KR100509625B1 - Osteosynthetic implant with an embedded hinge joint - Google Patents

Abstract

The present invention relates to an implant device comprising an artificial osteotomy implant or implant element and at least one rotating means 10 coupled to the implant or implant element. Each rotating means 10 comprises at least one flat or annular gimbal 4; 16 and two rod-shaped connecting members 5; 15 per gimbal 4; 16. The member is formed along one axis (11; 18; 36; 37) and forms a pivot axis about the outer periphery of the gimbal (4; 16). One gimbal 4; 16 is alternately coupled to an implant or implant element by means of a connecting member 5; 15. According to the design of the rotating means 10 it is used to receive the bone bonding means (1; 19).

Description

Osteosynthetic implant with an embedded hinge joint

The invention relates to an instrument, as defined in the preamble of claim 1, comprising a mandibular implant, an implant element and at least one rotating means connected to the implant, the implant element.

Longitudinally supported longitudinal supports, such as metal plates or rods, are increasingly used in artificial bones. First and foremost, the supports are advantageous for treating fractures near the joint and for fixing screws in the spinal column. When only short screws are used, they are inserted into the longitudinal support at an angle. However, if very long screws are to be used, problems arise due to system pressure and the fixed screw orientation. In order to solve the problem of the immediateness of the range of the spinal column, a special ball joint was developed. The feature of the technique is to give a boring hole specially formed to accommodate the correspondingly formed screw head, and to fix the bone screw in the bone stably independently of the direction. Corrugated plates with screw heads matching such specially formed screw holes are described in German patent 195 48 395.

However, in the implant section, neither the ball joint nor the screw heads with matching boring holes is the best way to deal with the above problems with system compression, defined bone screw orientation. It is because the manufacturing method is very complicated or the load strength of the attachment is not appropriate. Moreover, as is indicated, this known design is very large. DEZOL 38 24 669 of Bezould discloses an artificial osteotomy plate with screw holes having a distance which is varied by externally applied forces. The screw hole is provided in the eye formed by cutting a part of the main body of the artificial osteotomy plate and is connected to the artificial osteotomy plate only through an elastic pin. In one example of such a known device, the pins are aligned in one axis, connected to the eye and opposite to this axis. A disadvantage of this known device is that the pin is bent by the rotation of the eye about the plane of the plate such that the axis of rotation no longer coincides with the axis of the eye and the screw hole. In addition, as the eye rotates, the center of the screw hole is moved, which is negative in medical applications.

1 is a longitudinal sectional view and a plan view of a corrugated plate integrated into the rotating means of the present invention.

Figure 2 is a plan view of a corrugated plate integrated into another embodiment of the rotating means of the present invention.

Figure 3 is a longitudinal sectional view through two femoral bones integrated into another embodiment of the rotating means of the present invention assembled with a hip screw.

4 shows an elevation view, a side view and a bottom view of the vertebral splicing means integrated into another embodiment of the rotating means of the invention,

Figure 5 is a perspective view of the spinal unit united in another embodiment of the rotation means of the present invention.

6 is a cross-sectional view of another embodiment of the spinal unit which is integrated into another embodiment of the rotating means of the present invention.

7 is an elevation view of the spinal unit of FIG. 6.

FIG. 8 is a view of the spinal unit of FIG. 6 with an upright spinal plate end;

It is an object of the present invention to reduce the size. In other words, with respect to the corrugated plate, a planar rotation means is made to connect an implant element such as a bone screw in a single or double gimbaled manner together with other implant elements.

The present invention solves this problem by means of a mechanism consisting of an artificial osteotomy implant or implant element, and at least one of the features of claim 1 and one rotating means connected with the implant or implant element.

Another advantageous embodiment of the invention is defined in the dependent claims.

In a preferred embodiment of the instrument of the present invention, the rotating means placed in the artificial osteotomy implant is located on an axis opposite to one axis and bonded inward to the plane or to the annular gimbal outward with respect to the implant or implant element. Two planar, rod-shaped connecting members. The gimbal is mounted through the connecting member so as to be rotatable about the axis of rotation formed by the arms, and is fixed to the borehole of the implant or implant element.

Another embodiment of the invention differs from the above embodiment only in that it is integral with an implant or implant element and rotation means comprising a connecting member and a gimbal.

Another embodiment of the present invention is that the two planar, rod-shaped coupling means are adapted because of the plastic deformation that allows the angularly fixed position of the gimbal in which they are rotated relative to the implant or implant element. It differs from the embodiment only in that it is large.

Another embodiment of the present invention is that a connecting member and an implant or implant element between a planar or annular gimbal is replaced by a pivot axis, and the gimbal is concentric with the boring hole of the implant or implant element. It differs from the above embodiments only in that it is supported and rotatable about a pivot axis.

Another embodiment of the invention differs from the above embodiments only in that the thickness of the pivot element is less than or equal to the thickness "b" of the implant wall receiving the implant or rotating means.

Another embodiment of the invention is that two gimbals are superimposed on one another so that the outer gimbal is installed in the boring hole in the implant or implant element, and the other inner gimbal is the outer gimbal. Same as the above embodiments except that it is rotatably supported in a boring hole in.

Another embodiment of the present invention is identical to the above embodiments except that the rotational axes of the rod-like couplings of the two complementary gimbals are inclined at 90 degrees.

Another embodiment of the invention is that the gimbals are separated by slots from the implant or implant element to the connecting members, except that these slots are annular. Is the same as

Another embodiment of the present invention is characterized in that the rotating means is integral with the corrugated plate.

Another embodiment of the invention is characterized in that the rotating means is integral to the receiving head for connecting the pedicle screw with the longitudinal support in the spinal joint system.

In another embodiment of the present invention each one of the rotating means is characterized in that it is integral to the upper and lower portions of the spine.

In another embodiment of the present invention, the spinal unit is designed such that the two vertebral plate ends, to which the element is coupled, are connected to bars at both ends of the inner gimbal perpendicular to the axis of rotation of the rotating means. The end of the spinal plate adjacent to the vertebra is elliptical and is engaged with the connecting member of the outer gimbal. Thus, the two spinal plate ends are each connected to the rod by means of rotation, in a manner of rotation about at least one axis of rotation.

Another embodiment of the present invention is the same as the above embodiment except that the gimbal is assembled in the boring hole to receive the bone bonding means, in particular the bone screw or the pedicle screw.

In another embodiment of the present invention, the gimbal boring hole receiving the bone joint means is conical, and the bone joint means or the bone screw or the pedicle screw is fitted with a corresponding conical screw, and the angularly fixed coupling is It differs from the above embodiment in that it can be made between graft or graft elements and bone bonding means.

In another embodiment of the present invention, in connection with the above embodiment, the boring hole of the gimbal is assembled to the internal threaded portion, and the bone joining means, the bone screw or the pedicle screw are screwed together with the corresponding external threaded portion. It is characterized in that it is assembled to the head and thus an angled bond can be formed between the implant or implant element and the bone bonding means.

Another embodiment of the present invention is that bone bonding means such as bone screws or pedicle screws are assembled to expandable heads, and the tightening screws, which are pieces of expandable heads, are pressurized against the boring hole walls. Angledly anchored bonds are distinguished from the above embodiments in that they can be formed between an implant or implant element and bone bonding means.

In another embodiment of the present invention, the gimbal boring hole is fitted to a conical inner sickle, and bone joining means such as a bone screw or a pedicle screw are assembled to a corresponding outer screw portion at a screw head, so that It is distinguished from the above embodiment in that a fixed bond can be formed between the implant or implant element and bone bonding means.

Another embodiment of the present invention is characterized in that the rotating means is integral to the receiving head for engaging the pedicle screw and the longitudinal member in the spinal joint system.

An essential advantage of the present invention is that the rotating means of the present invention allow for a simpler design and a shorter length than ball coupling.

The invention and its improvements will be described with reference to various schematic embodiments shown in the following partial schematic drawing.

1 shows a schematic embodiment of the rotating means 10 of the present invention installed on the corrugated plate 3. The corrugate plate 3 has threaded holes 7 penetrating from its upper face 13 to the lower face 14. The screw holes 7 have a central axis 12 and receive the bone screw 1. By machining two semicircular slots 6 having a wider diameter from the corrugated plate 3 concentrically to the threaded hole 7, the annular gimbal 4 is provided with two opposite connecting members ( 5) is connected. In the embodiment shown in FIG. 1, the connecting member 5 and the gimbal 4 are integrated together with the corrugated plate 3 in the forming parts as in the embodiment of FIG. 1.

The boring hole 8 and the boring hole 9 are constituted from the upper surface 13 and the lower surface 14 of the corrugated plates 3 coaxially with the central axis 12 and connected with such gimbal 4. The thickness "a" of the member 5 is smaller than the thickness "b" of the corrugated plate 3. In this case the embodiment of the rotating means 10 for the embodiment shown in FIG. 1 is merely a gimbal bounded by a connecting member 5, the rotating shaft 11 being the longitudinal direction of the corrugated plate 3. It passes through the connecting member (5). The screw head 2 of the bone screw 1 is located at the gimbal 4 and if the bone screw 1 should be tightened at an angle to the bone, then the rotation means 10 of the present invention is a gimbal 4 By pivoting the element 4 in the desired direction with respect to the connecting member 5 by means of a rod inserted into the boring hole 7. The bone screw 1 can then be tightened in that position at a fixed angle.

Embodiment of the rotation means 10 of the present invention shown in Figure 2 is a circular outer gimbal (with a connecting member 5 installed therein is another connecting member 15 offset by 90 degrees from the connecting member 5) It is the same as FIG. 1 except that it is installed in the gimbal) 16. FIG. The outer and mutually opposite connecting members 15 connect the outer outer gimbal 16 to the corrugated plate 3 and the outer gimbal relative to the axis 18 which runs parallel to the longitudinal direction of the corrugated plate 3. allow pivoting (gimbal) 16. The connecting member 5 is installed in a circular, external gimbal 16, which connects the external gimbal 16 with an internal gimbal 4, and an internal gimbal 4. ) Pivot about the axis (11) passing across the plate in the longitudinal direction. The 90 degree offset of the inner connecting member 5 relative to the outer connecting member 15 enables a double gimbal system 10 between the inner gimbal 4 and the corrugated plate 3. As shown in the embodiment of FIG. 1, the inner gimbal 4, the connecting members 5; 15 and the outer gimbal 16 are integral to the bone plate 3. In this embodiment, the connecting members 5 and 15 are in the form of pins supported on the corrugated plate 3 at the outer gimbal 16 and the inner gimbal 4.

FIG. 3 shows another application of the corrugated plate 3 shown in FIG. 1 or 2 with an integral rotating means 10. The hip screw 19 passes through the corrugated plate 2 at an angle and is located there by the rotating means 10 shown in FIG. 1 or FIG. 2. As in the case of the embodiment of the rotating means 10 of FIG. 1, the screw head 20 of the hip screw 19 is located in the inner gimbal 4. The hip screw 19 is oblique to the corrugate plate 3 and the inner gimbal 4 will be pivoted in the desired direction before the hip screw 19 is placed in place. As shown in Fig. 1 or Fig. 2, the gimbal is positioned by the connecting members 5; The connecting members 5 and 15 are rigid between the corrugated plate 3, the internal gimbal 4 or between the corrugated plate 3, ie between the external gimbal 16 and the internal gimbal 4. Since the engagement is formed, a return force is formed when pivoting the rotating means 10 away from the seating position. In order for the heap screw 19 to be loaded solely by the axial force, the return force must be supplemented. In the application below the replenishment is carried out when the two corrugated plates 3 and 26 overlap and the shank 21 of the hip screw 19 is made to pass through the rotating means 10 of the present invention. The two bone plates 3 and 26 may be joined to the bone 25 by another bone screw 24. The direction of the hip screw 19 can be fixed and adapted to the place by swapping the two corrugated plates 3 and 26 with each other. The direction of the corrugated plate (3; 26) and the hip screw (19) is fixed in place by tightening the bone screw (24). The body 21 of the hip screw 19 is guided through boring holes 22; 23 at the inner gimbal 4 of the rotating means 10 of the present invention with respect to the two corrugated plates 3; 26. . Thus, despite the return force of the connecting members 5 and 15 shown in Figs. 1 and 2, when the corrugated plates 3 and 26 are held in place, the hip screws 19 with respect to the longitudinal axis 27 No force in the transverse direction is generated.

4 shows another application for the rotating means 10 of the present invention. As shown in FIG. 2, the rotating means 10 comprises an inner gimbal 4, an outer gimbal 16, and a connecting member 5; 15. In the present invention, the rotating means 10 couples the pedicle screw in the spinal joint system to the mechanism 34 for joining the pedicle screw 29 to the longitudinal support 32. Between the inner gimbal 4 and the outer gimbal 16 as well as the outer connecting member 16 between the outer gimbal and the receiving head 31 for the longitudinal support 32. The inner gimbal 4, the outer gimbal (gimbal) 16 and the inner connecting member 15 is integral to the receiving head 31. The pedicle screw 29 is made to pass through the boring hole 28 with respect to the screw head 30 in the inner gimbal 4 until the screw head 30 is positioned in the boring hole 28. . If the pedicle screw 29 is inclined with respect to the longitudinal axis 35 of the receiving head 31, the deviation angle will be absorbed by the rotating means 10 of the present invention. If a dual gimbal system 10 is used as shown in Fig. 2, the pedicle screw 29 is received head 31 about the axis 36; 37 bounded by the connecting member 5; Can be pivoted in connection with the If a single gimbal rotating means 10 is used as shown in Fig. 1, the pedicle screw 29 is pivoted about one axis 36 or 37 with respect to the receiver head 31 only. Can be

The application shown in FIG. 5 for an embodiment of the rotating means 10 of the present invention comprises one spinal unit 38 and two rotating means 10 of the present invention, the inner gimbal of which 4) acts as a surface lying on the spinal portion proximal to the implanted spinal unit 38. The vertebral unit is approximately right parallelepiped and includes an upper face 39, a lower face 40, a front face 41, a back face 42 and two sides 43 and 44. The spinal unit 38 includes other pass-boring holes 45 passing from the front to the back and a pass-boring hole 46 passing between the sides 43 and 44. Each of the upper and lower surfaces 39 and 40, and the spinal unit 38, the inner gimbal (4) of the rotating means 10 is installed in the upper portion 39, the lower portion 40 and the upper portion 39 and The top and bottom surfaces of each of the lower parts 40 are bent in such a manner as to constitute each other. In this particular application, therefore, the rotating means 10 of the present invention allow the use of the spinal unit 38 when the lower and higher surfaces are not parallel in the spinal cord. Rotating means 10 of the present invention is integral to the spinal unit 38 in each of the upper 39 and the lower 40. That is, the spinal unit 38 and the rotation means 10 of the present invention are integral. As shown in FIG. 2, the rotating means is pivotally connected to an inner gimbal 4 pivotally connected to an outer gimbal 16 by two connecting members 5 opposite to each other along an axis. It is composed. The external gimbal 16 is alternately pivotally connected by two mutually opposite external connecting members 15 along the axis, and is 90 degrees from the internal connecting member 5 to the spinal unit 38. Is offset. As a result, the inner gimbal 4, which serves as a surface for the portion of the spinal cord that strikes the spinal unit 38, is perpendicular to two mutually at the top 39 or lower 40 plane of the spinal unit 38. You can pivot about the in-axis. In a variant of this embodiment, the vertebral unit 38 comprises one rotating means 10 of the invention at the top 39 and one at the bottom 40 as well, between-vertebral or alternative-vertebral elements. Also used as.

Another embodiment of the spinal unit 38 is shown in FIGS. 6, 7 and 8. The rotating means 10 is integrated into the judging unit 61 of the spine unit which is composed of two laid gimbals 4 and 16 pivotably connected by the connecting members 5 and 15. When the rotating means 10 is not pivoted, the gimbals 4 and 16 are on a plate formed about the rotational shafts 11 and 18 and on the seating surface of the judging unit 61 of the spine unit. Passing in parallel The outer annular gimbal 16 is alternately connected to the spinal plate end 61 by two pivoting connecting members 15 in the outward direction, which ensures an oval shape. The outer gimbal 16 is also alternately coupled to the inner gimbal 4 by a connecting member 5 in the inner direction. The inner gimbal 4 is installed at both ends 63 and 64 of the rod 60 and the rod is perpendicular to both the plane bounded by the rotational shafts 11 and 18 and the inner gimbal 4. . The two lumbar end plates 61 are therefore each connected to the rod 60 by means of the rotation means 10 in order to pivot about a particular axis of rotation 11; 18.

This invention is such that the rotating means allows a simpler design and a shorter length than the ball coupling.

Claims (26)

An apparatus comprising an artificial osteotomy implant or implant element and at least one rotating means connected to the artificial osteotomy implant or implant element, a) at least one rotating means 10 is in the form of a single gimbal, b) said at least one rotating means 10 is mounted on at least one flat or annular gimbal 4; 16 and one axis 11 per gimbal 11; 18; 36; 37, Includes two flat, rod-shaped connecting members (5; 15) forming a rotation axis on the outer periphery, c) A device characterized in that one gimbal (4; 16) per rotation means (10) is rotatably connected to an implant or implant element by means of a connecting member (5; 15). The boring hole (7; 22; 23; 28) of claim 1, wherein the inner gimbal (4) passes perpendicular to the gimbal plate of pivoting defined by pivot axes (11; 18; 36; 37). Device having a. Device according to claim 1 or 2, characterized in that one implant or implant element is integral with the other rotating means (10). 3. The two flat and rod-shaped connecting members 5 and 15 have an inclined fixed position of the gimbal 4 and 16 due to the plastic deformation of the connecting members 5 and 15. An apparatus characterized in that it is formed on an implant or implant element. 2. The rotating means (10) according to claim 1, wherein the rotating means (10) is pivotable about the axes (11; 37), two gimbals (4; 16) lying on each other and two connecting members ( 5) a particular inner gimbal 4 which is coupled to a particular outer gimbal 16 by means of which the second outer gimbal 16 can be pivoted about an axis 18; 36. 15) by means of a device connected to the implant or implant element. 6. Device according to claim 5, characterized in that the pivot axes (11; 37) pass between the gimbals (4; 16) on which they are laid and the planes on which they pivot. 6. The pivotal shaft (11; 37) between the gimbals (4; 16) placed on each other is characterized by a 90 degree deflection relative to the outer gimbal (16) and the pivot axis (18) between the implant or implant element. Device. The flat and rod-shaped connecting member (5; 15) of the at least one gimbal (4; 16) and the implant or implant element (3; 26; 31; 39) is rotatable. Device supported on the axes. 2. Device according to claim 1, characterized in that the gimbal (4; 16) and the implant or implant element are separated from each other by slots (6; 17) up to the connecting member (5; 15). 10. Device according to claim 9, characterized in that the slots (6; 17) are arcuate arcs. 2. Device according to claim 1, characterized in that the implant to be joined to the rotating means (10) is a corrugated plate (3) of thickness "b" which is approximately perpendicular parallel hexagonal. Device according to claim 11, characterized in that the at least one gimbal (4; 16) has a thickness "a" that is thinner than the thickness "b" of the corrugated plate (3). 13. Device according to claim 11 or 12, characterized in that the flat, rod-shaped connecting member (5; 15) is a thickness "a" which is thinner than the thickness "b" of the corrugated plate (3). The method of claim 1, characterized in that the rotating means (10) is integral to the receiving head (31) for coupling the pedicle screw (29) to the longitudinal support (32) in the spinal joint system. Device. 15. The method of claim 14, wherein the rotating means (10) is formed to form an integrated unit together with at least one gimbal (4), the receiving head (31) for coupling to the longitudinal support (32), and the pedicle screw (29). Characterized in that the device. 2. The device of claim 1, wherein the implant is in the form of a mutual spine unit (38) or a spinal column unit. 18. The device according to claim 16, wherein each of the rotary means (10) is integral with the intervertebral unit (38) at the surface that can be joined to the upper (39) and lower (40) adjacent spinal column. . 17. The two rotating means (10) according to claim 16 are perpendicular to the pivot axis (11; 18) with respect to the ends (63; 64) of the rod (60) of length "c" by their inner gimbals (4). Device, characterized in that the gimbal (4; 16) is coupled to each rotating means (10) with respect to the spinal plate end (61). 2. Device according to claim 1, characterized in that the rotating means (10) are designed for receiving bone bonding means. 20. The device (1) (19) according to claim 19, wherein the device serving as bone joining means passes through a boring hole (7) in the gimbal (4) in which the screw head (2) rests on the gimbal (4). Wherein the bone screw (1; 19) is received in the corrugate plate (3) by means of a rotating means (10) to rotate about at least one axis (11; 18). 20. A screw according to claim 19, comprising an additional pedicle screw 29, such as bone joint means, wherein the screw 29 passes through a boring hole 28 in the gimbal 4, the screw head 30 of the gimbal And the pedicle screw 29 is rotated by means of rotating means 10 at the receiving head 31 of the spinal joint system 50 to rotate about at least one axis 36; 37. Device characterized in that it is accommodated. 22. The method according to claim 20 or 21, wherein the boring holes 28 in the gimbal 4 are conical, and bone joining means such as bone screws (1; 19) or pedicle screws (29) fit into the corresponding cones. A device comprising a screw head (2; 20; 30), wherein a fixed annular bond can be formed between the implant or implant element and the bone abutment means. 22. The boring hole 28 in the gimbal 4 is assembled to an internal threaded portion, and the bone joining means, bone screw 1 or 19 or pedicle screw 29 are correspondingly external. A device in which a screw head (2; 20; 30) or a body portion with a threaded portion is intimately coupled, an angularly fixed coupling can be formed between the implant or implant element and the bone abutment means. 22. The boring hole 28 in the gimbal 4 is assembled to an internal conical threaded portion, and the bone joining means, the corrugated plates 1 and 19, and the pedicle screw 29 correspond to each other. An apparatus characterized in that the screw head (2; 20; 30) having an external thread or a close coupling with the body part can be formed between the graft tissue or the graft element and the bone bonding means. 22. The device according to claim 20 or 21, wherein the bone abutment means, bone screw (1; 19) or pedicle screw (29) are assembled to an expandable head (2; 20; 30) and the means for tightening the screw By means of which parts of the expandable head are pressed against the wall of the boring (28), so that an angularly fixed coupling can be formed between the implant or implant element and the bone abutment means. Apparatus according to claim 1 or 2, characterized in that the rotating means (10) is a flat double-gimbal system.