RU2571559C1 - Method for making endosseous carbon-coated dental implant - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: method for making an endosseous carbon-nanocoated dental implant involves processing an implant surface with argon ions accelerated to 1 keV at a pressure of (2-6)·10Pa with supplying a negative offset voltage onto a carrier to be increased from 800 to 1,500 V for at least 1 hour; multilayer coating of two alternating layers in the total number of 20-30 is sprayed onto the implant base; a thickness of each layer is 50-100 nm; a carbon nanocoating of a thickness up to 1 mcm is sprayed onto the above coating. The first layer of the multilayer coating consisting of compounds of titanium and carbon is sprayed together with arc spraying of a titanium cathode and pulse-arc spraying of a graphite cathode with increasing carbon concentration in each following layer to the overall increase in the concentration in these layers from 14 to 75 wt %; the second layer consisting of solid amorphous diamond-like carbon having a hardness of 70-100 GPa is applied by pulse-arc spraying of the graphite cathode in the environment of diamond-like film condensation at a temperature of no more than 150°C and a carbon ion power of no more than 100 eV.EFFECT: using the method enables producing the implant having high mechanical and chemical coating stability, as well as biocompatibility and antibacterial properties.1 dwg, 1 tbl, 3 ex

Description

The invention relates to the field of medical equipment, namely to orthopedic dentistry, and can be used in the manufacture of intraosseous implants.

Currently, dental implants made of various materials are widely used: alloys based on iron, titanium and its alloys, ceramics based on aluminum and zirconium oxides [RF Patents 2140227, 2522934, 2441621]. Implants made of titanium and its alloys have several advantages compared with implants made of alloys based on iron and ceramics. Titanium alloys have good biocompatibility and high corrosion resistance.

The increase in the strength properties of the implant surface and the improvement of the osseointegration process are achieved by a useful modification of its surface by means of various methods (ion-plasma, plasma, electrolytic) deposition of coatings that improve the strength properties and biocompatibility of the implant.

A known method of manufacturing an implant with a biocompatible multicomponent nanostructured coating based on titanium carbonitride with additional elements (Ca, Zr, Si, K, MnO at an appropriate concentration) that improve the mechanical and tribological properties of the coating, as well as ensuring its bioactivity, biocompatibility and non-toxicity [RF patent 2281122].

The main disadvantage of this method is the difficulty in providing an appropriate percentage concentration of additional elements in a multicomponent nanostructured coating obtained by magnetron sputtering of composite targets and cathodes containing elements with different sputtering speeds.

A known method of manufacturing an implant by applying a calcium phosphate biologically active coating to an implant of corundum or zirconium ceramic [patent RU 2507316] with the application of an intermediate layer of titanium with a thickness of 5-50 μm in a plasma of a continuous vacuum arc discharge and a layer of calcium phosphate compound deposited by the electrochemical method anodizing of titanium in the mode of spark or arc discharges.

But this method is characterized by insufficient adhesion of the biologically active coating, obtained by the electrochemical method, to the intermediate layer of valve group metals (titanium, tantalum, niobium or zirconium). This leads to a partial exfoliation of the biologically active coating and, as a consequence, to a violation of the conditions of germination of the jaw bone.

There is also a known method of manufacturing an intraosseous dental implant with a plasma-sprayed multilayer bioactive coating [RF patent 2146535], including plasma spraying of a coating system of five layers of different dispersion and thickness: the first two of titanium or titanium hydride, the next two layers of a mixture of titanium or titanium hydride with hydroxyapatite, characterized by the content of components in the layers, and the outer fifth layer of hydroxyapatite. Spraying is carried out layer by layer under various modes, providing a smooth transition from the compact structure of the titanium base of the implant through a multilayer transition coating system to a thin biologically active porous layer.

However, with plasma spraying of a hydroxyapatite coating due to the high temperature of the powder atomization, there is a problem of preserving its initial chemical and phase composition, which have a significant effect on the biological properties [Kalita V.I. Physics and chemistry the formation of bioactive and bioinert surfaces on implants. Overview // Physics and Chemistry of Materials Processing. 2000, No. 5, p. 28-45].

Closest to the claimed is a method of manufacturing an intraosseous dental implant with carbon nanocoating [RF Patent 2490032], including sandblasting the surface of the titanium base of the implant with alumina particles, plasma spray coating of the biocompatible coatings of the implant base with a mixture of titanium or titanium hydrite powders of various dispersity and hydroxy hydroxy calcium in the amount of three layers, the fourth layer is sprayed with hydroxyapatite, on this system of biocompatible coatings by magnetron sputtering, a metal film of an iron triad 20-35 nm thick is applied, on which carbon nanocoating up to 1 micron thick is obtained by chemical deposition. In this case, the carbon coating is carbon nanotubes and carbon nanofibres with a diameter of 50-200 nm, which have the greatest bioactive effect.

This method of creating intraosseous dental material consists of several technological stages and has a number of significant disadvantages:

1. A 3-stage technology for the manufacture of the coating material is used, namely: a) plasma spraying of a multilayer biocompatible coating with different dispersion of titanium particles or titanium hydride of various thicknesses followed by spraying a layer of hydroxyapatite; b) magnetron sputtering of a thin layer of a film from an iron triad (iron, nickel, cobalt); and c) chemical deposition of a carbon coating from a mixture of carbon-containing gases. With such a multi-stage technology, it is difficult to withstand all spraying conditions of a coating of an appropriate composition and structure.

2. Sandblasting with alumina particles contaminates the titanium surface with impurity phases that are difficult to remove by washing. Impurity phases can cause osteeliosis and subsequent bone resorption around the implant, which leads to a loss of its stability.

3. Hydroxyapatite refers to bioresorbable materials, ie it undergoes dissolution and dissociation in a biological environment. Due to the resorption of hydroxyapatite, peeling of a thin 20-35 nm adhesive metal film obtained by magnetron sputtering is possible, since it is not a protective barrier to ion diffusion.

4. The structure of the carbon nanocoating consisting of nanotubes is porous, which does not prevent the penetration of the physiological environment into the inner layers of the coating, under the influence of which the hydroxyapatite layer is resorbed, accompanied not only by a change in its composition, but also by peeling of the upper layers of the multilayer coating. Rigidity of nanotubes can injure the tissue of the jawbone.

Thus, the closest to the claimed method does not provide sufficient mechanical strength of the multilayer hydroxyapatite coating on the surface of the metal implant, and due to mechanical damage to the coating there is a resorption of the coating and a decrease in its antibacterial properties.

The basis of the invention is the task of increasing the strength of the surface of a metal implant, improving its biocompatibility and antibacterial properties.

The problem is solved in that in the method of manufacturing an intraosseous dental implant with carbon nanocoating, including surface treatment of the implant, layer-by-layer spraying of the multilayer coating implant base and spraying of a carbon nanocoating on this coating with a thickness of up to 1 μm, according to the invention, surface treatment is carried out by ions accelerated to 1 keV argon at a pressure of (2-6) x 10 ^-2 Pa with a negative voltage-bias to the substrate with a gradual increase in its from 800 to 1500 for not less its 1 h, a multilayer coating is made of two alternating layers, with a total number of layers of 20-30, with a thickness of each layer of 50-100 nm, while the first layer of a multilayer coating, consisting of compounds of titanium with carbon, is sprayed by simultaneous arc spraying of a titanium cathode and by pulsed-arc sputtering of a graphite cathode with increasing carbon concentration in each subsequent layer with a total increase in concentration in these layers from 14 to 75 wt.%, and the second from solid amorphous diamond-like carbon with a hardness of 70-100 GPa lyayut pulsed-arc sputtering a graphite cathode, carbon nano-coating is sprayed pulse-arc sputtering a graphite cathode in the condensation conditions, a diamond-like film at a temperature not higher than 150C and an ion energy of 100 eV uglerodane more.

Plasma treatment of the implant surface with argon at a pressure of (2-6) · 10 ^-2 Pa with applying a negative bias voltage with a gradual increase from 800 to 1500 V for at least 1 h ensures the cleaning of the surface from contamination by removing the surface layer and creates the necessary surface microrelief, which provides the necessary adhesion of the subsequent multilayer coating.

The spraying of a multilayer coating of two alternating layers, with a total number of layers of 20-30, with a thickness of each layer of 50-100 nm, while the first layer of a multilayer coating, consisting of compounds of titanium with carbon, is sprayed by simultaneous arc sputtering of a titanium cathode and pulsed arc spraying graphite cathode with increasing carbon concentration in each subsequent layer with a total increase in the concentration in these layers from 14 to 75 wt.%, and the second from solid amorphous diamond-like carbon with a hardness of 70-100 GPa, allowing t get a nanostructured coating several microns thick, chemically resistant to the environment. Chemical resistance is achieved by reducing the likelihood of cracking in a multilayer coating due to an increase in the volume fraction of interfaces in a layer consisting of compounds of titanium with carbon, the structure of which includes particles several tens of nanometers in size, which inhibits the movement of dislocations, blocking the development of cracks at the layer boundaries.

An increase in the carbon concentration in the layer of the titanium-carbon compound from 14 to 75 wt.% With increasing thickness of the multilayer coating provides sufficient hardness and mechanical strength of the nanostructured coating. The low concentration of carbon in the layer of the titanium compound with carbon directly in contact with the implant surface increases the adhesion of the multilayer coating.

Carbon nanocoating with a thickness of at least 1.0 μm deposited on a multilayer coating by pulsed-arc spraying of a graphite cathode under conditions of condensation of a diamond-like film at a temperature not exceeding 150 ° C and carbon ion energy not exceeding 100 eV, increases the mechanical strength of the implant surface, its biocompatibility and antibacterial properties . The resulting solid amorphous diamond-like material is biologically compatible with the tissues of living objects, non-toxic, and has osseointegration properties [Thomson L.F., Law F. C, Rushton N. et al. Biocompatibility of diamond-like carbon coatings // Biomaterials, 1991.-V.12.-P.37-40; Chai F., Mathis N., Blanchemain N. et al. Osteoblast interaction with DLC-coated Si substrates // Acta Biomater., 2008. - V. 4. - P. 1369-1381].

Thus, the new technical result consists in increasing the strength of the surface of the metal implant, improving its biocompatibility and antibacterial properties.

The drawing shows an electron microscopic image of the structure of the multilayer coating.

The method is as follows. A metal implant, for example, of titanium, consisting of an intraosseous element and a plug, is washed in an ultrasonic bath in a mixture of alcohol with organic matter. This is the standard procedure for pre-cleaning spray surfaces from contamination.

The implant parts on special holders are placed in the chamber of the spraying unit and vacuumized to a pressure of 10 ^-3 -10 ^-4 Pa.

The plasma method is used to clean the surface with argon ions accelerated to 1 keV at a pressure of (2-6) · 10 ^-2 Pa with applying a negative bias voltage with a gradual increase from 800 to 1500 V. The processing time depends on the degree of surface contamination and the number of parts, but not less than 1 hour

After argon treatment, a multilayer coating is deposited, consisting of an alternating layer of titanium compounds with carbon of variable concentration and a layer of solid amorphous diamond-like carbon. Layers of the compound of titanium with carbon are obtained by simultaneous arc spraying of a titanium cathode and pulsed arc spraying of a graphite cathode, with an increase in the frequency of propagation of carbon pulses (see table).

This mode of operation of the carbon source provides an increase in the carbon concentration in the layers of titanium compounds with carbon from 14.6 to 71 wt.%, And layers of solid amorphous diamond-like carbon with a hardness of 70-100 GPa are sprayed by pulsed arc spraying of a graphite cathode. The total number of layers 23. The multilayer coating structure, consisting of nanometer film layers, has numerous interlayer boundaries that block crack propagation, providing higher mechanical as well as chemical resistance of the coating, which is important for dental prostheses operating under load and in an aggressive environment (saliva, nutritional supplements, etc.).

By the method of pulsed-arc sputtering of a graphite target, a diamond-like carbon nanocoating is deposited on a multilayer coating at a temperature on the substrate of not higher than 150 ° C and an ion energy of not more than 100 eV. Under such conditions of film condensation, a carbon diamond-like structure with the largest number of sp ³ bonds is formed. The thickness of the diamond-like coating is not more than 1 μm.

Achievement of the technical result is confirmed by clinical examples of the use of an intraosseous dental implant with carbon nanocoating at Private Dentistry LLC (Emanzhelinsk, Chelyabinsk Region).

Clinical example 1: Patient - age 62 years. Secondary adentia of the upper jaw. Partial adentia of the lower jaw. Installed implants made of titanium alloy with carbon nanocoating. During the installation of the intraosseous implant, an implantological physiological dispenser was used. Installation of implants was carried out in a mode of 30 revolutions and with a load of 30 N.

Result: 1. Three weeks later, stability was noted, good secondary fixation of the implant in the implant bed was observed.

2. After three months, the condition of the implant is stable. The plugs were replaced with abutments with spherical attachments (locks), fixing removable dentures.

3. After 10 months of observation, the condition of the implants is stable.

Clinical example 2: Patient - age 58 years. According to the patient, the condition after coronary bypass surgery takes blood-thinning drugs. Installed implants made of titanium alloy with carbon nanocoating. Installation of implants was carried out in the same modes as in the first example.

Result: 1. Three weeks later, stability was noted, the control period of the germination of the trabecular bone in the body of the implant favorably changed the primary fixation.

2. After three months, the implants are stable. The plugs were replaced with abutments and a bridge-like prosthetics was performed with a plastic structure with fixation on implants.

3. After ten months of observation, the condition of the implants is stable.

Clinical example 3: Patient - age 47 years. Complaints about the absence of teeth in the area 1.4, 2.4. Installed implants made of titanium alloy with carbon nanocoating. Installation of implants was carried out under the same modes as in the previous examples.

Result: 1. Three weeks later, stability was noted, good secondary fixation of the implant in the implant bed was observed, and bone growth to the body of the implant was observed.

2. After three months, the implants are stable. The plugs were replaced with abutments followed by prosthetics with plastic crowns.

3. After 10 months, the condition of the implants is stable.

As a result of the tests, it was found that signs of rejection, inflammation, suppuration, allergic reactions in patients with established implants are not observed.

The invention can be used in dental implantology in outpatient dental institutions.

Claims (1)

A method of manufacturing an intraosseous dental implant with a carbon nanocoating, including surface treatment of the implant, layer-by-layer spraying on the base of the implant of a multilayer coating and spraying onto this coating of a carbon nanocoating up to 1 μm thick, characterized in that the surface treatment is carried out with argon ions accelerated to 1 keV at a pressure of (2 -6) · 10 ^-2 Pa with applying a negative bias voltage to the substrate with a gradual increase from 800 to 1500 V for at least 1 hour, a multilayer coating is performed and of two alternating layers, with a total number of layers of 20-30, with a thickness of each layer of 50-100 nm, while the first layer of a multilayer coating consisting of compounds of titanium with carbon is sprayed by simultaneous arc sputtering of a titanium cathode and pulsed-arc sputtering of a graphite cathode with an increase the carbon concentration in each subsequent layer with a total increase in the concentration in these layers from 14 to 75 wt.%, and the second from solid amorphous diamond-like carbon with a hardness of 70-100 GPa is spray-pulsed spray graph tovogo cathode, carbon nano-coating is sprayed pulse-arc sputtering a graphite cathode under the conditions of the condensation diamond-like film at a temperature not higher than 150 ° C and a carbon ion energy less than 100 eV.

Images