RU2745534C1 - Method of applying a bioactive coating to a titanium plate for osteosynthesis - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention relates to the field of medical equipment, namely the methods of applying bioactive coatings to titanium plates and discloses a technique for applying a bioactive coating to a titanium plate for osteosynthesis. Method includes mixing a powder consisting of 2 pts. wt. (parts weight) calcium phosphate and 1 pts. wt. hydroxyapatite, with water to obtain a pasty mass with a water content of 3-5 wt. %; applying the obtained pasty mass to the surface of the titanium plate and overmolding it onto the titanium plate by rolling between rolls, and the cycle of applying and overmolding the pasty mass onto the titanium plate is repeated 2- 4 times, reducing the roll gap after each cycle.EFFECT: method enables to increase the adhesion strength of the bioactive coating with the titanium substrate while improving the physical and mechanical properties of the finished product and can be used in traumatology, orthopedics and maxillofacial surgery for the manufacture of implants for osteosynthesis.3 cl, 1 ex, 1 dwg

Description

The invention relates to the field of medical technology, in particular to methods of applying bioactive coatings to titanium plates, and can be used in traumatology, orthopedics and maxillofacial surgery for the manufacture of implants for osteosynthesis.

Bioactive coating of medical implants made of biocompatible metals and alloys can shorten the patient's rehabilitation period, since it has osteoconductive properties and does not cause a local inflammatory reaction and does not have a toxic and allergic effect on the body.

Various technological methods of applying bioactive coatings to titanium implants are currently known.

A bioactive coating based on hydroxyapatite can be formed on a titanium implant by plasma spraying (see, for example, SU 1743024, A61F 2/00, A61F 2/02, 1990; RU 2146535, A61L 27/00, A61C 8/00, 1998; RU 2157245, A61L 27/06, A61F 2/28, 2000).

However, this method gives a low adhesion strength of the coating to the base material due to the large difference in the thermo- and biomechanical characteristics of the base material and the coating.

There are also known methods of applying a bioactive calcium phosphate coating to titanium implants by electrochemical method under spark or arc discharge conditions (RU 2154463, A61K 6/033, A61N 1/32, 1999; RU 2159094, A61F 2/02, A61L 27/30, C25D 11/26, 2000; RU 2291918, C25D 11/26, A61F 2/02, 2007; RU 2394601, A61L 27/06, A61L 27/32, 2010).

Such methods are quite technologically advanced, but they are energy and economically expensive and do not allow the application of a bioactive coating on plates for osteosynthesis only from one side.

Known methods for applying hydroxyapatite coatings, including mixing hydroxyapatite powder with a binder, which is used as phosphate binders, taken in a ratio of 1.0-1.5: 1.5-2.0 to the powder, drying and heat treatment by firing at a temperature of 250- 600 ° C (RU 2158189, B05D 7/24, B05D 7/14, A61L 27/00, 2000), or an argon-plasma jet at an arc current of 300-500 A, duration 0.5-2.0 min at a distance of 40 -100 mm (RU 2417107, A61L 27/30, B05D 7/24, A61L 27/32, 2011), or in conditions of induction heating with a value of electrical power consumption of 0.20-0.25 kW, current frequency on the inductor 90 ± 10 kHz and duration 1.0-1.5 min (RU 2581824, A61L 27/30, A61L 27/32, A61L 31/08, 2016).

As a prototype, a method for applying hydroxyapatite coatings was chosen, including mixing hydroxyapatite powder with a binder, drying, firing, in which phosphate binders are used as a binder, and hydroxyapatite powder and a phosphate binder are taken in a ratio of 1-1.5: 1.5- 2, firing is carried out at a temperature of 250-600 ° C (RU 2158189, B05D 7/24, B05D 7/14, A61L 27/00, publ. 10/27/2000).

This method does not provide sufficient adhesion strength of the coating to the substrate and does not allow controlling the thickness and uniformity of the coating.

A technical problem is the development of a simple and effective method of applying a biologically active coating to a titanium plate for osteosynthesis, which ensures high adhesion of the coating to the substrate material.

The technical problem is solved by the method of applying a bioactive coating to a titanium plate for osteosynthesis, in which a powder consisting of 2 parts by weight. calcium phosphate and 1 wt.h. hydroxyapatite, mixed with water to obtain a pasty mass with a water content of 3-5 wt.%, then the resulting pasty mass is applied to the surface of the titanium plate and pressed onto the titanium plate by rolling between rolls, and the cycle of applying and pressing the pasty mass onto the titanium plate is repeated2 -4 times, reducing the roll gap after each cycle.

The finished coated plate can be additionally heat treated under induction heating conditions at a temperature of 800-900 ° C for 30-60 seconds.

The proposed method provides an increase in the adhesion strength of the bioactive coating to the titanium substrate while improving the physical and mechanical properties of the finished plate.

The essence of the invention is as follows.

During rolling, the crystal structure of titanium changes due to plastic deformation of the metal, and at the same time diffusion of the bioactive coating material into the surface layer of the titanium plate, which leads to an increase in the adhesion strength of the bioactive coating to the titanium substrate and, at the same time, to an improvement in the physical and mechanical characteristics of the finished product.

The mixing of the powder with water is carried out in order to eliminate the flowability of the powder and adhesion to the rolling rollers, as well as to apply the powder uniformly with the same packing density of the particles. The optimal amount of water in the paste-like mixture of powder and water is 3-5 wt%; an increase or decrease in the amount of water will lead to an uneven coating.

The optimal number of cycles of applying the mixed powder with water and rolling the plate is 2 to 4 times, and is determined by the thickness of the finished coated plate. Increasing the number of cycles is impractical because does not lead to a further increase in the strength characteristics of the finished coated plate, and a decrease will not provide strong adhesion of the coating to the substrate.

The invention is illustrated by the figure, which shows a diagram of the implementation of the proposed method.

The method is carried out as follows.

Powder of calcium phosphate with hydroxyapatite, taken in a mass ratio of 2: 1, is mixed with water to obtain a pasty mass 1, which is loaded into hopper 2 and fed to a titanium plate 3. When the rolling rolls 4 rotate, titanium plate 3 is captured with a paste-like mass 1 and rolling between rolls 4. Then the gap between the rolls 4 is changed, and the cycle of application and rolling is repeated 2 to 4 times, depending on the required thickness of the finished coated plate.

Examples of specific implementation.

When implementing the method, rolling equipment with a roll diameter of 200 mm was used. Titanium plates for coating were obtained by rolling a strip of VT1-0 titanium with a size of 8 × 18 mm and a length of 0.5 to 1.0 m between rolls. The titanium plate was 16 mm wide. The initial roll gap was 7.0 mm. After each rolling, the roll gap was reduced by 1 mm.

Example 1.

Powder of calcium phosphate with hydroxyapatite was mixed with water (the water content in the resulting mixture was 5 wt%), the resulting pasty mass was applied to a titanium plate 0.7 m long, 16 mm wide and 8 mm thick. The number of cycles of application and rolling - 3. The total thickness of the finished coated plate was 5 mm.

Example 2 is similar to example 1, the number of cycles of application and rolling is 4. The total thickness of the finished coated plate was 6 mm.

The thickness of the bioactive coating was 5-8 microns, depending on the number of application and rolling cycles.

To assess the strength characteristics, comparative bending tests were carried out for plates with a bioactive coating obtained by the proposed method and similar titanium plates without coating from different grades of titanium on a bench for testing straight plates for bending in accordance with GOST ISO 9585-2011 “Implants for surgery. Determination of strength and bending stiffness of metal plates for fastening bone fragments. "

Tests have shown that titanium plates with a bioactive coating obtained by the inventive method are comparable in strength characteristics with similar plates made of doped VT-6 titanium, and in terms of plasticity, with the original plates made of VT1-0 titanium. With multiple bending deformations of the obtained plates, the integrity of the bioactive coating was preserved, the coating did not peel off and the formation of chips and cracks did not occur, and after removing the load, the plates returned to their original shape.

Thus, the proposed method, in comparison with the prototype, provides a uniform bioactive coating on titanium plates with high adhesion strength of the coating to the substrate while increasing the physical and mechanical properties of the finished product. The method is simple, does not require complex equipment, and is easily applicable for mass production. The obtained titanium plates are used for the manufacture of implants for osteosynthesis.

Claims (3)

1. A method of applying a bioactive coating to a titanium plate for osteosynthesis, comprising mixing a powder consisting of 2 parts by weight. calcium phosphate and 1 wt.h. hydroxyapatite, with water to obtain a pasty mass with a water content of 3-5 wt.%, applying the resulting pasty mass to the surface of the titanium plate and pressing it onto the titanium plate by rolling between rolls, and the cycle of applying and pressing the pasty mass onto the titanium plate is repeated 2- 4 times, reducing the roll gap after each cycle. 2. A method according to claim 1, characterized in that the finished coated plate is additionally subjected to heat treatment at a temperature of 800-900 ° C for 30-60 seconds. 3. The method according to claim 2, characterized in that the heat treatment is carried out under induction heating conditions.

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