RU207128U1 - Biocompatible Coated Elbow Endoprosthesis - Google Patents

Abstract

The useful model relates to medicine, namely to traumatology, orthopedics and implantology, and can be used for the surgical treatment of the elbow joint for its various diseases and traumatic injuries. The technical result of the utility model consists in creating a heterogeneous osseointegrated surface of the intraosseous parts of the elbow joint endoprosthesis as a result of its laser pulsed oxidation in air and imparting a complex of antimicrobial and antiplatelet properties due to ion-beam modification with silver ions and lanthanum ions. An elbow joint endoprosthesis with a biocompatible coating contains a shoulder and elbow legs, an insert with a sleeve and a locking ring, an axis and a fixing pin for fixing the axis, the shoulder leg is made with a washer-shaped eyelet, the latter has an insert and an axis inserted, which is fixed by a sleeve with a locking ring, an elbow the leg in the proximal part is made in the form of a washer-shaped spike with a groove for contact with the liner and the axis, coaxial cylindrical holes for the fixing pin are made in the washer-shaped spike, the axis is made on the side of the pin with a tide, on which a conical groove is made, the fixing pin is made with surfaces: conical - for contact with the groove and cylindrical coaxial - for contact with the elbow leg, the conical surfaces of the fixing pin and groove are made with a cone angle of 4 to 6 degrees, the shoulder leg is equipped with anti-rotation plates, the washer-shaped eyelet is tipped from the lateral side of the leg, the elbow leg in the area washer spike a is equipped with a plate in contact with the eyelet tide, on the surface of the intraosseous parts of the endoprosthesis, namely the humerus and ulnar legs, a biocompatible heterogeneous oxide coating is made, obtained as a result of laser pulsed oxidation in air, modified with silver ions (Ag +) and lanthanum ions (La +) in the process of ion-beam treatment. 5 fig.

Description

The utility model relates to restorative medicine, namely to traumatology and orthopedics, and can be used for the operative surgical treatment of the elbow joint for its various diseases and traumatic injuries.

Replacement of elbow joints with endoprostheses is an orthopedic operation with the implantation of certain structures into the body. The percentage of complications and unsatisfactory results of implantation remains at a high level and amounts to 3.3-13.2%. It is possible to increase the efficiency of such operations by increasing the level of biocompatibility of endoprostheses using new materials and coatings, as well as by developing new, high-tech designs of endoprostheses.

The surfaces of the intraosseous parts of endoprostheses should have a high total open porosity and morphological heterogeneity, which is necessary for the effective germination of bone tissue cells and strong osseointegration anchoring of implanted structures in the body.

Under the action of an aggressive biological environment, due to the absence of physical and mechanical conditions that ensure effective integration (at the micro- and nanoscale) interaction of the surface of the endoprosthesis with adjacent bone structures, inflammation of the adjacent tissues and rejection of the installed structures occur. Therefore, the problem of increasing the efficiency of using endoprostheses for osteosynthesis is very urgent and can be solved by giving the surface, which has a biocompatible coating, a complex of antimicrobial and antiplatelet properties.

Known design of the endoprosthesis of the elbow joint [Patent RU No. 2082358, IPC A61F 2/38, application publ. 10/27/1993], containing the elbow and shoulder parts. The ulnar portion includes a longitudinal grooved pedicle and an articular component connected to the pedicle. The shoulder section includes a leg, adapter fork and polyethylene head.

The disadvantage of this endoprosthesis is the absence of a biocompatible heterogeneous coating with a complex of antimicrobial and antiplatelet properties on the surface of the intraosseous parts of the endoprosthesis to ensure their high osseointegration capacity.

The known design of the endoprosthesis of the elbow joint [Patent RU No. 2171657, IPC A61F 2/38, publ. 10.08.2001], containing the proximal and distal rods. The proximal shaft contains a triangular stabilizer with a groove and an eyelet with a through groove, and the distal shaft of the triangular section has a washer-shaped part mating with the groove of the proximal shaft eyelet.

The disadvantage of this endoprosthesis is the absence of a biocompatible heterogeneous coating with a complex of antimicrobial and antiplatelet properties on the surface of the intraosseous parts of the endoprosthesis to ensure their high osseointegration capacity.

Known design of the endoprosthesis of the elbow joint company "Voldemar Link" model St. George 2nd generation, produced since 1974 (Catalog WALDEWAR LINK GmbH & Co b ELBOW-PROSTHESIS-SYSTEM ed. 1999). The endoprosthesis includes a humeral leg with a washer-shaped eyelet and an insert fixed in it and an axis provided with a groove, an elbow leg with a groove in a washer-shaped spike in contact with the insert and an axis secured with a fixing pin.

The disadvantage of this endoprosthesis is the absence of a biocompatible heterogeneous coating with a complex of antimicrobial and antiplatelet properties on the surface of the intraosseous parts of the endoprosthesis to ensure their high osseointegration capacity.

Closest to the technical essence of the proposed utility model is the design of the endoprosthesis of the elbow [RF Patent No. 2290143, IPC A61F 2/38 (2006.01), publ. 12/27/2006], which contains the shoulder and elbow legs, an insert with a sleeve and a locking ring, an axle and a fixing pin for securing the axle. The shoulder leg is made with a washer-shaped eyelet, in the latter an insert is installed and an axle is inserted, which is fixed by a sleeve with a locking ring. The ulnar pedicle in the proximal part is made in the form of a washer-shaped spike with a groove for contact with the liner and the axis. Coaxial cylindrical holes for the fixing pin are made in the washer-shaped spike. The axis is made on the side of the lug pin, on which a conical groove is made. The fixing pin is made with surfaces: conical - for contact with the groove and cylindrical coaxial - for contact with the ulnar leg. The tapered surfaces of the fixing pin and groove are made with a taper angle of 4 to 6 degrees. The humeral leg is equipped with anti-rotation plates, the washer-shaped eyelet is provided with tides from the lateral side of the leg. The elbow leg in the area of the washer-shaped spike is equipped with a plate in contact with the lug of the eyelet.

The disadvantage of this design is the absence of a biocompatible heterogeneous coating with a complex of antimicrobial and antiplatelet properties on the surface of the intraosseous parts of the endoprosthesis, namely the ulnar and humeral legs to ensure their high osseointegration ability.

The objective of the utility model is to create an endoprosthesis of the elbow joint with a biocompatible heterogeneous coating with a complex of antimicrobial and antiplatelet properties on the surface of the intraosseous parts of the structure - the ulnar and humeral legs.

The technical result of the utility model consists in creating a heterogeneous osseointegrated surface of the intraosseous parts of the elbow joint endoprosthesis as a result of its laser pulsed oxidation in air and imparting a complex of antimicrobial and antiplatelet properties due to ion-beam modification with silver ions and lanthanum ions.

The problem is solved due to the fact that in the proposed endoprosthesis of the elbow joint with a biocompatible coating containing the shoulder and elbow legs, an insert with a sleeve and a locking ring, an axis and a fixing pin for fixing the axis, the shoulder leg is made with a washer-shaped eyelet, the latter has an insert and the axis is inserted, which is fixed by a bushing with a locking ring, the elbow leg in the proximal part is made in the form of a washer-shaped spike with a groove for contact with the liner and the axis, coaxial cylindrical holes for the fixing pin are made in the washer-shaped spike, the axis is made on the side of the pin with a tide, on which a conical groove is made, the fixing pin is made with surfaces: conical - for contact with the groove and cylindrical coaxial - for contact with the elbow leg, the conical surfaces of the fixing pin and groove are made with a cone angle from 4 to 6 degrees, the shoulder leg is equipped with anti-rotation plates, washer-shaped eye - tides from la on the teral side of the leg, the ulnar leg in the area of the washer-shaped spine is equipped with a plate in contact with the lug of the lug, according to a new technical solution, on the surface of the intraosseous parts of the endoprosthesis, namely the shoulder and ulnar legs, there is a biocompatible heterogeneous oxide coating obtained as a result of laser pulsed oxidation in air modified with silver ions (Ag ⁺ ) and lanthanum ions (La ⁺ ) during ion-beam treatment.

The manufacture of the proposed elbow joint endoprosthesis with a biocompatible coating can be carried out by casting, pressure treatment, mechanical shaping (turning, milling), laser pulsed oxidation in air (obtaining a biocompatible heterogeneous oxide coating), ion-beam treatment (modification with silver ions and lanthanum ions in the process ion beam treatment). Titanium, tantalum, zirconium and their alloys can serve as materials for the manufacture of an elbow joint endoprosthesis with a biocompatible coating.

The utility model is illustrated by drawings and a 3D model. FIG. 1 shows a frontal view of an elbow joint endoprosthesis with a biocompatible coating, FIG. 2 is a top view, FIG. 3 - section A-A, in Fig. 4 - section along B-B, Fig. 5 - 3D model.

FIG. 1 shows the proposed design of the endoprosthesis of the elbow joint with a biocompatible coating, including the shoulder leg 1, the elbow leg 2 (Fig. 1), the insert 3 with the sleeve 4 and the locking ring 5, the axis 6 (Fig. 4) and the fixing pin 7 (Fig. 3 ). The humeral leg 1 (Fig. 1) in the proximal part is made in the form of a washer-shaped eye 8 (Fig. 1, Fig. 2) and is equipped with anti-rotation plates 9 (Fig. 1), and from the lateral side with a tide 10 (Fig. 2, Fig. 2). 3). The proximal part of the ulnar leg 2 (Fig. 1) is made in the form of a washer-shaped thorn 11 (Fig. 3) and is equipped with a plate 12 (Fig. 1) contacting the end surface with the tide 10 (Fig. 2, Fig. 3) of the humeral leg 1 ( Fig. 1). On the medial side in the washer-shaped spike 11 (Fig. 3), a groove 13 (Fig. 3) is made in contact with the axis 6 (Fig. 4), and coaxial cylindrical holes 14 and 15 (Fig. 3), respectively, for the fixing pin 7 (Fig. . 3). The axis 6 (Fig. 4) is equipped with a boss 16 (Fig. 4), on which a conical groove 17 (Fig. 3) is made, in contact with the fixing pin 7 (Fig. 3). The fixing pin 7 (Fig. 3) is provided on one side with a thread 18 (Fig. 3), and on the other side with a slot 19 (Fig. 3) for a screwdriver. On the shoulder 1 and ulnar 2 legs there is a biocompatible heterogeneous oxide coating 20 (Fig. 5), obtained as a result of laser pulsed oxidation in air, modified with silver ions 21 and lanthanum ions 22 (Fig. 5).

Studies have shown that the optimal values of the parameters of the process of laser pulsed oxidation in air to obtain a biocompatible heterogeneous oxide coating are the following: laser pulse energy E = 0.75-1.12 J; diameter of the focused laser spot d = 0.7 mm; pulse duration t = 0.6 ms; the number of scanning passes is 3-5. With a decrease in the values of these parameters, the formation of a heterogeneous structure of the oxidized surface is not observed, and when they are exceeded, the formation of a heterogeneous structure of the oxide coating does not occur as a result of strong melting of the modified surface. The density of microprotrusions is D = 146-193 1 / cm, which confirms the developed surface structure and increased heterogeneity of the oxide coating. The current-free corrosion potential of the coating in physiological solution is E _cor = 0.3-0.4 V, which confirms the high corrosion resistance of the obtained oxide coating under conditions of exposure to biological fluids (blood, lymph, tissue fluid).

Biocompatible heterogeneous oxide coating 20 possesses antimicrobial properties due to its modification with silver ions 22 during ion-beam treatment, which is confirmed by experimentally obtained research results, which showed that the optimal doses of silver ions required to impart antimicrobial properties to the coating are 1.2⋅ 10 ¹⁶ -1.8⋅10 ¹⁶ ion / cm with an accelerating voltage of 50 kV. At doses of silver ions less than 1.2⋅10 ¹⁶ ion / cm ² and more than 1.8⋅10 ¹⁶ ion / cm ^2, antimicrobial properties are not manifested. Antimicrobial properties are due to a complex of therapeutic properties inherent in silver-containing coatings and silver preparations: a wide antibacterial spectrum against pathogenic flora, including antibiotic resistant; the complexity of the development of protective mechanisms in pathogenic microorganisms to the action of silver ions; well-pronounced wound healing effect.

Biocompatible heterogeneous oxide coating 20 possesses antiplatelet properties due to its ion-beam modification with lanthanum ions 22 in the course of ion-beam treatment, which is confirmed by experimentally obtained research results, which showed that the optimal doses of lanthanum ions necessary to impart antiplatelet properties to the coating are 1 , 2⋅10 ¹⁶ -1.8⋅10 ¹⁶ ion / cm ² with an accelerating voltage of 50 kV. At doses of lanthanum ions less than 1.2⋅10 ¹⁶ ion / cm ² and more than 1.8⋅10 ¹⁶ ion / cm ^2, high antiplatelet properties do not appear. Antiplatelet properties are due to a complex of therapeutic properties inherent in lanthanum-containing coatings and lanthanum-containing drugs and help to reduce the processes of implant rejection, by reducing the risk of blood clots in capillaries and small blood vessels adjacent to the wound surface.

To install the proposed elbow joint endoprosthesis with a biocompatible coating, conventional approaches to the elbow joint are used while preserving the flexor and extensor apparatus of the forearm. If this apparatus is broken, then at the final stage it is restored. After exposure of the elbow joint, the articular surfaces of the humerus and ulna are mobilized. The medullary canal of the humerus is sequentially processed with rasps. In the prepared canal, the humeral pedicle 1 is implanted on a cement or cementless basis, depending on the state of the bone tissue. The medullary canal of the ulna is also sequentially processed with appropriate rasps, and the ulnar stem 2 is implanted into it on a cement or cementless basis, depending on the state of the bone tissue. Then the endoprosthesis is assembled as follows. Insert 3 is installed in the washer-shaped eye 8 of the shoulder leg 1, then the axis 6 is pushed in and secured with the bushing 4 with a locking ring 5. The elbow leg is turned towards the shoulder leg at an angle of about 180 degrees. The axis 6 is oriented in such a way that the tide 16 is directed towards the groove, and it is inserted into the groove, then the fixing pin 7 is inserted into the hole 14 and screwed in with a screwdriver by transferring torque through the slot 19, it, in contact with the conical groove 17 on the axis 6, the cone angle of which is from 4 to 6 degrees, provides self-locking and reliably fixes the ulnar stem on the axis. Then the volume of movement is checked and the integrity of the skin is restored. In the process of engraftment of the endoprosthesis of the elbow joint, the cells of the surrounding biostructures penetrate into the heterogeneous surface 20. Due to this, in-depth growth of adjacent cellular structures into the surface of the shoulder 1 and ulnar 2 legs of the endoprosthesis of the elbow joint with a biocompatible coating increases, the osseointegration capacity of the surface and the strength of the biomechanical connection bone. Biocompatible heterogeneous oxide coating 20, providing an integration interaction with the bone tissue, creates the necessary biotechnical conditions for the effective operation of the endoprosthesis under the action of functional loads.

Biocompatible heterogeneous oxide coating 20 is sequentially modified with silver ions 22 and lanthanum ions 23, which give it a complex of antimicrobial and antiplatelet properties, which contributes to fast and reliable osseointegration of the implant with biological tissues due to the lowest percentage of their rejection.

Thus, the proposed design of an elbow joint endoprosthesis with a biocompatible oxide coating creates the best conditions for an effective integration interaction of the surface of the humeral and ulnar legs with bone tissue and for the reliable functioning of the endoprosthesis in the body under prolonged exposure to mechanical loads due to the formation of a heterogeneous surface in the form of a biocompatible porous oxide coating. In addition, due to the successive modification of the coating with silver ions and lanthanum ions, the surface of the intraosseous parts of the endoprosthesis has a complex of antimicrobial and antiplatelet properties.

Claims (1)

An elbow joint endoprosthesis with a biocompatible coating, containing a shoulder and elbow legs, an insert with a sleeve and a locking ring, an axis and a fixing pin for fixing the axis, the shoulder leg is made with a washer-shaped eyelet, the latter has an insert and an axis inserted, which is fixed by a sleeve with a locking ring, the ulnar pedicle in the proximal part is made in the form of a washer-shaped spike with a groove for contact with the liner and the axis, coaxial cylindrical holes for the fixing pin are made in the washer-shaped spike, the axis is made on the side of the pin with a tide, on which a conical groove is made, the fixing pin is made with surfaces: conical - for contact with the groove and cylindrical coaxial - for contact with the ulnar leg, the conical surfaces of the fixing pin and groove are made with a cone angle of 4 to 6 degrees, the shoulder leg is equipped with anti-rotation plates, the washer-shaped eye - with tides from the lateral side of the leg, the ulnar leg is in washer-shaped area the thorn is equipped with a plate in contact with the tide of the eyelet, characterized in that a biocompatible heterogeneous oxide coating is made on the surface of the intraosseous parts of the endoprosthesis, namely the shoulder and ulnar legs, obtained as a result of laser pulsed oxidation in air, modified with silver ions (Ag ⁺ ) and ions lanthanum (La ⁺ ) in the process of ion-beam treatment.

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