threads.

Achievability of the technical result relative to the prototype is due to the dispersion of the material, the movable connection of its elements. The layout of the fibers shown in Fig.1, 2, 3.

The knitted form (figure 1) of the structure compared with the textile (figure 2) has an additional degree of mobility of an individual element due to the possibility of bending deformation of the loops. Known from engineering experience for such structures and experimentally confirmed for structures made of titanium nickelide, plasticity exceeds the plasticity of the prototype many times. The functional properties of the material for plastics - impregnation with body fluids and retention of fluid volumes (when covered) - are ensured by the organization of the capillarity effect. For this, the structural elements of the material — fibers — are located at relatively small distances from each other. For wetting liquids, which include body fluids on the surface of titanium nickelide, the thickness of two liquid films on adjacent fibers approximately determines the gap between them so that these films close. For the claimed interval of the thicknesses of the fibers experimentally found the limit value of the gaps - 3 mm The lower boundary of the gaps can reach zero values, i.e. dense, but practically not achieved tightness of the arrangement of the fibers, when the gaps between them still exist and provide capillary penetration of the liquid.

A specific embodiment of the proposal is a “gimp” type structure (FIG. 3). This is randomly entangled and crumpled into the necessary volume of wire (fiber), which in replacement operations must also satisfy the indicated signs.

The implementation of the material fibers, which is necessary for the necessary plasticity and hydrophilicity and possible from the point of view of the technology of nickel-titanium wire, can vary from one thread (monofilament) to two or more, arranged in a row or hidden in multicore complexes.

The illustrations show:

Figure 1. A fragment of the structure of knitted material for plastics and covering fabrics.

Figure 2. A fragment of the structure of textile material for plastics and covering fabrics.

Figure 3. Structure "gimp" of the material for plastic and tissue cover.

Achievability of the technical result is confirmed experimentally by laboratory comparative tests of materials made by the technology of sintering and molding of thin porous-permeable sheets (prototype) and by the technology of knitting (proposed material). Efforts of bending deformation vary multiple. The magnitude of the bending deformation of the porous monolith does not exceed 10%. The proposed materials allow them to be deformed to a large extent to millimeter radii of curvature, which ensures congruent placement of the material in general surgery operations on various organs and tissues and defects of any configuration.

The attainability of the technical result is due to the wettability and capillarity properties. The non-woven structure of the material as a kind of permeable-porous structure is made of an alloy based on titanium nickelide, which is wettable with respect to tissue body fluids, in particular and mainly blood. The sizes of the unit cells of the proposed material are characteristic of capillary containers of liquid. The phenomena of wetting and capillarity in the aggregate determine the dynamics of the behavior of the material placed in the liquid medium of the body. The liquid after impregnation of the structure, under the influence of surface tension, is held in the form of a film in the lumen of the cell. In this case, the retention strength is affected by the thickness of the filament and the dimensions of the cell lumen. The interdependence of these parameters is physically explainable and reduces to the fact that the retention strength is higher, the smaller the size of the cell lumen, and with the constancy of the latter, the thinner the thread. Thus, by varying the thickness of the filament, it is possible to control the size of the cell provided that it retains the liquid film. In the proposed solution to the problem, the values of the diameter of the thread and the gaps that ensure retention, i.e. for the maximum value of the gap interval of 3 mm, you can choose the diameter of the thread less than 100 microns, and for the maximum value of the diameter of the thread of 100 microns - the gap is less than 3 mm, when the condition for holding the film is satisfied.

It was found experimentally that for titanium nickelide and characteristic body fluids, this relationship appears for a thread diameter of up to 105-115 μm and decreases sharply with its increase beyond these limits.

In the practical sense of the proposed solution, the retention of a liquid film means the formation of a continuous, respiratory surface for aerosol gases and bacteria, which is necessary for a surgical covering material.

In the prototype material, which is made by weaving nickel-titanium filaments with a diameter of 120 μm and above with gaps of 1.5 mm or more, the retention effect is weak or completely absent.

An additional factor reinforcing the technical result is the presence on the surface of the microfilament (diameter up to 100 μm) of porosity (see figure 1, 2 (add.)), Formed in the process of drawing technology. Porosity increases the effective surface of the thread and the strength of surface-liquid bonds. With increasing filament diameter above 115 μm, the porosity decreases and completely disappears.

The claimed dimensional characteristics of the material do not reduce and, moreover, do not eliminate its functionality as a "reinforcing" material for plastic operations. On the contrary, in cases where it is necessary to increase the strength of the reduced tissues, their connection with the edges of the wound, the use of such a material is preferable.

Thus, the use of the revealed properties of the mesh material leads to the expansion of its functional capabilities due to the ability to cover the wound surface, and the non-obviousness and unknownness of these connections in the prior art indicates that the proposal meets the criterion of "inventive step".

For clarity, the presentation of materials - the prototype and the proposed - we also provide photographs of fragments made on the same scale. They can be used in addition to illustrations of the primary materials of the application.

Additional illustrations show:

Figures 4 and 5. Micrographs of the surface of a nickel-titanium filament at different magnifications with a diameter of 60 μm obtained by drawing technology.

6. A fragment of the material for plastic surgery (prototype).

7. A fragment of the proposed material for plastic surgery.

The image scale is the same with FIG. 6.

Tested mesh-knitted materials (figure 1) from nickel-titanium wire with a diameter of 45 μm. The distance between adjacent fibers was 0.5-3.0 mm in different directions.

The material implanted in the body tissue works according to the dynamics known for porous materials based on titanium nickelide, i.e. it is impregnated with liquids, filled over time with connective and subsequently functional tissue, vascularized and innervated.

The state of the technological base for the production of fibrous titanium nickelide, the successful testing of the material in clinical conditions allow us to conclude that it is industrially applicable.

Sources of information

1. Biocompatible materials and shape memory implants. Ed. V.E. Gunther. Tomsk, Northampton, MA, 2001.S. 9-11.

2. RF patent No. 20823-55 (prototype). Endoprosthesis for the upper and middle areas of the facial skeleton.

Claims (1)

Material for plastic operations formed by interweaving superplastic nickel-titanium yarns, characterized in that the yarns with a transverse size of 10-100 μm are selected and are located in a woven structure of the material with gaps not exceeding 3 mm.

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