DE102012005293A1 - Implant for serving as replacement part or for supporting bony structures within body for e.g. hip joints of patient, has layer arranged on surface with opened pores and comprising smoothing material for smoothing surface with opened pores - Google Patents

Abstract

The implant (1) has a layer (2) comprises a metal-foamed structure (3) with closed pores (5) and/or opened pores (4), where the open pores are arranged on a surface (6) of the metal-foamed structure. Another layer (8) is arranged on the surface with the opened pores and comprise a resorbable smoothing material (9) i.e. squirtable plastic, for smoothing the surface with the opened pores. The metal-foamed structure comprises titanium and/or a titanium alloy. A growth support layer (7) is attached on the surface of the metal-foamed structure between the layers. The growth support layer is provided in form of a hydroxyapatite coating. An independent claim is also included for a method for manufacturing an implant.

Description

The invention relates to an implant, in particular as a replacement or for supporting bony structures within a body, with at least two layers. Furthermore, the invention relates to a method for producing such an implant.

Implants are usually an artificially manufactured material that is introduced into the body and should remain permanently or at least for a certain period of time within the body. Implants for bony structures usually have the task of completing the bone and are used, for example, in hip joints, shoulder joints or knee joints.

In known implants, however, the rigidity of the implant material is significantly higher than that of the bone. The effect resulting from the higher modulus of elasticity involves several problems. Due to the higher rigidity of the implant material, this can not bend analogously to the bone. Thus, at high loads at the transition between the implant and bone to a lever effect, wherein the transition of the rigid structure to the bone directly below the joint generates a predetermined breaking point. Another effect of this lack of flexibility is due to the resource efficiency of the human body. Lack of elasticity or bending is synonymous with material, so bone cell excess. This supposedly excessive material is considered by the body as unused or unnecessary and degraded. As a result, the implant loosens in the bone and another, so-called revision surgery is necessary.

Furthermore, in the case of conventional implants, growing tissue can only be supplied with nutrients on one side, ie tissue lying outside of the implant. Due to the unilateral supply, the healing process or the growth of the bone on the implant is delayed. This prolongs the rest period of the operated person, who can thus only move the limb operated on with the implant at a later time.

Diverse implants, especially joint implants, which should remain as permanently as possible in the body, are provided with a rough surface to facilitate the growth of the bone. During implantation, however, the rough surface counteracts a higher assembly resistance. In addition, bone fragments are deported by the often undefined protrusions of the rough surface. This can lead to unnecessary abrasion and inflammation.

The invention is therefore based on the object of specifying an implant which has an elasticity modulus that is identical to the surrounding bone material, ensures rapid bone integration and supplies growing tissue with nutrients on all sides and causes low assembly resistance.

It is another object of the present invention to provide a method for producing an implant, which reduces the assembly resistance with a simple construction of the implant, realizes an all-round nutrient supply with rapid bone integration and allows a modulus of elasticity analogous to the bone structure.

With regard to the implant, the aforementioned object is achieved according to the invention by the features of claim 1 with respect to the method according to the invention by the features of claim 7.

Further advantageous embodiments of the present invention are the subject of the dependent claims.

According to a first aspect of the invention, it is provided that an implant, in particular as replacement or for supporting bony structures within a body, has at least two layers, wherein a first layer has a metal-foamed structure with closed and / or open pores, wherein the open pores are disposed on at least one surface of the metal foamed structure, and wherein a second outer layer disposed on the at least one open pore surface has a smoothing material for smoothing the open pore surface.

By means of such an optimized design, with closed and / or open pores of a metal-foamed structure, it is possible to realize a flexible movement or a modulus of elasticity analogous to the bone structure within an implant. As a result, at the transition between implant and bone, a lever effect or the resulting break at the transition metal-foamed structure-bone is avoided.

Due to the open pores on a surface of the metal-foamed structure, it is also possible to provide an optimized topology, which in addition to the adhesion during insertion of the implant allows a form and material connection by ingrowth of the surrounding bone tissue around the implant or into the open pores. In particular, the open pores or the rough surface serves for better integration of the bone tissue, whereby an increase of the bone on or in the implant is facilitated and made possible.

The arrangement of a second layer or of the smoothing material on the open pores of the at least one surface has the advantage that the mounting resistance during insertion of the implant into the surrounding bone tissue can be reduced. In this way, the gentler introduction into the bone is possible, at the same time the formation of bone fragments, which arise by friction of a rough surface on the bone, can be avoided. The formation of bone splinters is therefore disadvantageous since surrounding tissue or even organs can experience injuries and / or irritations due to friction on a splinter.

Preferably, the smoothing material fills at least the depth of the open pores of the metal-foamed structure. In other words, it is preferable if the smoothing material completely fills the open pores of the metal-foamed structure, i. H. to the surface of the implant. Thus, a smooth surface can be produced in which the material of the pores or the metal-foamed structure and the smoothing material together form a uniform, planar surface. That is, such a surface may include both material of the metal-foamed structure and smoothing material.

Particularly preferably, the at least one surface above the open pores has only the smoothing material. In other words, it is favorable if the smoothing material fills the open pores of the metal-foamed structure and covers it with a uniform surface. In this case, it is particularly advantageous if the at least one surface above the open pores is smooth, preferably planar or coextensive.

This can be achieved in a simple manner in that the second layer is applied to the at least one surface with open pores of varying thickness which closes both the largest and the smallest pores such that the side facing away from the metal-foamed structure a surface is formed which is spaced from the surface of the metal-foamed structure. In this way, a smooth surface, which consists only of smoothing material without intervening metal-foamed structure, can be generated.

Preferably, between the first and second layers, a growth promoting layer is disposed on the surface of the metal-foamed open pore structure. In this way, it is possible to achieve the growth and ingrowth of the surrounding bone by coating the implant surface. For example, hydroxyapatite is suitable for such a coating. As a result, a better and faster integration of the bone tissue by attachment or attachment of bone cells in / on the surface can be achieved, because in this way a nutrient supply can also be provided by the metal-foamed structure for the growing bone.

Thus, it is possible over time, in addition to the force and form fit of the implant with the bone structure to realize a material bond and an improved form-fitting and thus to ensure a further increased connection. Thus, such a growth promoting layer facilitates the ingrowth and growth of the bone into the metal-foamed structure, particularly into the open pores.

The metal-foamed structure preferably has titanium and / or a titanium alloy. This has been recommended as biomaterial for implants because it does not cause any immunological rejection or implant allergies. In this context, it is also advantageous if the surface of the first layer provided with open pores has a titanium oxide layer as boundary layer to the environment. An advantage of this embodiment is that the solid growth of bone is made possible on the implant, which in addition to the aforementioned advantages, the connection between bone and implant can be further strengthened. Also, titanium is a lightweight material that is not unpleasantly noticeable after being introduced into the bone by additional weight. Further, a titanium foamed structure may have a modulus of elasticity similar to bone.

Preferably, the smoothing material is resorbable for smoothing the surface with open pores. This has the advantage that it dissolves in the body after a completed task, instead of having to be removed in another operation. Advantageously come as materials magnesium and iron and various plastics used. In particular, in the present case, the smoothing material can dissolve by absorption after surgery and degraded by the body. Furthermore, the smoothing material can avoid splinters that arise when inserting the implant, wherein the rough surface of the open pores after the absorption time is available for ingrowth and thus for the healing process.

Advantageously, the material of the metal-foamed structure and / or the growth-promoting layer and / or the smoothing material is osteoconductive, i. H. they can facilitate the growth of the bone as a scaffold, whereby a faster and better integration into the implant is achieved.

Preferably, the materials of the metal-foamed structure and / or the growth promoting layer and / or the smoothing material are osteoinductive, ie they have a substance capable of stimulating the formation of new bone. This property also increases the rate of integration of the bone in the implant with improved bone growth.

In a second aspect of the invention, it is provided to specify a method for producing an implant, which serves in particular as a replacement or for supporting bony structures within a body, with at least two layers, the method having the following steps.

In a first step, a first layer having a metal-foamed structure having closed and open pores is preferably created, wherein the open pores are arranged on at least one surface of the metal-foamed structure.

The metal-foamed structure preferably has titanium and / or a titanium alloy. The production of such a structure can be done in various ways, for example by means of metal powder and a placeholder, which are mixed in predetermined proportions and pressed into a green compact. By chemical or thermal triggering of the placeholder is removed and the structure is sintered in a heat treatment process under an inert atmosphere. Furthermore, it is also possible to use the slurry reaction foam sintering process or to produce the structures by coating plastic foams, for example by sputtering followed by electrodeposition.

Due to the formation of a surface with closed and open pores, it is possible to adapt the elastic modulus of the metal-foamed structure to the bone structure. As a result, leverage at the implant - bone transition is avoided. The open pores or their topology also make it possible to grow into the bone in the implant, thus achieving an improved form and material connection.

In a further step, after creating the first layer, a second layer is disposed on the at least one open pore surface, the second layer having a smoothing material for smoothing the open pore surface.

The second layer or the smoothing material is advantageous because the mounting resistance during insertion of the implant into the bone can be reduced. Thus, a gentler introduction into the bone is possible, which simultaneously avoids the formation of bone splinters.

Conveniently, the smoothing material is absorbable by the body. This allows the body to dissolve this second layer, which is useful for implant placement, thus exposing the open pore surface. This allows the body to grow to the rough structure with open pores, which in addition an improved form-as well as an adhesion between bone and implant can be achieved.

Furthermore, it is preferred if the production of the first layer comprises the opening of the metal-foamed structure or of closed pores. This can preferably be done by mechanical processing, in particular milling. Due to the fact that implants have partly complex outer structures, it is better to create a metal-foamed structure and to supply them by mechanical post-processing of the correct shape. It is advantageous to use a convenient and fast method of shaping, in particular, offers a milling process, which serves to produce an exact shape.

Furthermore, it is advantageous if the subsequent placement of the second layer precedes the step in which it is favorable to attach a growth-promoting layer to the surface of the metal-foamed structure having the open pores. Thus, it is easily possible to facilitate the growth and ingrowth of the bone into the metal-foamed structure. Consequently, in addition to the introduction of the implant and the associated non-positive connection, a material and improved positive connection can be achieved by ingrowth of the bone, because the growth promoting layer ensures nutrient supply of the bone from the side of the implant, whereby a better and faster growth of the bone tissue can be achieved ,

In order to easily apply a growth promoting layer to the surface of the metal-foamed structure or to the surface of the open pores, it is favorable to immerse the metal-foamed structure in a bath of the growth-promoting layer and then to dry it. Thus, a simple and uniform thickness of the growth promoting layer can be achieved, following the irregular, uneven, open-pore surface of the metal-foamed structure.

It is also possible to introduce the resorbable smoothing material by means of the same method, ie by immersion, onto the metal-foamed structure or into the open pores. In this context, it is advantageous if the opening of the open pores facing upward to produce a flat, smooth surface or surface. Furthermore, it is possible to spray on the smoothing material.

In other words, the invention aims to eliminate a predetermined breaking point at the implant-bone interface under high stress and to reduce osteoporosis, to achieve improved integration through facilitated body cell loading and restoring, and thus to the associated force, shape and strength enable cohesive integration of the implant into the body. In this way, a gentler and easier implantation of the structures by operation-optimized structural surfaces, which provide their functionality by absorption of the surface smoothing only during the healing process possible. The combination of these functions essentially provides the advantage of using an illustrated implant and is intended to help extend the lifetime of the implants.

Generally speaking, the implant as well as the proposed method can serve for osteosynthesis, ie for the surgical treatment of bone fractures and other bone injuries. However, a distinction must be made during use as to whether the implant should remain permanently in the body. Osteosynthesis plates, for example, or other seeming bone healing support systems, are usually surgically removed after the healing process. The improved growth of bone and soft tissue on the implant would be a hindrance to such structures and would eventually be detrimental.

A particularly advantageous application of the proposed implant or the method for producing such an implant is in the area of the joint prosthesis, in particular shoulder, hip and knee prostheses. Mostly caused by increased bone and joint wear (arthrosis), a joint replacement is necessary, which should remain as long as possible in the patient.

These applications depend on a good ingrowth of the implants and are suitable, for example, as an application area for the presented implant.

The features described above, all of which serve to form and produce an implant, can be freely combined with one another.

The invention will be explained in more detail below with reference to embodiments in conjunction with the accompanying drawings. In these show schematically:

1 a longitudinal section through an implant,

2A to 2C a method of making an implant, and

3 an ingrown implant.

1 shows a schematic sectional view of a partial section of an implant 1 with a first layer 2 in training as a metal-foamed structure 3 , In the metal-foamed structure 3 it is a titanium foam. Metal foams have a low density and thereby have a high specific rigidity and strength. The production of such a metal foam includes, for example, the use of metal powder and a placeholder, in particular ammonium bicarbonate, which are both mixed together in powder form and processed by pressing to a semi-finished, three-dimensional part or material. The material is then subjected to a chemical or thermal dissolution process in which the placeholder disintegrates. The remaining metal structure is sintered in a heat treatment. Alternatively, plastic foams can also be coated with titanium or titanium alloys and then thermally removed or the so-called slurry reaction foam sintering process can be carried out. The open-pored or partially open cellular structures allow a supply of nutrients to the growing or growing tissue through the implant.

As 1 further shows, the metal-foamed structure 3 various closed 5 and open pores 4 on. Here are the open pores 4 although only on the left side of the metal-foamed structure 2 arranged, but may be arranged on all sides or at any other locations. On the surface 6 formed by a continuous closed area of straight and curved portions of the open pores 4 and the metal-foamed structure 3 , is a growth promoter 7 arranged. This growth promotion layer 7 preferably has hydroxyapatite, whereby a better and faster growth of bone tissue by deposition or attachment of bone cells in / on the surface 6 is reached. Furthermore, this growth promotion layer provides 7 sure that in addition to the adhesion, which results from the introduction of the implant into the bone, an additional material is realized. Furthermore, this layer provides the growing and growing bone with nutrients.

On the growth promotion layer 7 is a second layer 8th applied, which is a resorbable smoothing material 9 having. Here, the smoothing material fills the open pores 4 the metal-foamed structure 3 and is on the growth support layer 7 arranged. At the open pores 4 opposite side of the second layer 8th has the smoothing material 9 a plane or surface of equal area 10 on. Due to the fact that implants have partially complex structures also on their exterior, the surface can 10 also be formed only smooth. That is, at a shape transition in the outer shape of the implant 1 no sharp edges are created, but a smooth curved transition. In this way, shaft blasting, for example when introducing an implant into a femur or a humerus, can be avoided. In addition, bone fragments caused by friction of the implant on the bone during insertion are also avoided.

Of course, it is also possible, for example, in an implant that is introduced into the femur as a substitute for the femoral head, a metal-foamed structure on all sides 3 with open pores 4 and with the layers arranged therein and there (growth promoting layer 7 and second layer 8th or smoothing material 9 ).

Also, it is possible with an all-round open pore 4 provided metal-foamed structure 2 only specific pages with growth promotion layer 7 and smoothing material 9 to provide. Furthermore, it is possible to design the different sides differently for a plurality of sides of an implant, ie to apply an inventive arrangement as described above on the one side and to arrange for example only one growth-promoting layer or one smoothing material on another side.

The smoothing material 9 is absorbable, thereby allowing integration of the bone in the implant and promoting growth of the implant to the bone. Furthermore, the smoothing material 9 , the metal-foamed structure 3 and the growth promoting layer 7 osteoconductive and osteoinductive trained. Ie. they serve as a framework for the growth of the bone and they have a substance that is able to stimulate the formation of new bone. Both promote a faster and better integration of the bone in the implant 1 ,

2A to C show a method for producing an implant according to the invention 1 , In 2A is shown as a metal-foamed structure 3 by means of a milling tool 11 is processed in a milling machine, not shown. A first shift 2 with the metal-foamed structure 3 indicates after processing in addition to the closed pores 5 open pores 4 on. By working the first layer 2 or the metal-foamed structure 3 by means of the milling tool 11 becomes a defined outer contour and surface 6 of the implant to be created 1 created, being on the surface 6 the open pores 4 are arranged. During milling, both the tool can 11 as well as the metal-foamed structure are moved against each other to the surface 6 to create. By way of example, the direction of movement of the milling tool is shown.

After cleaning and drying the metal-foamed structure 3 , which is preferably formed from a titanium foam, the pre-machined implant blank is subjected to a further process step, which in 2 B is shown.

Here is shown schematically how on an outer surface 6 the metal-foamed structure 3 with the open pores 4 or on the surface of the metal-foamed structure 3 a growth promotion layer 7 is attached. This happens because the implant 1 or the metal-foamed structure 3 in a bath 12 the growth promoting layer 7a is immersed and then by means of a lamp 14 , preferably an infrared lamp, is dried. Of course, drying in air is also possible, but requires a greater amount of time.

The bath 12 has a container 13 in which the liquid growth promoter layer 7a is filled. Due to the nature of the liquid growth promoter layer 7a inside the container 13 This settles when removing the metal-foamed structure 3 from the bathroom 12 to the irregular surface 6 the metal-foamed structure 3 on, the open pores 4 having curved surface and the pores connecting straight sections. By drying the same, a connection between the metal-foamed structure 3 and the growth promoting layer thus produced 7 created by adhesion.

After drying, the intermediate becomes 2 B the last step shown in 2C , subjected to a smooth surface of the implant, especially above the surface with open pores 4 , is created.

This shows 2C schematically a nozzle 15 containing a resorbable smoothing material 9 in training as a sprayable plastic, which also has resorbable properties, on the irregular surface 6 that with the growth promotion layer 7 coated, injected.

With the help of this injection process, in which the nozzle 15 and / or the implant 1 moving against each other, becomes a second layer 8th with a smooth surface 10 created. This is especially in the open pores 4 Added more material to create a smooth surface faster. At the end of this process step, the smoothing material covers 9 the complete surface 6 of the implant at the locations of the surface where open pores 5 are arranged. Also, the smoothing material can cover the entire implant.

By spraying resorbable smoothing material 9 having a higher elastic modulus than the growth promoting layer 7 , which is preferably formed as a hydroxyapatite, becomes such a mineral layer 7 protected from chipping during insertion of the implant into, for example, a femur. In this way it can be ensured that on the entire surface along a contact surface to the bone a growth promoting layer 7 is arranged.

Alternatively, the smoothing material may also be similar to the method step 2 B be applied.

3 shows a cross section of ingrown thigh bone 16 that already works with the implant 1 has grown and the absorbable smoothing material 9 completely dissolved or resorbed.

The invention relates to an implant and to a method for producing the implant, wherein a foamed titanium material with open pores on one side is provided with a growth-promoting layer and a smoothing material. The growth promoting layer is applied only to the irregular surface of the titanium material and follows the irregular structure. By contrast, the unevenness on the surface of the implant is compensated by the smoothing material, so that a smooth surface of the implant is formed. With the help of this surface a facilitated penetration within bones is possible.

Claims (10)

Implant ( 1 ), in particular as a replacement or for supporting bony structures within a body, with at least two layers ( 2 . 8th ), wherein a first layer ( 2 ) a metal-foamed structure ( 3 ) with closed ( 5 ) and / or open pores ( 4 ), wherein the open pores ( 4 ) on at least one surface ( 6 ) of the metal-foamed structure ( 3 ), and wherein a second layer ( 8th ), which on the at least one surface ( 6 ) with open pores ( 4 ), a smoothing material ( 9 ) for smoothing the surface ( 6 ) with open pores ( 4 ) having. Implant according to claim 1, characterized in that the smoothing material ( 9 ), and preferably the open pores ( 4 ) of the metal-foamed structure ( 3 ) fills. Implant according to claim 1 or 2, characterized in that the at least one surface ( 6 ) with open pores ( 4 ) is smooth, in particular plan or same area, is formed. Implant according to at least one of the preceding claims 1 to 3, characterized in that the metal-foamed structure ( 3 ) Has titanium and / or a titanium alloy. Implant according to at least one of the preceding claims 1 to 4, characterized in that between the first and second layer ( 2 . 8th ) a growth promotion layer ( 7 ) on the surface ( 6 ) of the metal-foamed structure ( 3 ) with the open pores ( 4 ) is attached. Implant according to claim 5, characterized in that as a growth promoting layer ( 7 ) a hydroxyapatite coating is used. Method for producing an implant ( 1 ), in particular an implant according to at least one of the preceding claims 1 to 6, in particular as a replacement or for supporting bony structures within a body, with at least two layers ( 2 . 8th ), comprising the following steps: - creating a first layer ( 2 ) with a metal-foamed structure ( 3 ), the closed ( 5 ) and open pores ( 4 ), wherein the open pores ( 4 ) on at least one surface ( 6 ) of the metal-foamed structure ( 3 ), - arranging a second layer ( 8th ) on the at least one surface with open pores ( 4 ), the second layer ( 8th ) a smoothing material ( 9 ) for smoothing the surface with open pores ( 4 ) having. Method according to claim 7, wherein the smoothing material ( 9 ) is absorbable, and preferably the metal-foamed structure ( 3 ) Comprises titanium and / or a titanium alloy, Method according to claim 7 or 8, wherein the creation of the first layer ( 2 ) opening the metal-foamed structure ( 3 ) or closed pores ( 5 ), which preferably by a mechanical processing, in particular milling, takes place. Method according to at least one of the preceding claims 7 to 9, wherein the arranging of the second layer ( 8th ) precedes the step: - applying a growth promoter layer ( 7 ) on the surface ( 6 ) of the metal-foamed structure ( 3 ) with the open pores ( 4 ), wherein the growth promoting layer ( 7 ) the growth and ingrowth of the bone into the metal-foamed structure ( 3 ), and wherein the arranging particularly includes immersion in a bath ( 12 ) of the growth promoter layer ( 7a ) and subsequent drying.

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