ES2385843T3 - Device for fixing an implant pin - Google Patents

Abstract

A fixing device (41) adapted to fix an implant pin (1) in an objective structure, in which the implant pin has a longitudinal axis (15) and comprises a pin head (3) having a molding portion of pin head (7) and a rod (5) having a rod molding portion (9), the pinhead molding portion and the rod molding portion comprising a moldable material that can be liquefied by energy application , the fixing device comprising: an ultrasonic sonotrode (43) comprising a vibration rod (47) adapted to generate ultrasonic vibrations at a tip (45) provided on the vibration rod; a guiding mechanism (51) adapted to cooperate with the implant pin in order to align the guiding mechanism with respect to the implant pin and adapted to guide the vibrating tip, characterized in that the tip on the vibration rod It has regions (81, 83) of different lateral dimensions.

Description

Device for fixing an implant pin

Field of the Invention

The invention relates to a fixing device for applying an implant pin to an objective structure.

Technical background

In the prior art several implantation devices for humans and animals are known. The implants, at least partially, create positively fitting connections to parts of human or animal tissue, particularly skeleton parts, in which the implants help connect tissue parts to each other, or help connect tissue parts to media that support or replace parts of tissue, or other therapeutic auxiliary devices. Additional procedures for implanting implants in humans or animals are known.

Known implants for creating connections to parts of the skeleton, such as bones, include screws, pins, staples, etc., which are used to connect bones to bones, or bones to artificial, loading, stabilizing or supporting parts, or parts that replace parts of the skeleton (stabilization or fixation plates, sutures, threads, artificial joint elements, artificial teeth, bone grafts, etc.). Said connection elements for implantation consist, for example, of metal or plastic, including resorbable plastic. After healing, the connecting elements can be removed by an additional operation or they can be left in the body where they will possibly decompose gradually and be replaced by vital tissue.

To stabilize a bone fracture, a fixation plate with the appropriate holes in the region of the fracture can be fixed using screws as mentioned above. The plate and screws may consist of metal (for example, stainless steel or titanium). The screws can be self-cutting and rotate into openings without thread in the bone, or they can be screwed into threaded openings pre-drilled. The plugs can be inserted into openings that have been previously created for similar purposes. Connections created in the above manner are normally based on friction closure, possibly in positive fit. Substantial pressure can be applied to living tissue during implantation.

The use of curable plastic materials (for example, particular cements on a water or polymeric basis) to create connections of the type mentioned is also known. Such materials are pressed from the outside between the implant and the vital tissue, or in tissue defects in a highly viscous condition, and are cured in situ. Positive fit connections using said material can be created, if the openings in which the material is pressed comprise suitable fillets. In order to reduce the tension and / or the cost of the corresponding operating procedure, the so-called biodegradable implants can be used, for example, bone pins. That is, bone pegs that degrade over time and are then absorbed by the body. One such known biodegradable bone peg is known under the trademark Polypin. This bone plug consists of a mixture of polyactide-copolymer and is absorbed over a period of approximately two years.

It is also known in the art the use of thermoplastic polymeric materials that can be liquefied in a desired manner by means of mechanical oscillation, such as ultrasonic oscillations and, in this condition, can be pressed into the cavities by means of hydrostatic pressure, thereby creating Positive fit connections after solidification.

Said implants can serve to create positive fit connections to parts of the tissue and can consist, at least partially, of a material that can be liquefied at a relatively low temperature (<250 ° C) by means of mechanical oscillation so that the material can Pressed into the pores or other openings of the tissue part by the effect of external pressure to form positive fit connections when it solidifies again.

In a prior art approach, an implant pin for implantation in an objective structure comprises a region of the base and a region of the rod. The base region comprises a connection portion that is adapted to interact with a coupling region of a sonotrode that applies ultrasonic vibrations. The rod region comprises a material that can be liquefied by the application of ultrasonic vibrations. Therefore, when ultrasonic vibrations are generated in the sonotrode and transmitted to the region of the base of the implant pin, these ultrasonic vibrations are further transmitted to the region of the rod. On a surface, in which the region of the rod adjoins the target structure, such as, for example, a bone in which a concavity has been formed in order to accommodate the implant pin, the local surface surface temperature increases due to friction between the target structure and the vibratory implant pin. This increase in surface temperature causes a melting of the liquefiable material so that the latter can flow through the pores of the bone. After the resolidification of the liquefiable material, a positive adjustment connection can be created between the implant pin and the bone.

However, with this prior art implant pin, the surfaces of the implant pin rod region that will be connected to the target structure have to be in direct contact with the target structure while ultrasonic vibrations are applied. For example, when the implant pin is to be fixed to a bone, it has to be inserted into a concavity previously prepared in the bone and has to come into contact with the inner surface walls of the concavity in order to liquefy the material of the rod region in these locations. For this purpose, it may be necessary to precisely adapt the geometry of the implant pin to the geometry of the concavity in the bone. In addition, it may be necessary to exert a substantial pressure on the implant pin while ultrasonic vibrations are applied in order to liquefy the material from the rod region, and this substantial pressure can be transmitted to the inner surface of the concavity in which Bone location may be sensitive to injuries.

In addition, the prior art implant pin indicated above must have sufficient rigidity in order to transmit the ultrasonic vibrations applied to the region of the base with respect to the region of the rod such that the region of the rod vibrate enough in order to melt the liquefiable material at this rod location.

WO 02/069817 A1, WO 2004/017857 A1 and WO 2005/079696 show implant pins having regions that include a moldable material that can be liquefied by the application of ultrasonic vibrations. In them, the liquefiable moldable material can flow through channels from an inner portion of the plug to an outer portion of the plug.

A fixing device with the features defined in the preamble of claim 1 is known from WO02 / 069817 A1 mentioned above.

Summary of the Invention

There may be a need to provide a fixing device for applying an implant pin to an objective structure that can overcome, at least in part, the deficiencies described above in the prior art. In particular, there may be a need to provide a fixing device with the help of which an implant pin is adapted so that the liquefiable moldable material can be provided inside an objective structure without applying excessive mechanical tension to the interior of the structure objective.

This need can be satisfied with a fixing device according to the independent claim. The embodiments of the invention are described in the dependent claims.

In the following, additional features that are useful for understanding the invention are described.

An implant pin is described for implantation in an objective structure in which the implant pin comprises a pinhead and a rod. The pin head comprises a pin head molding portion comprising a moldable material that can be liquefied by the application of energy, preferably mechanical energy. In the implant pin a channel extends along the pin head and the rod, and the channel connects the pin head molding portion to a discharge opening located on the rod.

To liquefy the moldable material on the pinhead, the source of ultrasonic vibration has to be depressed on the pinhead in order to effectively transmit the ultrasonic vibration energy to the pinhead molding portion. However, this pressure is not mainly applied to the possibly sensitive inner surface of the concavity or hole in the bone, since the rod does not have to snap into this concavity or hole. Instead, the pressure can be applied mainly to the outer surface of the bone that surrounds the concavity or the hole that is so unresponsive that it has not been previously damaged.

The pinhead can have any desired geometry and can be adapted to cooperate with a source of mechanical energy, such as a source of ultrasonic vibrations. The geometry of the rod must adapt to the geometry of the concavity in the objective structure in which the implant pin will be implanted. Since the concavity is normally prepared by perforation, the rod can have an elongated geometry with a circular cross section. Since the concavity that is prepared by a drilling tool can have a conical terminal portion, the tip of the rod distal to the pinhead can also have a corresponding conical shape, for example, in the form of a pointed end. However, since the distal end of the rod is not used to apply high pressure on the bone while the implant pin is inserted and fixed within the bone, unlike the prior art implant pins, the Implantation pin does not necessarily need said pointed end, but can also be blunt or flat.

The pinhead molding portion may be a partial portion of the pinhead consisting of a moldable material. Alternatively, the entire pinhead can be made of a moldable material in which only a partial region of the pinhead will actually be liquefied, since the contact surface between the mechanical power source and the pinhead is only a partial surface of the entire pinhead.

The moldable material can be any material that can be liquefied by the application of energy, particularly mechanical energy, and more particularly by the application of ultrasonic vibration energy. In other words, the moldable material must be such that it is originally solid and becomes liquid or plasticized after the application of energy. Preferably, the moldable material can be adapted such that its liquefaction can be achieved by an energy input that does not destroy or damage human tissue, particularly bone tissue. The moldable material can be, for example, a thermoplastic material. Said material can be liquefied or plasticized at elevated temperatures. For example, the material and geometry of the implant pin can be selected to show a sufficient degree of liquefaction at temperatures below a predetermined temperature threshold, such as not to substantially damage any tissue. Examples of moldable materials may be thermoplastics, such as, for example, PA (Polyamide), PC (Polycarbonate), PP (Polypropylene), PE (Polyethylene), PMMA (Polymethylmethacrylate), POM (Polyoxymethylene), PES (Polyethersulfone), PEI (Polyetherimide), PPSU (Polyphenylsulfone), PEEK (Polyethethercetone), PSU (Polysulfone) or the bio-compatible or bio-reabsorbable materials mentioned further below.

The liquefaction of the moldable material should be such that the liquefied material can easily flow through the channel that extends from the pinhead molding portion. Therefore, the liquefied material must have such a low viscosity that it can be pushed through the channel without applying excessive pressure on the implant pin in order not to damage or injure the target bone structure.

A main characteristic function of the implant pin can be seen in the channel that connects the pinhead molding portion to a discharge opening located separately from this molding portion. This channel allows a spatial separation between the location of the application of the mechanical energy that thus liquefies the moldable material, and the location of the application of the liquefied material in a region between the rod of the implant pin and the surrounding objective structure . In addition, the region in which the pressure applied from a mechanical energy source is transmitted over the target structure, such as bone, and the region in which the liquefied material is applied to the target structure through the channel can be different

It should be noted that a single channel that connects the pinhead molding portion to a single discharge opening in the rod may be sufficient. However, a plurality of channels and / or a channel can be provided that branches off into several branches and leads to a plurality of discharge openings located at different positions on the rod and / or on the pinhead in order to distribute the moldable moldable material advantageously to a plurality of locations within the concavity in the target structure in which the implant pin will be placed.

The channel can extend internally through the pinhead and the rod. In other words, the channel has its origin adjacent to the pinhead molding portion and then runs through the rod to the discharge opening. For example, the channel may extend along a central longitudinal axis of the implant pin.

The at least one channel discharge opening can be located on a lateral surface of the rod. In this way, the liquefiable moldable material can be transferred to a circumferential surface of the rod in such a way that a positive fit can be obtained between the lateral surface of the rod and the side walls of the concavity in the objective structure.

The discharge opening can be located at one end of the distal rod of the pinhead. In other words, at least one discharge opening of the channel can be discharged into the concavity of the target structure at a position closer to a distal end of the rod than to the pinhead. Preferably, the discharge opening is located in direct proximity to the distal end of the rod. Thus, the liquid moldable material can exit the channel in a deep position inside the concavity in the objective structure thus supporting a secure fixation of the rod within its concavity.

The rod may comprise a rod molding portion adjacent to the channel, the rod molding portion comprising a moldable material that can be liquefied by the application of mechanical energy. In other words, the implant pin comprises both a pinhead molding portion and a rod molding portion where the material can be liquefied by applying, for example, ultrasonic vibration energy. Accordingly, the molding portions are not limited solely to the pinhead but also extend to the rod thereby providing a larger volume of moldable material. Preferably, the rod molding portion is located directly adjacent or continuous to the pinhead molding portion. In addition, the moldable materials of the pinhead molding portion and the rod molding portion may be the same or similar.

The implant pin can consist entirely of a single material. In this example, the entire implant pin can be made of a moldable material and can be manufactured, for example, in the form of a single integral component. In this embodiment, the pinhead molding portion and / or the rod molding portion can be defined as partial areas of the implant pin which, during use, are actually liquefied by the application of mechanical energy, for example, using an ultrasonic sonotrode, whose geometry is specially adapted to the geometry of the implant pin. Providing the entire implant pin with a single material can significantly simplify the manufacturing of said pin. For example, the plug can be made by injection molding.

The pinhead may have a larger lateral dimension perpendicular to a longitudinal axis of the pin than the rod. In other words, with respect to the width perpendicular to the longitudinal axis of the pin, the pin head is wider than the rod. In this example, if both the pinhead and the rod have a circular cross-section, the radius of the pinhead is larger than the radius of the rod. Accordingly, the plug can be inserted with its rod into a concavity of the target structure until the wider pinhead borders the circumferential edge of the concavity. The rod itself may or may not only slightly contact the surfaces of the concavity in the target structure. Thus, when pressure and vibrations are applied to the implant pin, forces are mainly transmitted to the outer surface of the target structure, such as a bone, while the internal part of the bone in the concavity that houses the rod will not be loaded or It will only slightly.

The channel can flow into a plurality of discharge openings in various surface portions, preferably opposite side surface portions, of the rod. In other words, the channel from the molding portion can branch into several subchannels that can lead to a plurality of discharge openings. These discharge openings can be located on the lateral surface of the rod in opposite locations such that the liquefiable moldable material from the molding portion can be distributed homogeneously around the lateral surfaces of the rod. The subchannel or subchannels can be branched from the central main channel at an obtuse angle in order to improve the fluid properties of the liquefiable moldable material through the channels.

An additional channel can be extended through the pinhead, the channel that connects the pinhead molding portion to a discharge opening located on a surface portion of the pinhead. In other words, one or more additional channels may be provided in the implant pin so that the pinhead molding portion is not only connected to one or more discharge openings in the rod, but is also connected to a or more additional discharge openings located on the pinhead on a surface that, during use, is directed at or near the target structure in which the implant pin will be implanted. Thus, additional stability of the connection between the implant pin and the objective structure can be obtained since the implant pin is not only "glued" to the inside of a concavity in the objective structure, but also the pinhead of the Implant pin is "glued" to the surface of the target structure.

At least one of a surface coating of the implant pin, a bulk material of the implant pin and the moldable material may comprise a bio-compatible material. A bio-compatible material can be a material that does not interfere negatively with human or animal tissue.

Examples of bio-compatible materials can be specially adapted metal alloys, such as titanium or specific plastics, for example, PEEK (Polyethetherketone), UHMWPE (Ultra Molecular Weight Polyethylene), PLA (Polylactic Acid), PLLA (Poly-L- lactide), PLDLA (Poly (D, L-Lactide)), PDL-LA (Poly-DL-lactide), PVDF (Polyvinylidene Difluoride). Such bio-compatible materials can be used especially for the outer "skin" of the implant pin in order to avoid rejection of the implant pin when implanting the pin, for example, in a bone. It is advantageous to use a biocompatible thermoplastic that can be used both for the outer skin of the plug, as well as for the internal moldable material so that the entire implant pin can be made of this unique bio-compatible material.

At least one of a surface coating of the implant pin, a bulk material of the implant pin and the moldable material may comprise a material bio-absorbable material. Said bioabsorbable material can be absorbed by the body of a human being or an animal after a certain period such that the parts of the plug consisting of said bio-absorbable material can be replaced by living tissue after this period, providing this mode an increase in the stability of the connection between the implant pin and the living tissue and a reduction of rejection reactions.

A possible bio-absorbable material comprises a copolymer comprising between 50% and 90% Poly-Llactide and between 10% and 50% Poly-D, L-lactide. In particular, the bio-absorbable material may be a copolymer comprising 70% by weight Poly-L-lactide and 30% Poly-D, L-lactide by weight. Preferably, the bioabsorbable material may be formed of an amorphous material.

The material described above may be a suitable material for an implant pin, the material of which may exhibit a suitable tensile strength of approximately 60 MPa, and a suitable E module of approximately 3500 MPa. In addition, an implant pin that includes the above material can maintain its resistance for approximately a sufficient time when implanted in the body of a human being or an animal. A time period of this type can be approximately 16 to 26 weeks. The copolymer described can have a reabsorption time of approximately two to three years in the body of a human being or an animal. The material may additionally show an increase in implant volume of up to 200% after 24 months from implantation in the target structure. Such a material can also be easily sterilized by radiation and. An adequate energy dose may be between 20 kGy and 30 kGy, in particular below 25 kGy.

One aspect of the present invention relates to a fixing device that is adapted to fix an implant pin according to the above description. The fixing device comprises an ultrasonic sonotrode comprising a vibration rod adapted to generate ultrasonic vibrations at a tip provided in the vibration rod. In addition, the fixing device comprises a guiding mechanism adapted to cooperate with the implant pin in order to align the guiding mechanism with respect to the implant pin and adapted to guide the vibration rod and / or the tip provided in the rod

It can be seen how the essence of this aspect of the invention is to provide a fixing device that, on the one hand, includes a source of ultrasonic vibration and, on the other hand, is adapted to apply the ultrasonic vibrations generated in a predetermined manner to the implant pin described above in accordance with the first aspect of the invention in order to liquefy the moldable material of the implant pin in the region of the moldable portion or portions. In order to be able to apply the ultrasonic vibrations in said predetermined manner, the sonotrode comprises a tip at which the ultrasonic vibrations are generated. In addition, a guiding mechanism is provided such that the position and direction of travel of the vibrating tip can be controlled as desired during an operation. Specifically, the guiding mechanism may be adapted in such a way that it can cooperate with implant pin structures, such as, for example, the surface or circumferential of the pinhead in order to align the position of the fixing device. with respect to the implant pin. For this purpose, the guiding mechanism may have specially adapted support surfaces in order to maintain or fix the guiding mechanism to the implant pin.

In addition, the guiding mechanism may be adapted to guide the vibration rod and / or the tip with respect to the implant pin. For example, the guiding mechanism may have a sliding mechanism such that, after it is fixed with respect to the implant pin, the tip of the ultrasonic sonotrode can slide or move in a predetermined direction with respect to the guiding mechanism. In this way, the vibrating tip can be further displaced by the molding portion of the implant pin at the same time that the moldable material is liquefied thereon, thereby pushing the liquefiable moldable material through the channel of the implant pin .

The ultrasonic sonotrode may be adapted to generate ultrasonic vibrations at the tip with a frequency of between 10 and 50 kHz, preferably, between 20 and 30 kHz, and a suitable amplitude of vibration may be in the range of between 1 and 100 µm, preferably between 5 and 30 µm. The vibrations may preferably be generated in a direction along the vibration rod and / or in a direction perpendicular to the vibration rod. All sonotrode construction, including the rod and the tip, must be adapted so that ultrasonic vibrations can be properly transmitted through the vibration tip to a target region in an implant pin. For example, the rod and the tip must comprise sufficient rigidity in order to transmit the vibration energy through the vibration tip.

The guiding mechanism may be adequately adapted to maintain or guide the sonotrode and / or its vibrating tip with respect to the implant pin to which the guiding mechanism is fixed. In addition, a damping element may be provided in the guiding mechanism such that the vibrations of the sonotrode are not substantially transmitted to the guiding mechanism in order to prevent the implant pin from vibrating through the guiding mechanism in undesired locations. .

According to one embodiment, the guiding mechanism is adapted to guide the vibration rod in a parallel direction along the longitudinal axis of the implant pin. In other words, the vibrating tip disposed on the vibration rod can advance in a direction parallel to the longitudinal axis of the implant pin guided by the guiding mechanism that can be fixed with respect to the implant pin. Thus, the fixing device can be used to liquefy the moldable material of the implant pin into predetermined regions, namely, for example, regions along the longitudinal central axis of the implant pin. Since the channel of the implant pin also preferably extends along this central axis, the vibrating tip that preferably has a lateral dimension greater than the channel of the implant pin, can be introduced into the molding portion of the pin of implantation at the same time that the moldable material is liquefied therein, thereby pushing the moldable moldable material through the channel.

According to a further embodiment, the tip on the vibration rod has a smaller lateral dimension perpendicular to the longitudinal axis of the rod than the pinhead of the implant pin. In other words, the width of the tip is smaller than the width of the pinhead or, again in other words, the contact surface between the vibrating tip and the pinhead is smaller than the entire surface of the pinhead. Therefore, when the vibrating tip is in contact with the pinhead of the implant pin, only a partial region of the pinhead that can correspond to the pinhead molding portion can be liquefied. Particularly, the geometry and / or the cross section of the vibrating tip may be adapted to correspond with the geometry and / or the cross section of a molding portion of a particular implant pin.

According to a further embodiment, the tip on the vibration rod has a smaller lateral dimension perpendicular to the longitudinal axis of the vibration rod than the rod of the implant pin. In other words, the width or cross section of the vibrating tip may be smaller than the width or cross section of the rod of the implant pin. Accordingly, the vibrating tip can be inserted, for example, into the rod molding portion of the rod of the implant pin in order to liquefy the moldable material in this part of the pin rod.

According to the invention, the tip on the vibration rod has regions of different lateral dimensions. In other words, the width or size of the cross section of a tip may vary along the direction of the longitudinal axis of the vibration rod. Therefore, while the moldable material is liquefied and the vibrating tip is pushed to the implant pin regions of different cross-section can be liquefied. For example, a distal portion of the vibrating tip may have a width smaller than the rod of the implant pin, while a proximal portion is wider than the distal portion and has a width that is slightly smaller than the width of the pinhead of the implant pin but possibly wider than the rod of the implant pin.

An implantation kit may be provided that includes an implant pin. In addition, the implantation kit may comprise a fixation device according to the invention. Additionally, the implant kit may comprise additional elements or components, such as, for example, a multitude of implant pins of different geometry, such that a surgeon can choose an implant pin that matches the geometry of a concavity that It has been previously prepared in a bone. In addition, a plurality of vibrating tips for the sonotrode can be included in the implant kit in which the tips can have different geometries adapted to different implant pins.

The aspect and embodiments that have been defined above and the aspects and additional embodiments of the present invention are apparent from the examples of embodiments that will be described hereafter in this document and are explained with reference to the embodiments. The invention will be described in more detail hereinafter with reference to embodiments, but to which the invention is not limited.

Brief description of the drawings

Figure 1 shows an implant pin that has an inner channel.

Figure 2 shows an implant pin having an additional channel in the pinhead.

Figure 3 illustrates an implantation procedure using an implant pin and a fixation device.

Figure 4 illustrates an implantation procedure using an implant pin and a fixation device according to an alternative embodiment of the present invention.

It should be noted that the figures are only schematic and are not to scale. The corresponding reference signs have been used throughout the figures to designate similar elements.

Figure 1 shows an implant pin 1 that includes a pin head 3 and a rod 5. The entire implant pin is made as an integral part from a moldable material that is biocompatible or bioabsorbable. The pin head 3 comprises a pin head molding portion 7. The rod 5 comprises a rod molding portion 9. Both molding portions 7, 9 are arranged adjacent to a channel 11 that connects the molding portions 7, 9 to the discharge openings 13 located at a distal end of the rod

5. The channel 11 is arranged linearly along the longitudinal axis 15 of the implant pin and two subchannels 17 connect the channel 15 in the middle of the pin to the lateral surface of the rod.

The width w2 of the rod 5 is smaller than the width w3 of the pinhead. A cylindrical concavity 19 is provided on the upper surface of the pinhead 3. The concavity 19 has a smaller lateral dimension w1 than the lateral dimension w2 of the rod 5.

The implant pin 1 'of Figure 2 additionally includes more channels 21 leading to the discharge openings 23 located in a lower lateral surface portion of the pin head 3'.

With respect to figure 3, a procedure for implanting and fixing an implant pin is described.

First, a concavity 31 is drilled in an objective structure 33, such as a bone. Then, an implant pin 1 is inserted as shown in Figure 1 in the concavity 31. In it, an implant pin 1 with such a geometry is chosen such that the contour of the implant pin 1 is slightly smaller than the concavity 31, so that a small gap is established between the concavity 31 and the implant pin 1. The pinhead 3 of the implant pin 1 adjoins the upper surface 35 of the bone 33 in a contact region 37.

A fixing device 41 is placed on top of the implant pin 1. The fixing device 41 comprises a sonotrode 43 with a vibration rod 47 and a tip 45 provided on the vibration rod

47. The sonotrode 43 includes an ultrasonic vibration generator 49 to which the vibration rod 47 is fixed. The ultrasonic vibrations generated by an ultrasonic generator 49 are transmitted to the tip 45 through the vibration rod 47.

In order to align the fixing device 41 with respect to the pin 1 a guiding mechanism is provided

51. The lower portion of the guiding mechanism 51 is adapted to cooperate with the pinhead 3. In the upper portion of the guiding mechanism 51 is a sliding mechanism 53 which is adapted such that the rod 47 of the sonotrode is guided linearly when sliding along the sliding mechanism 53. In addition, the recess 19 in the pinhead 3 can help align the tip 45.

The distal part of the vibrating tip 45 comprises a cylindrical end portion 61 having a concave surface 63 at its lower end.

5 When the tip 45 guided on the vibration rod 47 is excited by ultrasonic vibrations, the moldable material of the implant pin 1 is liquefied in a contact region between the cylindrical end portion of the tip 61 and a pin 1. According to the tip 61 is pushed toward the distal end of pin 1 the liquid moldable material is forced through the channel 11 in the pin and exits through the discharge openings 13 in the space between pin 1 and the concavity 31.

After resolidification of the moldable material, the pin 1 is securely fixed inside the concavity 31. During the fixing procedure, excessive force is not applied to the interior of the concavity 31 but the pressure applied by the tip 45 of the sonotrode 41 is mainly transmitted to the contact surface 37 and is thus applied to an outer surface 35 of the bone.

15 After removal of the pin 1 fixing device, a separating element 71 is used to fill the remaining space inside the pin 1 that has been generated by pushing the vibrating tip 61 through the moldable portions of the pin 1 Accordingly, the cross section of the separator 71 must correspond substantially to the cross section of the vibrating tip 61. The separator element 71 can be of any material since it is not in direct contact with the vital tissue. For example, the separator element 71 can be provided with a metal, such as to stabilize the implant pin itself consisting of a moldable plastic.

With respect to Figure 4, an alternative example of a procedure for the implantation and fixation of an implant pin 1 'as shown in Figure 1 is described.

The implant pin 1 'additionally comprises the channels 21 in the pin head 3'.

The fixing device 41 'comprises a sonotrode 43' with a vibration rod 47 'in which a vibrating tip 45' is provided. The tip 45 'comprises a lower portion 81 with a width smaller than the width of the rod 5' of the plug 1. When the plug is fixed in the recess 31, first of all this lower portion 81 of the tip 45 'is Insert into the implant pin 1 'by liquefying the moldable material.

The tip 45 'further comprises an upper portion 83 having a width greater than the lower portion

35 81. While pushing the vibrating tip 45 'into the plug and thereby pressing the moldable material through the channel 11' and into the space between the plug 1 'and the concavity 31, the upper portion 83 will come into contact with the upper surface of the pinhead 3 'after a certain distance. Then, the upper portion 83 of the tip 45 'will liquefy more amount of moldable material on the pinhead 3' and this material will flow through the additional channels 21 and will exit from the discharge opening 23 resting above the surface of the bone. Liquefied moldable material will flow to the surface of the bone and "stick" the 3 'pinhead to the bone in this region.

Again, after removing the fixing device from the fixed pin, a separator 71 'is inserted into the remaining hollow space inside the pin 1'.

45 It should be noted that the terms "comprising" or "including" do not exclude other elements or stages, and "a" or "a" do not exclude a plurality. It should also be noted that the reference signs in the claims will not be construed as limiting the scope of the claims.

List of reference signs

1 implant pin 3 pinhead 5 rod 7 pin head molding portion 9 rod molding portion 11 channel 13 discharge opening 15 longitudinal central axis

17 subchannel 19 concavity 21 additional pinhead channel 23 discharge head opening

pin 31 concavity 33 objective structure 41 fixing device 43 sonotrode 45 vibrating tip 47 vibration rod 51 guiding mechanism 53 sliding mechanism 61 end portion of cylindrical tip 63 end portion of concave tip 71 spacer

Claims (4)

1. A fixing device (41) adapted to fix an implant pin (1) in an objective structure, in which the implant pin has a longitudinal axis (15) and comprises a pin head (3) having a pinhead molding portion (7) and a rod (5) having a rod molding portion (9), the pinhead molding portion and the rod molding portion comprising a moldable material that can be liquefied by applying energy, comprising the fixing device: an ultrasonic sonotrode (43) comprising a vibration rod (47) adapted to generate vibrations ultrasonic on one end (45) provided on the vibration rod; a guiding mechanism (51) adapted to cooperate with the implant pin in order to align the guiding mechanism with respect to the implant pin and adapted to guide the vibrating tip, characterized because The tip on the vibration rod has regions (81, 83) of different lateral dimensions.

2.

The fixing device according to claim 1, wherein the guiding mechanism is adapted to guide the vibration rod in a parallel direction along the longitudinal axis of the implant pin.

3.

The fixing device according to claim 1 or 2, wherein the tip in the vibration rod has a smaller lateral dimension perpendicular to the longitudinal axis of the rod than the pin head of the implant pin.

Four.

The fixing device according to any one of claims 1 to 3, wherein the tip in the vibration rod has a smaller lateral dimension perpendicular to the longitudinal axis of the rod than the rod of the implant pin.