EA038840B1 - Implant for osteotomy - Google Patents

Abstract

The proposed object pertains to the field of medicine, specifically traumatology and orthopedics. The osteotomy implant is made of metal or alloy and has a prism-shaped base with a right-angled triangle base containing long and short legs and a hypotenuse. The prism is characterized by a set of primary channels that create porosity, with the channels extending along a direction orthogonal to the long leg and/or hypotenuse. The prism contains a set of additional channels orthogonal to the primary channels. The spaces between the channels are formed by sintered metal powder. The sintered metal powder is sintered titanium or titanium alloy powder. The technical result of the proposed porous structure design for medical implants is improved elastic properties due to the possibility of further optimization of porosity.

Description

The object belongs to the field of medicine, namely to traumatology and orthopedics.

Known designs of implants used in traumatology and orthopedics, which are rod systems and made of titanium or titanium alloys by casting [1] or rolling [2]. They are mainly used for knee replacement. The structure of titanium casting or rolled products is a solid (non-porous) metal obtained by casting in vacuum arc remelting furnaces and subsequent pressure treatment, including pressing, forging and rolling, and, if necessary, hot forging [3].

The disadvantage of the mentioned implant structures is the absence of pores, which can fulfill several functions. First, the presence of pores reduces the mass of the implant, bringing it closer to the mass of the bone material. Secondly, the specific architecture of the pore placement allows for improved compatibility with bone due to the invasion of bone tissue into the pore space. Thirdly, porous structures provide a level of physical and mechanical properties more acceptable for implants: elasticity, damping, etc. [4].

This drawback has been eliminated in other technical objects, which are porous structures created in one way or another.

The porous structures of implants have been repeatedly complicated by various methods. The patents [5, 6] provide for the creation of a surgical implant that provides improved compatibility with bone and / or resistance to wear. The implant consists of a superficial and a central area. In this case, the proportion of pore volume within the porous surface region is 20 to 50%. The pores are mutually connected and substantially evenly distributed within the porous surface region. At least some of the pores range in size from 100 to about 750 microns. The porous surface region has a thickness of at least about 1 mm, and preferably from about 2 to about 5 mm. Different regions within the porous surface region have a different pore size distribution and / or a different pore volume fraction, so that a pore size and / or pore volume fraction exists within the porous surface region. The core region has a density of 0.7 to 1.0 of the theoretical density. The core area and / or the porous surface area are made of titanium, commercial grade titanium, stainless steel, titanium-based alloys, titanium-aluminum-vanadium alloys, titanium-aluminum-niobium alloys, or cobalt-chromium based alloys. The core area and / or the porous surface area are made of Ti-6A1-4V, Ti-6Al-7Nb, Stellite 211 or 316L stainless steel.

The shape of the implants depends on the function to be performed. In particular, implants in the form of a spatial figure in the form of a prism with a base in the form of a right-angled triangle are in demand. Such implants are described, for example, in the publication [7], patents [8-10] and are used for osteotomy of the tibia to eliminate deformation or improve the function of the musculoskeletal system.

The closest analogue is the description of the implant given in US patent 6008433 [11]. The implant is made of metal or alloy and has the shape of a prism with a base in the form of a right-angled triangle with long and short legs and a hypotenuse. The prism is made of a solid material, which can be titanium.

It should be noted that when the implant is made of a solid material, the strength properties of the object are the highest, but the absence of pores negatively affects the survival conditions, in addition, the elastic modulus of such a material turns out to be excessively high, which reduces the effect of damping. For titanium, the modulus of elasticity is 112 GPa, which is much higher than the modulus of elasticity of porous bone.

The disadvantage of the closest analogue is the too high level of structural rigidity and the lack of conditions for effective growth of bone tissue.

The technical task is to create conditions for better survival and a decrease in the elastic modulus while eliminating the risk of possible destruction of the implant.

This is achieved by the fact that the implant for osteotomy is made of metal or alloy in the form of a prism with a base in the form of a right-angled triangle with long and short legs and hypotenuse. It differs in that the prism contains a set of main channels that create porosity, and the channels are extended along the direction orthogonal to the long leg and / or hypotenuse.

An implant for osteotomy differs in that the prism contains a set of additional channels orthogonal to the main channels. The spaces between the channels are formed by sintered metal powder. The sintered metal powder is titanium sintered powder. The sintered metal powder may be titanium alloy sintered powder.

For a better perception of the essence of the proposed solution, FIG. 1 shows the appearance of an implant in the form of a prism with a base 1 in the form of a right-angled triangle ABC. With this design of the implant, one of the edges of the implant 2 is adjacent to the junction of the hypotenuse AB and the long leg AC. As can be seen from the figure, the angle BAC in this case is the most acute, and the edge adjacent to it is thin.

An important issue of the operability of the implant structure is its strength. It is conditioned not only by the strength properties of the material from which the implant is made, but also by its design, including the architecture of the pore space [12].

Experiments carried out by the authors to obtain a 3D-printed implant for osteotomy in the form of a prism with a base in the form of a right-angled triangle showed that the edge of the implant 2, adjacent to the junction of the hypotenuse and long leg, easily collapses under the influence of small loads even at the stage of transportation, which is shown in fig. 2. This is due to the fact that it is desirable to build the architecture of the implant in the form of a porous structure, which is necessary for better connection of the implant with the bone tissue. However, the presence of pores reduces the strength properties of the implant. In the massive part of the implant, some of its fragments are held by a large number of bridges between the pores. Another situation is created in the thin part of the implant, namely in the edge of the implant adjacent to the junction of the hypotenuse and long leg. This situation is illustrated in the enlarged view of the edge shown in FIG. 3, which shows that the edge is partially destroyed in zone 3, adjacent to the thin edge 2.

Here, the number of bridges between the pores is critically small, the cross-sections from the position of resistance to deformation turn out to be dangerous and easily destroyed. In this regard, it is desirable to carry out the pores in a certain direction. Therefore, it is proposed to equip the prism with a set of main channels, while the pores are made in the form of channels elongated along the direction orthogonal to the long leg or hypotenuse. In this case, the lowest risk of the onset of destruction of the implant is created. The presence of channels with a direction orthogonal to the long leg of the AC and / or channels 5, elongated along the direction orthogonal to the hypotenuse AB, makes it possible to form the path of least resistance for the invasion of bone tissues, since the germination begins from surfaces adjacent to the leg of the AC or hypotenuse AB.

One can also consider the negative situation when the channels acting as pores are directed along the thin edge of the prism. Then the thin edge is almost completely cut by these channels and easily breaks off from the rest of the implant, which indicates the low strength of the structure as a whole.

FIG. 1 is an external view of a prototype implant showing its general geometry. FIG. 2 shows a photo of an implant made using 3D printing techniques, in Fig. 3 shows a photo of a thin edge of an implant with a zone of destruction. FIG. 4 shows a general view of the proposed implant showing the direction of the channels, orthogonal to the larger leg. FIG. 5 - the same for the implant with the channel direction orthogonal to the hypotenuse. FIG. 6 shows the presence of intersecting channels orthogonal to both the great leg and the hypotenuse.

The proposed design of the implant for osteotomy has the shape of a prism with a base in the form of a right-angled triangle ABC (Fig. 4), having a long leg AC and a short leg BC, as well as a hypotenuse AB. The prism contains a set of main channels 4, creating porosity, while the channels are elongated along the direction orthogonal to the long leg AC. In another embodiment (Fig. 5), the prism contains a plurality of channels 5, wherein the channels are extended along a direction orthogonal to the hypotenuse AB. In another embodiment (Fig. 6), there are channels 4 extending along the direction orthogonal to the long leg AC and channels 5 extending along the direction orthogonal to the hypotenuse AB.

The presence of channels with a direction orthogonal to the long leg of the AC, and / or channels 5, elongated along the direction orthogonal to the hypotenuse AB, makes it possible to form the path of least resistance for the beginning of the process of bone tissue invasion.

Once this process has started, the direction of germination can be reversed. Therefore, the prism may contain a plurality of additional channels orthogonal to the main channels. This makes it possible to increase the porosity of the structure as a whole, thereby further reducing the elastic modulus of the system and increasing its damping. Due to the absence of channels parallel to the thin edge, there is no danger of a decrease in strength.

The gaps between the channels can be formed by sintered metal powder. This powder can be a sintered titanium powder or a sintered titanium alloy powder.

The proposed implant design can be obtained by the additive 3D printing method. For this, a computerized volumetric model of the implant is created. Using a laser sintering unit using 3D printing technologies, the desired structure is produced from a metal powder, such as titanium.

The technical result of the proposed design of a porous structure for medical implants is to improve the survival rate and lower the elastic modulus while eliminating the risk of possible destruction of the implant in the form of a prism with a base in the form of a right-angled triangle with long and short legs and hypotenuse.

Sources of information.

1. Patent RU 2397738. Titanium alloy joint prosthesis. Application: 2007135065/14, 27.02.2006. Published: 27.08.2010 Bul. № 24. Author (s): BALIKTAI Sevki (DE), KELLER Arnold (DE). Patentee: WALDEMAR LINK GMBH und CO. KG (DE). IPC A61F 2/36.

- 2 038840

2. Patent RU 2383654. Nanostructured commercially pure titanium for biomedicine and a method for producing a rod from it. IPC C22F 1/18, В82В 3/00. Application: 2008141956/02, 22.10.2008. Posted by:

10.03.2010. Bul. № 7. Valiev RZ, Semenova IP, Yakushina E.B., Salimgareeva G.Kh. Patentee:

Ufa State Aviation Technical University, LLC NanoMeT.

3. Tarasov A.F., Altukhov A.V., Sheikin S.E., Baytsar V.A. Modeling the process of stamping blanks of implants using schemes of severe plastic deformation. Bulletin of the Perm National Research Polytechnic University. Mechanics. 2015. No. 2, p. 139150.

4. Loginov Yu.N. Development of methods for mathematical modeling of plastic deformation of metal porous media. Scientific and technical statements of SPbPU. Natural and engineering sciences. 2005. No. 40, p. 64-70.

5. US patent 2004243237. Surgical implant. Publ. 2004-12-02. UNWIN PAUL [GB]; BLUNN GORDON [GB]; JACOBS MICHAEL HERBERT [GB]; ASHWORTH MARK ANDREW [GB]; W.U. XINHUA [GB]. Applicant (s): They are also STANMORE IMPLANTS WORLDWIDE LIMITED. IPC A61F 2/28; A61F 2/30; A61F 2/44; A61L 27/00; A61L 27/04; A61L 27/06; A61L 27/56; A61F 2/00. Application number: US 20040486627, 20040622.

6. Patent RU 2305514. A method of manufacturing a surgical implant (options) and a surgical implant. Application 2004107133/14. IPC: A61F 002/28. Published: 10.09.2007. Applicant Stanmore Implants Worldwide LTD. Authors: ANWIN Paul (GB), BLUNN Gordon (GB), JACOBS Michael Herbert (GB), ESCHWORT Mark Andrew (GB), WU Xinghua (GB).

7. Kalra M., Anand S. Valgus intertrochanteric osteotomy for neglected femoral neck fractures in young adults. International Orthopedics. 2001. V. 25. No. 6. P. 363-366.

8. Patent RU 2347540. Method for eliminating valgus (varus) deformity of the femur. IPC A61V 17/56. Application: 2007129284/14, 30.07.2007. Bul. № 6. Pozdeev A.P., Pozdeev A.A., Brytov A.V. Patentee (s): FGU Scientific Research Children's Orthopedic Institute named after V.I. G.I. Turner of the Federal Agency for High-Tech Medical Aid. Published: 27.02.2009.

9. Patent RU 2241399. Method of replacing necrotic defects of the tibial condyles during knee arthroplasty. IPC A61V 17/56. Application: 2002118371/14, 08.07.2002. Bul. № 34. Author (s): Kornilov N.V., Novoselov K.A., Kazemirsky A.V., Kulyaba T.A., Zasulsky F.Yu., Kornilov N.N., Khrulev V.N. Patentee (s): GUN Russian Research Institute of Traumatology and Orthopedics named after R.R. Vreden. Publ .: 10.12.2004.

10. US Pat. No. 8,632,547. Patient-Specific Osteotomy Devices and Methods. Inventor: MAXSON WILLIAM [US] STONE KEVIN T. [US]. Applicant: BIOMET SPORTS MEDICINE LLC [US]. IPC: А61В 17/56. Publ. 2014-01-21. Priority date: 2010-02-26.

11. US patent 6008433. Osteotomy wedge device, kit and methods for realignment of a varus angulated knee. Inventor: STONE KEVIN R [US]. Applicant: STONE, KEVIN R. IPC: A61B 17/68, A61B 17/80, A61F 2/28. Priority date: 1998-04-23. Publ. 1999-12-28.

12. Loginov Yu.N., Popov A.A., Stepanov S.I., Kovalev E.Yu. Sump test of a porous implant obtained by the additive method from a titanium alloy. Titanium. 2017. No. 2 (56).

Claims (5)

CLAIM 1. An implant for osteotomy, made of metal or alloy, in the form of a prism with a base in the form of a right-angled triangle, having long and short legs and a hypotenuse, characterized in that the prism contains a set of main channels that create porosity, and the channels extend along the direction, orthogonal to the side face of the prism containing long legs, and / or the side face of the prism containing the hypotenuse. 2. An implant for osteotomy according to claim 1, characterized in that the prism contains a plurality of additional channels orthogonal to the main channels. 3. An implant for osteotomy according to claim 1, characterized in that the spaces between the channels are formed by sintered metal powder. 4. An implant for osteotomy according to claims 1 and 2, characterized in that the sintered metal powder is a sintered titanium powder. 5. An implant for osteotomy according to claims 1 and 2, characterized in that the sintered metal powder is a sintered titanium alloy powder.