DE10006992B4 - Process for coating an implant and implant with coating - Google Patents

Abstract

method for coating an implant with body-soluble calcium phosphates, in which from a calcium-containing and phosphate-containing solution for Preparation of the coating on an electrolytic deposition the implant occurs, characterized in that dispersion particles be introduced into the coating that the dispersion particles from a biocompatible Metal salt and / or a plastic and / or a ceramic material are that in a deposited layer defects are generated, the serve for receiving and / or anchoring dispersion particles, and that the electrolyte bath stirred is used to immerse dispersion particles in a layer.

Description

The The invention relates to a method for coating an implant in the body soluble calcium phosphates, in which from a calcium-containing and phosphate-containing solution for Preparation of the coating on an electrolytic deposition the implant takes place.

Further The invention relates to an implant which has a coating out in the body having soluble calcium phosphates.

It is known to provide implants with a calcium hydroxyapatite (Ca ₁₀ (PO ₄ ) ₆ OH) ₂ ) coating. Such a bioactive coating stimulates bone growth around the implant to improve the connection between the implant and the bone. The calcium hydroxyapatite is not soluble in the body. It is known to produce such coatings by thermal spraying and in particular plasma spraying.

Besides It is also known to have implants with a coating of soluble in the body To provide calcium phosphates. These calcium phosphates can after Implantation of the implant are absorbed by the bone cells, which causes the postoperative recovery phase after implantation shortened provided with a coating prosthesis since the bone cells are built around the prosthesis and their neoplasm is stimulated.

For example, from the US 5,205,921 A or the US 5 310 464 A It is known to deposit calcium phosphate electrolytically on the implant to produce a coating.

From the DE 196 01 153 A1 is a method for applying bioactive phosphate layers on metallic implants, which are to remain permanently in the human body known. The bioactive phosphate layers serve to achieve the improvement of the ingrowth of these implants in human bones. The deposition of the phosphates is carried out from liquid, preferably aqueous phosphate solutions by electrolytic way by alternating current, direct current, pulsating direct current, pulsating alternating current or by superpositions of these types of current. It is described that the formation rate of the phosphate layer can be increased by adding oxidizing salts such as nitrates, nitrites or other substances.

From the EP 0 806 212 A1 For example, an implant made of a material having a surface roughness with an average peek distance (Ra value) between 10 and 1000 nm is known, the surface being coated with a layer comprising calcium ions and phosphate ions.

From that Based on the object of the invention, a coating to provide which is mechanically stable and good dissolution behavior Having implanted the implant.

These The object is achieved according to the invention in the method mentioned solved that Dispersion particles are introduced into the coating that the dispersion particles of a biocompatible metal salt and / or a plastic and / or a ceramic material are that in one deposited layer defects are generated for recording and / or anchoring of dispersion particles, and that the electrolyte bath touched is used to immerse dispersion particles in a layer.

By the targeted doping of the calcium phosphate coating material let yourself the mechanical stability increase the coating. Thereby is the risk of abrasion of coating material during insertion of an implant into a bone recess during surgery considerably reduced. It is then possible to produce larger layer thicknesses (For example, coatings with a thickness up to about 100 microns). Also This will increase the risk of damage that may affect the Growth of the bone cells around an inserted implant impact can, reduced.

It is the job of coating, the new bone formation in the environment of the implant. For this it is important that the Coating has a defined dissolution behavior, so that the bone cells can absorb calcium phosphate. The dissolution behavior, d. H. the absorption kinetics, can by a targeted doping be modified with dispersion particles such that the resolution the coating by a factor of the order of magnitude two, for example unmodified electrochemically deposited brushite layers changed d. H. the bone cells is at one with the inventive method produced coating in the same time an increased amount of growth-promoting Calcium phosphate provided.

It is also possible to deliberately introduce dispersion particles which contain growth-promoting proteins (BMP Bone Morphogenic Proteins) or consist of these. As a result, the formation of new bone in the environment of the implant can be promoted.

It could also dispersion particles of ceramic or plastic or metallic Substances are introduced, and in particular can also several Types of dispersion particles are introduced. Through a targeted Doping can be then modify the coating so that it has an increased mechanical stability has and increased biological effectiveness to support the formation of new bone around the implant.

It has surprisingly shown that dispersion particles as additional nuclei act and on the one hand accelerate the layer growth and on the other by the increased number due to the presence of dispersion particles of crystallization seeds, the structure of a layer becomes finer-grained. As a result, in turn, the mechanical properties of a coating influences and also the dissolution behavior the coating is affected. It occurs in particular the phenomenon an at least partial columnar crystallization.

to Incorporation of the dispersion particles in the coating is particularly advantageous if this conductive are. As a result, in the electrolyte bath, without the implant must be removed, a targeted doping of a calcium phosphate layer done with the dispersion particles.

Basically, the Dispersion particles from a non-biologically harmful Be material.

Around Storage positions and / or anchoring points for the dispersion particles in a layer are deposited in a Layer defects are generated. Such flaws can be at a variant of an embodiment be generated by the fact that the layer is umpolarisiert. A such repolarization can take place in that the voltage, which lies between an implant as a cathode and an anode, is reversed. this leads to cause the layer to tear and pores are formed and / or a crack network on the Layer forms. The repolarization of the layer takes place in particular, when a certain layer thickness is reached, such as a layer thickness of the order of magnitude of 5 μm. It is favorable if the repolarization for a period between about 10 s and 2 min, d. H. with a short-term potential, which, when the decomposition voltage at the electrolysis is in the range between 1 and 20 V, range of for example 5V to 100V, may be.

It is possible, too, Defects for attachment and / or anchoring of dispersion particles by to produce mechanical treatment of a layer. It is conceivable, for example a non-contact mechanical treatment by ultrasound or also a brush a layer.

All it is particularly advantageous if the electrolyte bath is stirred, to soak dispersion particles in a layer.

at a particularly advantageous variant of an embodiment be used to form a dispersion particle structure in a Coating applied at intervals of layers, taking between the application of successive layers of dispersion particles be introduced into the coating. It will do this on the implant a calcium phosphate layer deposited, it will be in this layer defects for storage produced by dispersion particles and subsequently dispersion particles stored. It then becomes the electrolytic deposition of calcium phosphate continued, so that the dispersion particles introduced between two layers are stored. On the last deposited layer In turn, defects are then generated for the storage of further defects Dispersion particles in a new intercalation layer. To this Way lets specifically build a layer structure in which the dispersion particles form a matrix. This also allows targeted dispersion particles to increase the mechanical stability the coating and correspondingly dispersion particles that are biological effective for promotion are the bone regeneration, store.

Such dispersion particles can be used particularly advantageously in order to increase the mechanical stability of the coating. The metal salts may also be iron-containing salts, such as FeO and / or Fe ₂ O ₃ , thereby also promoting bone regeneration; For example, iron-containing salts can be used to promote hemoglobin formation.

The Dispersion particles can also from a growth-promoting Protein, so as to promote the formation of new bone.

conveniently, For the deposition of a layer on the implant, the decomposition voltage is at the electrolysis pulsed. This allows the training of a Avoid space charge around the cathode (the implant), making the coating smoother.

The proportion of the dispersion phase is favorably chosen to be variable in order to specifically adjust the properties of the coating for the respective implant. For example, if it is important to achieve high mechanical stability, then a corresponding proportion of dispersion particles can be provided to ensure this stability.

It is particularly advantageous if an implant is heat-treated with a coating in order to adjust the calcium-phosphate ratio in the coating. For calcium hydroxyapatite (Ca ₁₀ (PO ₄ ) ₆ (OH) ₂ ), the calcium-phosphate ratio is 10: 6. This ratio is optimal for promoting the formation of new bone, since the bone cells can optimally process the calcium phosphate provided in the appropriate ratio. However, such a calcium hydroxyapatite is not soluble in the body. However, it would be desirable for coatings of soluble calcium phosphate that the calcium-phosphate ratio of the coating material is as close as possible to the ratio 10: 6. By a final heat treatment of the coating, which is formed by electrolytic deposition, the calcium-phosphate ratio can be increased and in particular set in a ratio between 1.1 and 1.4. The heat treatment shifts the corresponding chemical equilibrium according to the different phases of calcium phosphate. By adjusting the ratio in this way, the absorption kinetics can be modified accordingly and improved over non-heat-treated coatings.

advantageously, while the heat treatment takes place in a temperature range between approx. 80 ° C and 280 ° C. In particular, a slow warming, so the relationship to be able to adjust specifically.

to Producing a uniform and Well-adherent layer on the implant, it is favorable if the implant before the electrical coating is activated. When activated it may, for example, be a plasma activation and / or for a chemical activation by the implant, for example in a dilute Hydrofluoric acid solution pickled or is pickled in boiling sodium hydroxide solution.

The The above-mentioned object is in the implant described above according to the invention thereby solved, that in the coating dispersion particles are incorporated, that the dispersion particles of a biocompatible metal salt and / or a plastic and / or a ceramic material and that the Dispersion particles are embedded at defects of a layer, wherein the dispersion particles by flooding to the defects the layer are embedded.

By such dispersion particles as additional nucleation nuclei act, the layer growth is accelerated, and by an increased number of crystallization points a fine-grained Achieve structure of the coating. As a result, the mechanical Properties and also the dissolution behavior influenced by the coating. By an appropriate targeted Doping the coating with dispersion particles can be modify the absorption kinetics positively. In addition, can be thicker Form layers and also the risk of abrasion when introducing a Implant is through a higher Inherent stability of Coating significantly reduced.

The Dispersion particles are attached to defects of a layer. These defects represent anchoring points and / or attachment points for the Dispersion particles dar. Through targeted formation of defects, for example, by mechanical processing of a deposited layer or by electrical impulses as by Umpolarisierung the layer or exposure to electromagnetic radiation like microwaves, lets specifically create a flaw structure to thereby turn specifically a doping structure for the dispersion particles in to produce the coating.

Especially It is advantageous if the dispersion particles in storage layers lie. It can be then form a kind of sandwich structure in which the dispersion particles are arranged in a three-dimensional arrangement sional. At this Arrangement may also be a network. The order is chosen in such a way that yourself for the respective application gives an optimal result. Especially the layer structure is formed so that on the one hand a high mechanical stability achieved and on the other hand, a good dissolution behavior is present. It may also be provided that biologically active substances as growth-promoting Proteins are used as dispersion particles and so in the resolution of Coating the bone cells not only by absorption of calcium phosphate but also by the biologically active molecules for growing and / or to Regeneration be stimulated.

It is particularly advantageous when a coating a plurality of intercalation layers so as to conform the coating to be able to. In particular, it is also advantageous if the dispersion particles form a matrix structure in the coating, which crosslinks, for example is. The proportion of dispersion particles in the coating can in the range between 0.5 volume percent and 20 volume percent lie.

It is also favorable if a plurality of materials is provided for the dispersion particles. You can then choose materials that are fine are responsible for the mechanical structural stability of the coating and also materials that additionally promote the formation of new bone. For example, the dispersion particles can be made of biocompatible metal salts. Dispersion particles may also be growth promoting proteins (BMP).

Cheap is it, if fine dispersion particles are incorporated, so the mechanical stability to increase the coating. Preferably, this is the size of dispersion particles smaller than 2 μm.

Cheap is if the thickness of the coating is up to 100 μm. By such a thick coating is the risk of abrasion during operative insertion of the prosthesis reduced and also transport damage The coating has less negative effects on the dissolution behavior the coating than would be the case with thinner layers.

preferred embodiments the method according to the invention and the implant according to the invention are the subject of the following description and the drawings. Show it:

1 a schematic representation of an electrolytic cell for producing a coating according to the invention and

2 a schematic representation of a coating according to the invention with embedded dispersion particles.

In 1 is one as a whole with 10 designated electrolytic cell for carrying out the method according to the invention shown schematically. An implant 12 , which is made for example of a titanium alloy, immersed in an electrolyte solution 14 one that contains calcium and phosphate. The implant 12 is with the negative pole 16 a voltage source 18 connected and thus represents the cathode. Furthermore, an anode immersed 20 into the electrolyte bath. The implant 12 was before immersion in the electrolyte bath 14 pretreated and thereby activated, for example by plasma activation or by chemical activation, such as by heating in a dilute hydrofluoric acid solution.

For the electrolytic deposition of a calcium phosphate layer 22 on the implant 12 becomes a pulsed DC voltage between the anode 12 and the cathode 20 applied, wherein the amount of voltage, for example, in the range between 1 and 20 V and the pulse frequency can be in the range between 5 and 300 Hz.

The pH of the electrolyte solution 14 is set for example between 2.5 and 5.5.

By the voltage between cathode 12 and anode 20 occurs a pH shift, which leads to crystallization of CaHPO ₄ in the cathode region. The electrolytic deposition on the implant 12 to form a coating 22 is carried out until a certain layer thickness is reached, which may for example be 5 microns. The layer growth can be monitored over the duration of the electrolysis process.

When this layer thickness is reached, the tension between the implant becomes 12 and the anode 20 reversed for a short time, wherein the period of this Umpolarisierung the layer in a period between 10 s to about 2 min may be and the Umpolarisierungspotential may be in the range between 5 V to 100 V. Umpolarisierungsfall then sets the implant 12 the anode and the actual anode 20 acts as a cathode. The Umpolarisierung it comes to a pore formation and formation of a crack network in the previously deposited layer 23 (see. 2 ).

In the electrolyte solution are dispersion particles 24 , which are electrically charged, dissolved. By stirring the electrolyte solution 14 with a mixer 26 become the dispersion particles 24 in the flaws 28 (see. 2 ) of the layer 22 flooded and stored there or even anchored there. After this intermediate step of Umpolarisierung the original polarity is restored, ie the implant 12 set again as a cathode, so that a further electrolytic deposition of calcium phosphate on the implant 12 he follows.

Additionally or alternatively to the generation of defects 28 By Umpolarisierung defects can also be due to mechanical action such as brushing the layer 22 or by ultrasound or by the action of electromagnetic waves.

The dispersion particles 30 which are in the coating 22 are stored (cf. 2 ), act as additional nuclei in the deposition of calcium phosphate on the coating. As a result, the layer growth is accelerated in the further electrolytic deposition. The increased number of crystallization points also leads to a finer grain structure of the coating 22 , This will increase the mechanical structural properties of the coating 22 influenced and also the dissolution behavior of the coating 22 in an implant used in the body is modified.

By selecting suitable dispersion particles and by targeted control of the formation of the defect structure (in particular arrangement of the defects and formation of individual defects) can then be targeted, as in 2 shown schematically, storage layers 32 with dispersion particles 30 in a coating 22 produce. The variable proportions of the dispersion phase can be in the range between 0.5 percent by volume to about 20 percent by volume, so as to have a specific matrix structure of the doped dispersion particles within the coating 22 to reach.

Necessary requirement for the material from which the dispersion particles 24 are, that these are biocompatible, ie not biocidal. For example, the dispersion particles may be made of a ceramic material such as aluminum oxide or PLA or of biocompatible metal salts such as in particular FeO or Fe ₂ O ₃ . It is also conceivable to use growth-promoting proteins (BMP Bone Morphogenic Proteins), which promote their growth or new formation during absorption and uptake by bone cells.

Advantageously, the dispersion particles 24 which are in the coating 22 be installed, a size smaller than 2 microns. By targeted formation of a matrix structure can then be the coating 22 optimally adapt, on the one hand a high mechanical structural stability is ensured and on the other hand, the bone cells in the environment of an implant used with growth-promoting bioactive molecules can be supplied.

By the introduction of dispersion particles 30 Also, the thickness of the coating can be 22 extend up to 100 μm.

After completion of the coating 22 in the electrolysis bath 14 the implant is removed and a heat treatment is performed. The temperature range of the heat treatment is between 80 ° C and 280 ° C, in particular, a slow heating is provided. Through the heat treatment, the ratio of calcium to phosphate in the deposited coating 22 and, in particular, it is then set to be between 1.1 and 1.4. This will provide the beneficial biological effectiveness of the coating 22 at their resolution considerably and in particular positively influenced, since the bone cells growth-promoting substances are provided. The heat treatment can be carried out in particular by microwave irradiation and / or plasma heating in order not to influence the substrate thermally too strongly.

Claims (24)

A method of coating an implant with calcium phosphate-soluble in the body, wherein from a calcium-containing and phosphate-containing solution for the preparation of the coating takes place an electrolytic deposition on the implant, characterized in that dispersion particles are introduced into the coating, that the Dispersion particles of a biocompatible metal salt and / or a plastic and / or a ceramic material are that defects are generated in a deposited layer, which serve for receiving and / or anchoring of dispersion particles, and that the electrolyte bath is stirred to absorb dispersion particles in a layer , Method according to claim 1, characterized in that that the dispersion particles are conductive. Method according to claim 1 or 2, characterized that defects are generated by repolarization of the layer. Method according to claim 3, characterized that the repolarization for a period of between 10 seconds and 2 minutes. Method according to one of the preceding claims, characterized characterized in that defects by mechanical treatment of a Layer are generated. Method according to one of the preceding claims, characterized characterized in that to form a dispersion particle structure applied in a coating at intervals from layers where between applying successive layers Dispersion particles are introduced into the coating. Method according to one of the preceding claims, characterized characterized in that dispersion particles from a growth-promoting Protein are. Method according to one of the preceding claims, characterized characterized in that for depositing a layer on the implant the decomposition voltage is pulsed. Method according to one of the preceding claims, characterized characterized in that the proportion of the dispersion phase is chosen to be variable, um for that respective implant to adjust the properties of the coating targeted. Method according to one of the preceding claims, characterized in that the Volu proportion of the dispersion phase is between 0.5 percent by volume and 20 percent by volume. Method according to one of the preceding claims, characterized characterized in that an implant is heat treated with a coating to adjust the calcium-phosphate ratio in the coating. Method according to claim 11, characterized in that that the heat treatment in a temperature range between 80 ° C and 280 ° C. Method according to one of the preceding claims, characterized characterized in that the implant prior to the electrolytic coating is activated. Method according to claim 13, characterized in that that a plasma activation is provided. Method according to claim 13 or 14, characterized that a chemical activation is provided. Implant which has a coating ( 22 ) of body-soluble calcium phosphates, characterized in that in the coating ( 22 ) Dispersion particles ( 30 ) are embedded, that the dispersion particles of a biocompatible metal salt and / or a plastic and / or a ceramic material and that the dispersion particles ( 30 ) at defects ( 28 ) of a layer, wherein the dispersion particles ( 30 ) by flooding to the imperfections ( 28 ) of the layer are embedded. Implant according to claim 16, characterized in that dispersion particles ( 30 ) in storage layers ( 32 ) lie. Implant according to claim 17, characterized in that a coating ( 22 ) a plurality of intercalation layers ( 32 ) having. Implant according to claim 17 or 18, characterized in that dispersion particles ( 30 ) in the coating ( 22 ) form a matrix structure. Implant according to one of claims 16 to 19, characterized in that the proportion of dispersion particles ( 30 ) in the coating ( 22 ) ranges between 0.5 volume percent and 20 volume percent. Implant according to one of claims 16 to 20, characterized in that a plurality of materials for the dispersion particles, which in a coating ( 22 ) are stored, is provided. Implant according to one of Claims 16 to 21, characterized that dispersion particles are growth-promoting proteins. Implant according to one of claims 16 to 22, characterized that the size of dispersion particles smaller than 2 μm is. Implant according to one of claims 16 to 23, characterized in that the thickness of the coating ( 22 ) is up to 100 microns.