RU174437U1 - BONE TISSUE AUGMENT FOR REPLACEMENT OF THE SPAN BONE AND THE JOINT SURFACE - Google Patents

Abstract

The utility model relates to medicine, namely to orthopedics, and can be used to replace bone defects in the cancellous bone. The technical result of the patented solution is to increase the survival rate of the prosthesis element by eliminating rejection and additional trauma to surrounding tissues. The bone augment is made of a titanium alloy and includes curved and flat surfaces, while the flat surfaces are made porous and the curved is polished, and two through holes for the fixing screws are made so that the screw caps are flush with the polished surface.

Description

The utility model relates to medicine, namely to orthopedics, and can be used to replace bone defects in the cancellous bone.

The following technical solutions are known from the prior art.

A known implant for replacing a bone defect, containing a layer of grains of porous titanium nickelide, further comprises a monolithic part of porous titanium nickelide mounted on the above layer of grains of porous titanium nickelide, forming a spongy part of the implant, while both parts of the implant are pre-saturated with an antibiotic diluted with rich platelet autoplasma (RF patent No. 1055584, published on 06/20/2011).

The closest analogue of the patented product is an element of the tibia of the hip joint made of forged titanium alloy, having a shaft that is designed for cementless insertion into the femur of a human or animal, and which has a porous metal surface obtained by firing and / or in the proximal region fusion, as well as a region with a polished surface (WO 2015144129, published 01.10.2015).

The technical problem solved by the proposed utility model is to create a new tool for replacing a defect in the spongy bone and part of the articular surface, which is characterized by high survival rate and low trauma for the tissues surrounding the augmented defect.

The proposed tool is intended to fill a defect in bone tissue and articular surface with augment made by the additive technology of titanium alloy Ti 6Al 4V.

The technical result of the patented solution is to increase the survival rate of the augmentation element of bone tissue with the articular surface due to the exclusion of rejection and additional trauma to surrounding tissues, which is ensured by the adhesion of the porous surfaces of the augmentation element to the walls of the bone defect without the use of cement, which negatively affects the surrounding tissues.

The specified technical result is achieved due to the construction of bone augment for replacing the defect of the tubular bone, made by the additive technology of titanium alloy Ti 6Al 4V and including curved and flat surfaces, where the flat surfaces are porous and the curved is polished, and includes two through holes for mounting screws made in such a way that the screw caps are flush with the polished surface.

The proposed element is made of a titanium alloy corresponding to GOST R ISO 5832-3-2014 (Implants for surgery. Metallic materials. Part 3. Deformable alloy based on titanium, 6-aluminum and 4-vanadium).

The element is made according to individual anthropometric data using 3D printing using MSCT and MRI data, while the finished product size corresponds to the dimensions of the model obtained in the STL format.

The set of essential features of the product is aimed at reducing the invasiveness of tissues surrounding the bone, which increases the likelihood of engraftment of a fragment of a titanium alloy to the bone.

Flat surfaces of the structure are made porous, which allows not using cement to adhere the augment to the walls of the bone defect and ensures the gradual ingrowth of living tissue into the augment material. The curved augment surface forming the articular surface is polished, which ensures good sliding of the friction pair in the joint. The screw holes with recesses for the screw caps are made so that the surfaces of the caps are flush with the polished augment surface, which prevents contact of the screw caps in a friction pair. The direction of the holes is designed in such a way as to ensure easy installation of screws in a minimally invasive surgical manner using arthroscopy. The direction of insertion of the screws is perpendicular to the curved articular surface of the augment and is directed to the projection of the center of the bone metaphysis.

Next, the solution is illustrated by reference to the figures, which show the following.

FIG. 1 - a general view of augmentation of bone tissue.

FIG. 2 - the position of the screws in the augment.

The prosthesis element for replacing bone defects in the tubular bone is made by selective laser melting (SLM) and includes flat surfaces 1 made of porous. Porosity is obtained due to 3d printing by means of layer-by-layer growth of the cellular structure, the unit cell of which is the dodecahedron. The augment also includes a curved articular surface 2 made of polished. Polishing is carried out physically, using grinding tools and polishing paste. The bone tissue augment is fixed in the area of the defect by means of screws 5 in the holes 3. The holes 3 are made through and aligned with the screws 5, and also include recesses 4 under the caps of the screws 5 so that the caps of the screws are flush with the polished surface 2 of the part.

The overall overall dimensions of the part are individual for each application.

Bone augment is performed as follows.

The patient is tested - MRI or MSCT, according to the results of which the parameters of the bone defect are obtained. Titanium Augment is made by 3D printing of titanium alloy. The printing process begins with the separation of the digital three-dimensional model into layers with a thickness of 20 to 100 microns. The finished file in the standard STL format is used as drawings for building a physical model.

The production cycle consists of applying a thin layer of powder on the work surface - usually a metal table that can move in the vertical direction. The printing process takes place in a working chamber filled with inert gases. The lack of oxygen avoids the oxidation of the consumable, which makes printing possible with materials such as titanium. Each layer of the model is fused, repeating the contours of the layers of the digital model. Melting is carried out using a laser beam guided along the X and Y axes by two mirrors with a high deflection rate. The power of the laser emitter is high enough to melt the powder particles into a homogeneous material.

Claims (1)

Bone tissue augment to replace a defect in the cancellous bone and articular surface, characterized in that it is made of titanium alloy by means of selective laser melting and includes curved and flat surfaces, while the flat surfaces are made porous and the curved is polished, and two through holes for mounting screws made so that the screw caps are flush with the polished augment surface.

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