RU88952U1 - IMPLANT FOR COMPENSATION OF BONE DEFECTS - Google Patents

Abstract

An implant for compensating bone defects in the form of a block of cylindrical or prismatic shape, the base of which is made of composite material containing a multidirectional reinforcing frame of rods molded from carbon fibers located along the axis of these rods, and a carbon matrix, characterized in that the implant base is coated with a layer platelet-rich autoplasm of blood with a content of 0.02-0.5 g / cm2 of the surface of the base.

Description

The utility model relates to medicine, namely to surgery, traumatology and orthopedics and can be used in the surgical treatment of inflammatory and degenerative-dystrophic bone diseases, as well as bone injuries.

In the surgical treatment of bone diseases and injuries, it becomes necessary to compensate (replace) bone defects with implants. Bone fragments of the patient or artificial materials with biocompatibility and a sufficient level of strength are used as implants.

A known implant described in the patent of the Russian Federation No. 2204361 [prior. 07/04/2000, Cl. A61F 2/44]. The implant is made of a carbon-carbon composite material containing a pyrocarbon matrix and a multidirectional reinforcing frame of rods molded from carbon fibers located along the axis of these rods. The implant may be in the form of a prism (rectangular, with bases U- or L-shaped), as well as in the form of a cylinder. The known implant has a sufficient level of strength, good biocompatibility, after surgical use is well fixed in the bone.

A disadvantage of the known implant is the relatively slow germination of its bone tissue, which increases the time of bed rest and rehabilitation of patients who underwent surgery with the installation of a bone implant.

The objective of the utility model is an implant that accelerates the formation of bone tissue on the surface of the implant and restores the support ability of the bone skeleton.

The problem is solved in that the implant is made in the form of a block of cylindrical or prismatic shape, the base of which is made of composite material containing a multidirectional reinforcing frame of rods formed from carbon fibers located along the axis of these rods and a carbon matrix, which is coated with a layer of platelet-rich autoplasma blood with a content of 0.02-0.5 g of platelet-rich blood autoplasm per 1 cm ^{2 the} surface of the base.

The content of platelet-rich blood with autoplasma is less than 0.02 g per 1 cm ^{2 of the} surface of the base is impractical, because its content is too low to effectively accelerate the formation of bone tissue on the surface of the implant.

The content of platelet-rich blood with autoplasma of more than 1 g per 1 cm ^{2 of} the base surface is not technologically advanced, because the autoplasma layer in this case is quite large in thickness, which complicates the surgical operation.

The invention consists in the following. The implant proposed in this technical solution consists of a carbon base and a layer of platelet-rich blood autoplasm covering the base. The carbon base provides the mechanical properties of the implant, necessary for the formation of the support ability of the bone skeleton. A layer of platelet-rich blood autoplasm containing a complex of growth factors deposited on the surface of the carbon base, significantly accelerates the formation of newly formed bones.

It should be noted that the carbon material used as the base determines the high biocompatibility of the implant base, which has a heterogeneous structure, which is formed by carbon fibers and a carbon bond that binds carbon fibers into a single composite. The carbon structure in carbon fibers and carbon binder is different. This is due to the features of their receipt. Carbon fibers are the product of high-temperature processing (carbonization and subsequent graphitization) of polymers (polyacrylonitrile, viscose, etc.), while the carbon binder is formed by the high-temperature decomposition of gaseous hydrocarbons. Different production methods provide a difference in the content of carbon atoms with different hybridizations of valence electrons (sp ³ , sp ² , sp) in the structure of the fibers and the binder. The heterogeneous structure of the material ensures good adhesion of growing bone cells to the surface of the material. This is due to the ability of cells to localize on the surface of certain fragments of the structure, as well as at the interface of carbon phases. The layer of platelet-rich blood autoplasma formed on the surface of the base (containing 0.02-0.5 g of autoplasm per 1 cm ^{2 of} the base surface) induces the formation of newly formed bone tissue. Platelet-rich blood autoplasma is the patient’s own plasma with a platelet content of up to 1,000,000 in 1 ml. In the operated area, i.e. on the surface of the carbon base, platelets in a jelly-consistent plasma are degranulated to release a large number of growth factors (TGF, PDGF, EGF, etc.), which provides significant osteoinduction (exposure to pluripotent precursor cells). In this case, the effect of osteogenesis leads to the formation of mature bone tissue on the surface of the implant. Due to this, the patient recovery time is significantly reduced.

Thus, the proposed implants combine biocompatibility, support ability, osteoinductive properties. All this provides a good combination of implants with a bone environment and the rapid germination of implants by newly formed bone tissue and the formation of a bone-carbon block. This ensures biofixation of the implant in the patient's body without the use of other materials for their fixation or bone autoplasty. Features of the composition and structure of the material of the implants allow their effective use in various bone diseases.

The following example characterizes the essence of the invention:

An implant for compensating bone defects in the form of a rectangular prism (parallelepiped) measuring 5 × 5 × 10 mm consists of a carbon base coated with a layer of platelet-rich blood autoplasma. The implant base consists of carbon fibers (volume content of 28% vol.) And a carbon binder. The porosity of the implant base is 9% vol. The carbon base of the implant was obtained by assembling a workpiece from carbon rods with a diameter of 1.2 mm, molded from carbon fibers, in four directions (three of which lie in the same plane and form an angle of 60 ° relative to each other, and the fourth is orthogonal to the first three) and subsequent formation of a carbon binder into the preform. The binder is formed from gaseous hydrocarbons - methane - at a temperature of 1000 ° C until the above porosity is achieved. The implant surface is covered with a layer of platelet-rich blood autoplasma (platelet content of at least 750,000 per 1 ml) with a content of 0.1 g per 1 cm ^{2 of} the base surface.

Experimental studies on the surgical replacement of bone defects in 4 rabbits showed that the proposed implant does not cause any negative reactions from the side of the bone bed, is firmly fixed in it, due to the rapid formation of an inert carbon block due to newly formed bone tissue.

Thus, the application of the present invention provides the ability to effectively replace bone defects of various types, which is important to improve the quality of treatment of inflammatory and degenerative bone diseases, bone injuries, and to ensure the health of the nation.

Claims (1)

An implant for compensating bone defects in the form of a block of cylindrical or prismatic shape, the base of which is made of composite material containing a multidirectional reinforcing frame of rods molded from carbon fibers located along the axis of these rods, and a carbon matrix, characterized in that the implant base is coated with a layer platelet-rich autoplasm of blood with a content of 0.02-0.5 g / cm ^{2 the} surface of the base.