RU116769U1 - Joint Endoprosthesis of Isotropic Pyrolytic Carbon - Google Patents

Abstract

The invention relates to medical equipment and can be used in orthopedics to replace the affected natural joints of a person. Most successfully, the present invention can be used to replace the affected hip joint. However, with small structural changes without violating the essence of the invention, it can be used to replace the knee, elbow and other joints of a person. The purpose of the invention is to increase the reliability and manufacturability of the manufacture of a joint implant. An endoprosthesis of a joint contains a cup and a head made with interacting smooth surfaces. Wherein:

- and the head and the cup consists of a sleeve of isotropic pyrolytic carbon with a conical hole and a conical insert of isotropic pyrolytic carbon;

- the conical hole in the sleeve and the conical insert have a taper of 1:10 or 1:20;

- the conical insert is inserted into the conical bore of the sleeve with a force of 2500N.

The claims contain 3 points, one of which is independent.

Description

The utility model relates to medical equipment and can be used in orthopedics to replace the affected natural joints of a person. Most successfully, the present utility model can be used to replace the affected hip joint. However, without violating the essence of the invention, it can be used to replace the knee, elbow and other joints of a person.

Today, the main materials for the manufacture of hip cups are ultra-high molecular weight polyethylene UHMW PE ISO 5834/1 (ASTM F603), and for heads - hot-forged stainless steel FeCrNiMoMn ISO 5832/1 (ASTM F648), CoCrMo alloy ISO 5832/4 (ASTM F75) and Al ₂ O ₃ ceramic ISO 6474 (ASTM F603). Among traditional materials, the combination of polyethylene and Al ₂ O ₃ ceramics is considered the most optimal and most widespread [1]. However, the wear of polyethylene is one of the main problems in the total replacement of the hip joint.

For example, hip arthroplasty is known [2, 3], containing a hinge element in the form of a head and a cup made of ceramic. These joint prostheses have a low coefficient of friction in the joint and high wear resistance. However, there are serious limitations to the use of these endoprostheses. The natural fragility of ceramics does not allow to make the walls of the ceramic liner thinner than 5 mm. A common disadvantage of these prostheses is their low impact resistance. When jumping, running the patient, or during surgical procedures, shock loads affect the head and cup of the endoprosthesis, causing microcracks in the ceramics that grow during operation and cause the hinge element to fail.

Isotropic pyrolytic carbon has higher crack resistance, lower friction coefficient and higher wear resistance. Comparative tests of the physicomechanical properties of materials for orthopedic implants (silicone rubber, polyethylene, polymethyl methacrylate, titanium, stainless steel, Co-Cr alloy, Al ₂ O ₃ ceramics and pyrolytic carbon) showed that the properties of pyrolytic carbon are closest to cortical bone [4 ]. In terms of biocompatibility, toxicity and corrosion, carbon materials are some of the best for use as implants.

For example, in prosthetic heart valves, which are widely used in world cardiac surgery, the locking element and the body are made of isotropic pyrolytic carbon. At the same time, there is no wear on friction surfaces, which also experience shock loading, after hundreds of millions of valve opening and closing cycles.

In the first years after the discovery of this unique material, attempts were made to use it in orthopedics. For example, a joint endoprosthesis is known [5], which has at least one element in the form of a head or cup, made in the form of a predominantly rotation body. This element is made of graphite. Moreover, its surface interacting with the counter surface of the second element of the joint is covered with isotropic pyrolytic carbon.

However, endoprostheses with a hinge coated with pyrolytic carbon have not found wide application since the known technology of coating from isotropic pyrolytic carbon can successfully cover graphite elements of only a simple small shape. The technology predetermines the production of material in the form of coatings with a maximum thickness of about 250 microns, with a greater thickness due to high internal stresses it cracks. In this case, the coating should form a closed stressed surface, and in case of violation of the continuity of the coating its catastrophic destruction occurs. Therefore, the manufacture of heads and cups of endoprostheses using this technology has significant problems.

Known joint replacement [6], containing at least one element in the form of a head or cup. The head or cup of the endoprots is made of annular segments of monolithic isotropic pyrolytic carbon, the end surfaces of which are perpendicular to the axis of the body of revolution and are motionlessly connected to each other through a layer of polymer material, and the side surfaces that do not interact with the mating surface of the second joint element are motionlessly connected through a layer of polymer material with a frame element made, for example, of metal. The frame element in the joint head is made in the form of a hollow metal sleeve with a shoulder at the base, having a conical hole for connection to the endoprosthesis leg, and a support surface interacting with the end surface of the segment of carbon or ceramic material is made on the shoulder of the sleeve.

However, the manufacture of a head or cup of an endoprosthesis composite and fixedly connected to each other through a layer of polymer material has a number of significant drawbacks that reduce the reliability of the endoprosthesis. Firstly, the strength of the joint is at best equal to the strength of the polymer, which is much less than the strength of isotropic pyrolytic carbon. And there are several such compounds in the design of the endoprosthesis. And the more connections, the lower the reliability of the entire structure. Secondly, any polymers in the environment of the body are prone to swelling, which will also reduce the strength of the joints of the elements of the endoprosthesis. Therefore, it is difficult to talk about the long-term strength and reliability of this design. In addition, the design contains several elements of isotropic pyrolytic carbon, which are collected through polymer layers on a metal frame. To make and assemble this design is technologically difficult. This joint prosthesis [6] was chosen by us as a prototype. The purpose of the utility model is to increase the reliability and manufacturability of the manufacture of the joint endoprosthesis.

Achieving the goal of improving the reliability and manufacturability of the manufacture of an endoprosthesis of a joint containing a cup and a head, made with interacting smooth surfaces of isotropic pyrolytic carbon, is ensured by the fact that:

- and the head and the cup consists of a sleeve of isotropic pyrolytic carbon with a conical hole and a conical insert of isotropic pyrolytic carbon;

- the conical hole in the sleeve and the conical insert have a taper of 1:10 or 1:20;

- the conical insert is inserted into the conical bore of the sleeve with a force of 2500N.

Known technical solutions with a combination of features similar to those that distinguish the claimed solution from the prototype, not identified. The proposed technical solution improves the reliability and manufacturability of the manufacture of the joint endoprosthesis.

The highest reliability will have an endoprosthesis of the joint, in which both the head and the cup are made integral of monolithic isotropic pyrolytic carbon. However, based on the technological features of obtaining monolithic isotropic pyrolytic carbon, this is impossible. Upon receipt of a monolithic isotropic pyrolytic carbon of such sizes, it is impossible to ensure uniformity of physico-mechanical properties in the bulk of the material, while in this case large internal stresses will inevitably arise in it, which will lead to cracking of the material. Therefore, both the head and the cup of the joint endoprosthesis can only be made integral. When performing both the head and the cup of the joint prosthesis from a sleeve of isotropic pyrolytic carbon with a conical hole and a conical insert of isotropic pyrolytic carbon with the taper of the conical hole in the sleeve and the conical insert 1:10 or 1:20, while the conical insert is inserted into tapered bore of the sleeve with a force of 2500N, the problem of internal stresses will be eliminated and the possibility of technological production of both the head and the joint endoprosthesis cup will be the same as from a solid monolithic isotropic of pyrolytic carbon. The absence of foreign materials also increases the reliability of the joint endoprosthesis.

The invention is illustrated by drawings. Figure 1 shows the main view of an endoprosthesis of a hip joint made of isotropic pyrolytic carbon, taken for an example implementation of the invention. Figure 2 shows the endoprosthesis head in a diametric section. Fig. 3 shows a cup of an endoprosthesis in a diametrical section.

The endoprosthesis of the hip joint comprises a leg 1, a head 2 and a cup 3. The head 2, made of monolithic pyrolytic carbon, for example in the form of a ball, consists of a sleeve with a conical hole 4 and a conical insert 5, which are fixedly connected to each other in the zone 6 by means of conical surfaces without the use of foreign materials. Cup 3, made of monolithic pyrolytic carbon, for example with an internal spherical surface, consists of a sleeve with a conical hole 7 and a conical insert 8, which in the zone 9 are motionlessly interconnected by means of conical surfaces without the use of foreign materials.

The proposed utility model is implemented as follows.

Isotropic pyrolytic carbon is obtained by pyrolysis of hydrocarbons at high temperature by deposition of a special graphite substrate on the inner surface. With a flat form of the substrate, a plate is obtained, with a cylindrical one, a sleeve.

To obtain the endoprosthesis head, a sleeve made of isotropic pyrolytic carbon, obtained by the method described above, is taken. By machining, a conical hole with a taper of 1:10 or 1:20 is obtained in the sleeve. Such a taper has the conical surface of the leg of the endoprosthesis on which the head is worn. From a plate of isotropic pyrolytic carbon by machining, a conical insert with the taper is the same as in the sleeve. Then the conical insert with a force of P = 2500N is pressed into the sleeve. The magnitude of the load is selected in accordance with GOST [7], according to which the endoprosthesis is tested at a load of 2250N. Stresses of no more than 20 MPa occur in the material of the sleeve and insert with a material strength of at least 400 MPa.

To obtain a cup of an endoprosthesis, a sleeve made of isotropic pyrolytic carbon, obtained by the method described above, is taken. By machining, a conical hole with a taper of 1:10 or 1:20 is obtained in the sleeve. From a plate of isotropic pyrolytic carbon by machining, a conical insert with the taper is the same as in the sleeve. Then the conical insert with a force of P = 2500N is pressed into the sleeve.

After pressing the insert from the obtained blanks by machining, the elements of the joint endoprosthesis in the form of a head or cup are obtained, while the manufacturing process of the proposed endoprosthesis is more technologically advanced compared to the prototype.

An endoprosthesis of a joint containing a cup and a head works as follows.

Using conventional surgical procedures, the hip joint prosthesis is fixed in the patient’s femur and pelvic bones. When the patient’s leg moves, the head of the hip joint endoprosthesis moves inside the cup. In this case, smooth, for example, spherical surfaces interact - the outer one at the head and the inner one at the cup, made of isotropic pyrolytic carbon. Thanks to this, minimal friction forces and minimal wear of rubbing surfaces are achieved.

The proposed joint prosthesis containing a cup and a head, while maintaining such advantages of the prototype as high wear resistance and minimal friction in the hinge, has increased reliability and manufacturability.

Claims (3)

1. An endoprosthesis of a joint comprising a cup and a head of isotropic pyrolytic carbon made with interacting smooth surfaces, characterized in that the head and cup are obtained from the workpiece by machining, while the workpiece and heads and cups consist of a sleeve of isotropic pyrolytic carbon, which perform a conical hole, and a conical insert from a plate of isotropic pyrolytic carbon, which is pressed into the conical hole of the sleeve. 2. An endoprosthesis of a joint according to claim 1, characterized in that the conical hole in the sleeve and the conical insert have a taper of 1:10 or 1:20. 3. The joint endoprosthesis according to claim 1, characterized in that the conical insert is inserted into the conical hole of the sleeve with a force of 2500 N.