RU2624368C1 - Device for implant surface treatment - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device for implant surface modification contains an implant chamber, a laser, a water vessel, a heater, a steam pipe, a reversible motor, a moving assembly, a gripper, a nut and two limit switches, the end of the reversing motor shaft being in the form of a flat protrusion inserted into the slot made at one end of the moving assembly axis, a clamp is mechanically fixed at the other end of the moving assembly axis, the moving assembly axis is made in the form of a threaded cylinder screwed into a nut mechanically fastened with an inner wall of the chamber via a rack. The limit switches elements are mounted on the generating surface of the moving assembly axis.

EFFECT: invention allows the implant to rotate uniformly and move in the longitudinal direction, which allows uniform irradiation of the implant entire surface with a laser beam.

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Description

The invention relates to medical equipment and can be used in the production of implants and bone screws, as well as in dentistry during implantation operations, in traumatology during osteosynthesis.

A device for the manufacture of a dental implant with a multilayer bioactive coating (RF patent 2146535), which includes a unit for sandblasting the implant to obtain surface roughness and a plasma spraying unit that can provide adhesive strength, but does not create a surface ordered porosity of the coating, resulting in a decrease in its level osseointegration.

A device [1] is known for producing a nanostructured (nanostructured) porous surface of implants made of titanium and titanium alloys, including a sandblasting unit, etching units in acid solutions and anodizing. This device does not allow to obtain sufficient surface porosity of the coating, which reduces its osseointegration properties.

Closest to the claimed is a device for modifying the surface of the implants described in [2]

The prototype device includes a KrF (1) excimer laser (248 nm, pulse length 30 ns, 50 Hz) (LPX 305, Lambda Physics, Göttingen, Germany), a set of lenses and an implant mounted on a rotating table.

The disadvantages of the device is the lack of a node for the longitudinal movement of the implant, which does not allow for uniform laser beam processing of the entire surface of the implant. In addition, the prototype device has a limited range of applications, in particular for the treatment of titanium plasma implants with plasma spraying. For more biocompatible materials, in particular for zirconium, this setup does not allow to obtain a high-quality surface, due to the use of not optimal laser radiation wavelength of 248 nm.

The technical task of the invention is to ensure uniform irradiation of the implant surface with a laser beam by making it possible not only rotational motion, but also uniform longitudinal movement. In addition, the objective of the invention also includes the creation of opportunities to impart surface properties of implants based on zirconium, increasing their osseointegration with the bone tissue of patients.

The problem is solved in that in a device for modifying the surface of the implants, which includes a camera with an implant and a laser, an additional vessel with water, a heater, a steam line, a reversing engine, a moving assembly, a gripper, a nut and two limit switches are introduced, and the end of the shaft is reversible the engine is made in the form of a flat protrusion inserted into the slot, which is made on one end of the axis of the moving node, the clip is mechanically fixed on the other end of the axis of the moving node, the axis of the moving node is made in e cylinder with thread, screwed into the nut, mechanically fixed through the column with the inner wall of the chamber, the envelope surface on the axis of the conveying elements assembly mounted limit switches.

In FIG. 1. shows a diagram of the RD-09 reversible engine. In FIG. 2 shows a diagram of the inventive device. FIG. 1 and FIG. 2 serve to clarify the invention. In FIG. 1, the following designations are introduced: 1, 2, 3, 4 - terminals on the housing of the RD-09 reversible engine. Number 5 - indicates the contacts of the limit switch.

In FIG. 2, the following notation is introduced:

5 - contacts of the limit switch; 6 - camera; 7 - a rack; 8 - laser; 9 - a laser beam; 10 - steam line; 11 - an implant; 12 - heater; 13 - water; 14 - vessel; 15 - reverse engine; 16 - an engine shaft; 17 - a flat ledge; 18 - axis of the moving unit; 19 - slot; 20 - a nut; 21 - stand; 22 - clamp; 23 - spring.

The inventive device operates as follows.

Water 13 is poured into the vessel 14 (Fig. 2) and the heater 12 is turned on. After the water boils, water vapor through the steam line 10 begins to flow to the implant 11 fixed in the clamp 22 using a compression spring 23. The capture 23 is made in the form articulated manipulator, the grips of which are compressed by the action of the tightening spring 23. When water vapor enters the implant 11, a reversible motor 15 is mounted on the supports 21 and the laser 8. The laser beam 9 begins to irradiate the surface of the implant. In order for the laser beam 9 to uniformly irradiate the surface of the implant 11, the implant must not only rotate uniformly around its axis, but also move it uniformly in the longitudinal direction. The specified rotation and movement of the implant is as follows. Let the shaft 16 of the reversible motor 15, after turning on, rotate clockwise. A flat protrusion 17 at the end of the shaft of the engine 16, inserted into the slot 19 of the axis of the moving unit 18, which begins to rotate and screw into the nut 20, mechanically attached through the strut 7 to the wall of the chamber 6. In this case, the implant 11 begins to rotate with the axis 18 and simultaneously move in the longitudinal direction by screwing the nut 20 into the thread. As soon as the axis 18 moves to a predetermined distance, which is determined by the longitudinal dimensions of the implant 1, the contacts 5 of the limit switch are activated. When the limit switch 5 (Fig. 1) is activated, the capacitor C is disconnected from the terminal 4 of the reversing motor and connected to the terminals 3 and 2, due to which the reversing motor starts to rotate the opposite side (counterclockwise). The motor shaft 16 (FIG. 2) also begins to rotate counterclockwise. In this case, due to the spline connection, the axis 18 of the moving unit also begins to rotate counterclockwise. This rotation leads to the fact that the axis 18 begins to twist out of the thread of the nut 20, due to which the implant 11, while continuing to rotate, begins to move in the opposite, relative to the initial, longitudinal direction. This occurs until the implant 11 passes a predetermined distance determined by the dimensions of the implant. After that, the contacts of the limit switch 5 are activated again and the reversing motor starts to rotate in the opposite direction. Implant processing ends after 4-6 cycles of switching the reversing motor.

The essence of the invention is as follows. It is known that until recently, dental implants made of titanium alloys were the most common, which is described in particular in the prototype device. However, titanium has relatively low biocompatibility, and some patients are allergic to titanium. Under the influence of electro galvanism, the separated titanium particles combine with proteins and are perceived by the immune system as a foreign protein.

Zirconia implants have no such disadvantages. Of the properties of zirconium, the most interesting are biological inertness, significant resistance to various chemical influences, high fatigue resistance characteristics, tendency to “self-heal” surface defects, manufacturability, and strength. Therefore, products made of zirconium alloy are widely used in dental practice. Zirconium alloys are mainly used for the production of dental implants. This is due to the choice of zirconium dioxide in the inventive method. However, the part of the implant surface that is inserted into the alveolar bone made of zirconium or its oxides usually has a hardness significantly higher than the hardness of the alveolar bone. This leads to a significant deterioration in the adhesion of the implant with the alveolar bone. Therefore, to improve the processes of connecting the implant with the alveolar bone, a surface roughness is created on the surface of the implants using its mechanical processing, laser processing, etc. However, to improve biological affinity and achieve high bone bonding rates, simply roughening the surface of the implant is not enough, since biological affinity and high bone bonding rates are difficult to achieve.

In the inventive device, a significant improvement in the biological compatibility of an implant made of zirconium is achieved by irradiating it with a laser beam in water vapor. When a laser beam passes through water vapor under the action of a high temperature of the beam, water decomposes intensively into oxygen ions, hydroxyl group ions and hydrogen ions. At the same time, a layer of zirconium hydroxide is formed on the surface of the zirconium implant. High temperature gradients arising on the irradiated surface of the implant, the penetration of ions of the hydroxyl group, oxygen and heated water molecules lead to the formation on the irradiated surface of the hydroxide layer, which has significantly lower hardness than the zirconium base of the implant, with numerous pores and small cracks. When this implant is inserted into the alveolar bone, the surface layer acts as a buffer layer to reduce the difference in the degree of hardness between the bone and the base, as a result of which said soft surface further improves the characteristics and the process of fusion with the bone. Moreover, since numerous pores and microcracks are created on the surface layer of the implant, after the implant is inserted into the alveolar bone, bone cells begin to enter these pores and cracks in the surface layer. The entry of bone cells into microcracks leads to a significant increase in the contact surface area between the implant and the bone, which provides the effect of intermolecular bonding and the possibility of obtaining improved adhesion and bonding characteristics.

An example of a specific implementation.

The frame of the dental implant 11 (Fig. 2) was made of zirconium. The lower part (distal end) of the dental implant 11 was made in the form of a truncated cone tapering downward. A self-tapping thread was made on this cone, which makes it possible to directly screw the implant 11 into the drilled hole in the alveolar bone. The frame of the dental implant 11 was fixed with a clamp 22 located on the end of the axis 18 of the moving unit located in the chamber 6, which was moistened with water vapor obtained by evaporation of water 13 from the vessel 14, when heated on a hot plate 12. For rotation and longitudinal movement of the implant was used reversible engine RD-09. In FIG. 1 shows the power supply circuit and reverse switching of the specified engine from an alternating voltage network of 220 V. The RD-09 engine has a built-in gearbox, due to which the rotation speed of the motor shaft can vary in a wide range from 1.75 to 185 rpm. The speed of the longitudinal movement of the implant depends on the thread pitch in the nut 20 and axis 18 and on the rotation speed of the motor shaft. The distance of the longitudinal movement is determined by the length of the protrusion 17 at the end of the shaft and the depth of the slot 19 at the end of the axis 18. Depending on the longitudinal dimensions of the implant 11, the longitudinal movement is determined by the distance between the contacts of the limit switches.

It was previously established that the best results when laser processing a part of the surface of a dental implant connected to the alveolar bone are achieved if the wavelength of the laser beam lies in the range (914 ÷ 1342) nm. In this regard, we used a laser (solid state laser) with diode pumping based on a neodymium doped vanadate crystal, the active elements of which are Nd: YVO with a fundamental wavelength of 1064 nm. After processing the surface of the zirconium implant 11 with a laser beam, the characteristics of their treated surfaces were investigated.

Studies using electron microscopy of the surface of the implant 11, treated with a laser beam, showed that, compared with the untreated surface, it has numerous microcracks and pores with a diameter of 1.5-4 microns, uniformly distributed over the surface of the implant. X-ray diffraction analysis showed that the surface layer consists mainly of zirconium hydroxide. The surfaces of untreated and laser-treated implant samples were examined for hardness by the Vickers method. A quantitative indicator of Vickers hardness is the hardness number (HV). As a result of two measurements of Vickers hardness of an unprocessed laser beam of an implant sample made only from a zirconium base, the values 998 (HV) and 1129 (HV) were obtained. In contrast, the Vickers hardness of the irradiated surface of the implant samples, in which the surface layer consisted of zirconium hydroxide, was 336 (HV) and 328 (HV). Thus, the treated surface of the dental implant is about 1.5 less hard than the alveolar bone, whose Vickers hardness is usually 500 (HV).

The effectiveness of osseointegration of implants into the bone tissue of non-irradiated and laser-irradiated implants was studied in experimental animals (rats). Studies have shown that the coefficient of fusion of the surface of the implant body and bone tissue for the comparative (not irradiated with a laser beam) sample was about 28%, and for the experimental (irradiated with a laser beam) sample was 65%, which indicates a significant increase in the efficiency of implant ingrowth of the irradiated laser into bone tissue. The higher efficiency of osseointegration of the implant irradiated with a laser beam is due to two factors: high porosity and numerous microcracks filled with bone tissue during implantation into the bone, and buffering properties of the softened layer of the implant.

Thus, in comparison with the prototype, the implant has the ability to uniformly rotate and move in the longitudinal direction, which makes it possible to uniformly irradiate the entire surface of the implant with a laser beam. The steam treatment of the implant surface during its irradiation with a laser beam makes it possible to obtain a uniform layer of zirconium hydroxide with numerous pores and microcracks, and the hardness of the obtained layer is lower than the hardness of the alveolar bone. The zirconium implants obtained using the installation have a higher efficiency of connection with bone tissue. The inventive installation can be used not only for dental implants, but also for any other implants made on the basis of zirconium.

Information sources

1. RF patent №2154463, 2000. Coating on an implant made of titanium and its alloys and the method of its application.

2. Laser modification of titanium implants in order to improve cell adhesion. Heinrich K. Dengler T. Koerner W. Stritzker S. Haczek N. Deppe Department of Experimental Physics IV, University of Augsburg.

//http://www.findpatent.ru/patent/246/2469744.html (Prototype)

Claims (1)

A device for modifying the surface of the implants, including a camera with an implant and a laser, characterized in that it is additionally introduced a vessel with water, a heater, a steam line, a reversing engine, a moving assembly, a gripper, a nut and two limit switches, the end of the shaft of the reversing engine made in the form of a flat protrusion inserted into the slot, which is made on one end of the axis of the moving node, the clamp is mechanically fixed on the other end of the axis of the moving node, the axis of the moving node is made in the form of a cylinder with a thread screwed into a nut mechanically fixed through a rack with the inner wall of the chamber, while on the generatrix surface of the axis of the moving unit, the elements of the limit switches are installed.

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