IMPLANT, IN PARTICULAR A SPINAL IMPLANT

Abstract

A spinal implant, in the form of a multi-part connection device that couples a fastening element to a connection element, including a first part formed as a bracket, which has a receptacle for a part of the fastening element, and a second part in the form of a tulip, which has, in an axially upper region, a receptacle for the connection element and surrounds the bracket receptacle in an axially lower region. When the bracket is assembled in a predefined orientation in the tulip, the bracket can be axially moved in the tulip such that, when moved towards the upper region, in a receiving position the bracket can receive the part of the fastening element, and such that, when moved towards the lower region, in a holding position the bracket is no longer able to release the received part of the fastening element. An axial guide, for providing the axial movability, includes a projection region on the face of the bracket that is outside when viewed radially, which projection region engages in a cut-out region in the face of the tulip that is inside when viewed radially. The end regions, viewed azimuthally, of which projection region are spaced apart by at least 18°. An axial lock prevents the projection region from axially exiting the cut-out region towards the upper region, and a rotary lock prevents the projection region from rotationally entering the cut-out region and, when assembled, prevents the projection region from rotationally exiting the cut-out region.

Claims

1-16. (canceled)

17. An implant formed as a multi-part connecting device for coupling a fastening element to a connecting element, comprising: a first part formed as a saddle that has a receptacle for a part of the fastening element; a second part formed as a tulip which, in an axially upper region, has a receptacle for the connecting element and, in an axially lower region, surrounds the receptacle of the saddle, wherein, in an assembly state of the saddle already mounted in a predefined orientation in the tulip, the saddle is movable axially in the tulip so that, when moved in a direction of the upper region, said saddle in a receiving position is able to receive the part of the fastening element, and so that, when moved in a direction of the lower region, said saddle in a holding position is no longer able to release the received part of the fastening element; and an axial guide that provides axial mobility comprises a projection region on an outer face of the saddle when viewed radially, which projection region engages in a recess region on an inner face of the tulip when viewed radially, wherein end regions, when viewed azimuthally, of the projection region are spaced apart by at least 18°, and further comprises an axial lock that blocks the projection region against axially exiting the recess region in the direction of the upper region, and a rotary lock that prevents the projection region from rotationally entering the recess region and, in the assembly state, prevents the projection region from rotationally exiting the recess region.

18. The implant according to claim 17, wherein the end regions of the projection region are spaced apart by at least 24°.

19. The implant according to claim 17, comprising two of the axial guides arranged with a 180° offset.

20. The implant according to claim 19, in which the tulip has, in the upper region, two azimuthally spaced side walls, between which the receptacle for the connecting element lies.

21. The implant according to claim 20, wherein the inner face of the side walls that serves for screwing in a locking screw by which an axial force is exerted on the saddle via the connecting element.

22. The implant according to claim 20, wherein the saddle, at a side directed away from the receptacle, has two walls arranged in a predefined orientation corresponding to the side walls of the tulip, each wall carrying a projection region of a respective one of the axial guides.

23. The implant according to claim 22, wherein the walls of the saddle have an elastic resilience against radially inwardly directed bending, which allows the saddle to enter the tulip axially, when the assembly state is produced, by overcoming the axial lock.

24. The implant according to claim 21, wherein the thread on at least one of the side walls has a notch that facilitates axial entry of the saddle into the tulip.

25. The implant according to claim 17, wherein the azimuthal end regions of at least one of the projection regions are spaced apart by at least 30°.

26. The implant according to claim 25, wherein the azimuthal end regions of at least one of the projection regions are spaced apart by at least at least 36°.

27. The implant according to claim 26, wherein the azimuthal end regions of at least one of the projection regions are spaced apart by at least at least 42°.

28. The implant according to claim 19, wherein the recess regions, when viewed in section orthogonal to and axial direction, have a shape that complements a shape of the projection region.

29. The implant according to claim 28, wherein at least one of the projection regions, when viewed in section orthogonal to the axial direction, is continuous and formed as a crescent-shaped projection.

30. The implant according to claim 29, wherein at least one of the projection regions, when viewed in axial section, forms a substantially rectangular step in an upward direction and/or a reflex step in a downward direction.

31. The implant according to claim 22, wherein the walls of the saddle have an inner face with a thread that serves for coupling an elongate instrument, which instrument serves to release the fastening element by axially holding the saddle in the receiving position when part of the fastening element is received in the receptacle of the saddle.

32. The implant according to claim 17, wherein the receptacle of the saddle is configured to hold a head of a pedicle screw.

33. The implant according to claim 32, wherein the receptacle of the saddle is configured to hold the head of the pedicle screw by elastic clipping.

34. The implant according to claim 33, wherein the receptacle of the saddle is configured to engage beyond a region of a maximum diameter of the head of the pedicle screw.

35. The implant according to claim 21, further comprising a locking screw having a thread that matches the thread of the side walls.

36. An implant set, comprising: at least one connecting rod; at least two pedicle screws; and at least two implants according to claim 17 in the assembly state, wherein heads of the pedicle screws are insertable into the tulip through an opening at the end of the lower region of the tulip and are receivable by the receptacle of the saddle.

37. The implant according to claim 36, further comprising an instrument having a thread matching a thread of walls of the saddle, for holding the saddle relative to the tulip in the receiving position.

Description

[0026] Further features, details and advantages of the invention will become clear from the following description of the invention with reference to the accompanying figures, of which

[0027] FIG. 1 shows a saddle within a tulip, in a different view in different regions,

[0028] FIG. 2 shows a sectional view of a lower region of the arrangement from FIG. 1, with a held pedicle screw,

[0029] FIG. 3 is a view of the shape of projection regions of the saddle in an azimuthal plane,

[0030] FIG. 4 shows a notch in a thread portion,

[0031] FIG. 5 shows intermediate stages of axial assembly, in a perspective view, in a front view and in axial section, and

[0032] FIG. 6 shows a different configuration of projection regions than the one shown in FIG. 3.

[0033] FIG. 1 is a schematic representation of the basic structure of a part of a connecting device that is to be implanted, namely a combination of a tulip 1 and a saddle 2 arranged in the tulip 1. In the illustration in FIG. 1, the right-hand half of the picture shows a front view, while the left-hand half of the picture is divided further into an elevation view, in the right-hand region to the left of the axial axis X of the connecting device, and a sectional view on the far left of the picture.

[0034] With respect to the axial axis X, the tulip 1 forms a sleeve-shaped part with an upper end 11 and a lower end 12. Starting from the upper end 11, a U-shaped recess in the part of the sleeve wall facing toward the viewer and in the part facing away from the viewer forms a channel with a course direction Y perpendicular to the plane of the paper in FIG. 1. As can be seen clearly from FIG. 1 and FIG. 5a, the side walls 18L, 18R arranged laterally on both sides of the U-shaped recess (when viewed transversely to the course direction Y of the channel) comprise the recess region 14 of the axial guide. A connecting rod (not shown in FIG. 1) can be placed through this channel, which connecting rod, in a manner known to a person skilled in the art, connects a plurality of connecting devices of the type shown, which in turn are coupled to pedicle screws (likewise not shown in FIG. 1). The connecting rod can be inserted laterally (in the Y direction) or also from above along the axial direction X. The rod is fixed to the connecting device via a clamping screw (not shown), such as a grub screw, which is screwed into the inner thread 13 formed in the upper region of the tulip 1.

[0035] In its upper region, the saddle 2 likewise has a U-shaped recess which forms a channel which, in the position shown in FIG. 1 and intended for use, runs parallel to the channel of the tulip 1.

[0036] In the assembly position ready for use, as shown in FIG. 1, the saddle 2 is axially movable in the tulip 1 with an axial guide. For this purpose, a recess 14 is formed in the side walls 18L, 18R remaining in the upper region on account of the U-shaped cutout of the tulip 1, approximately halfway up the tulip 1, which recess 14 is limited in the downward axial direction by a shoulder 15 and in the upward axial direction by a shoulder 16. A projection 24 is guided in the recess 14, which projection 24 is arranged in the upper region of the saddle 2, on what is the outer face of the upper saddle wall 28L when viewed radially. It will be seen that the saddle 2, starting from its position relative to the tulip 1 as shown in FIG. 1, is axially upwardly movable relative to said tulip 1 until the upper end 26 of the projection 24 abuts the shoulder 16. In this way, an axial lock is provided which prevents further movement of the saddle 2 in the tulip 1 in the direction of the upper end 11 of the latter. The same axial guide is located on the right-hand side on the second wall 18R.

[0037] In its lower region, the saddle 2 is formed in the shape of a cup-like receptacle with holding portions 22 that are separated from one another by gaps 21. The cup-like receptacle can receive the head 32 of a pedicle screw 3 (FIG. 2). If, for example, a pedicle screw 3 has already been screwed into a vertebra, the tulip 1 with the saddle 2 lying therein can be pushed onto the screw head 32. As this is being done, the saddle 2 firstly moves upward in the tulip 1. As soon as the saddle 2 with its maximum radial dimension in the lower region reaches the region (indicated by the dashed line ZM) in which the tulip 1 has an inner curvature giving a larger internal diameter than at the lower end 12, the holding portions 22 can bend radially outward with elasticity, receive the screw head 32 in the manner of a clip and, with the screw head 32 received, can engage over the latter beyond a region of maximum diameter of the screw head.

[0038] In this position known to a person skilled in the art, the orientation of the screw axis with respect to the axial axis X can, starting from a parallel position, be pivoted in each spatial direction at any rate by a certain angle (polyaxial coupling before the rigid securing between pedicle screw 3 and connecting device).

[0039] According to a mechanism likewise known from the art, the ultimately desired rigid coupling between the connecting device, composed of tulip 1 and saddle 2, and the pedicle screw 3 is achieved by the fact that the clamping screw screwed into the thread 13 presses the saddle 2 in the tulip 1 downward via the connecting rod until, on account of the in particular conical narrowing of the opening of the tulip 1 in the lower region toward the lower end 12, the holding portions 22 are forced radially inward and hold the screw more and more firmly until the rigid coupling (conical clamping) is obtained, which is achieved by screwing the screw (not shown) tightly into the thread 13. It will be appreciated that, when the screw is only slightly tightened and not yet fully tightened, a situation that is favorable for the implanting surgeon is achieved, in the sense that the surgeon can still modify the relative position between screw and tulip 1, by targeted use of force, while an unintentional change of position no longer occurs.

[0040] As can be seen better in the top left view in FIG. 5 in column a), the recess 14 is likewise limited in the azimuthal direction (direction of rotation in the Y-Z plane) and does not open toward the U-shaped incision between the side walls 18L and 18R. Accordingly, as can be seen in FIG. 5c and FIG. 1, the projection region 24 of the saddle 2 is received in the recess 14 in the respective side wall 18L, 18R. The rotary lock thus formed prevents rotation of the saddle 2 in the tulip 1 with axial axis X as rotation axis from the relative position shown in FIG. 1. Conversely, from a position rotated by 90° about the axial axis X in relation to the position shown in FIG. 1, the saddle 2 could also not be brought to the position shown in FIG. 1, since the rotary lock acts in both directions with respect to the azimuthal direction. The insertion of the saddle 2 into the tulip 1 cannot therefore take place via the rotation movement as in the prior art. Instead, it takes place from above along the axial axis X, as can be seen from FIG. 5a.

[0041] The production of this operational state shown in FIG. 1, that is to say the assembly of the components saddle 2 and tulip 1, takes place purely on an axial path, as is shown in FIG. 5. FIG. 5 shows in three types of representation, from top to bottom in a perspective view, a front view and a sectional view, intermediate stages of such an assembly procedure. The left-hand illustration of FIG. 5a) shows how the saddle 2 is arranged above tulip 1 coaxially with respect to the common axial axis X, with aligned channels formed by the respective U-shaped cutouts. Starting from this position, the saddle 2 is axially inserted into the tulip 1 through the opening on the upper face 11 of the tulip 1, initially in a manner substantially free of force and deformation, until the state shown in the middle column in FIG. 5b) is reached. For this purpose, in the illustrative embodiment shown, a cutout 13A is provided in the thread ribs of the thread 13. Furthermore, in this illustrative embodiment, the dimensional relationships in the radial direction are such that the projections 24 also at least partially utilize the space that is formed by the cutouts 13A during the axial insertion, in other words the axial insertion would be more difficult without the cutouts 13A. The cutout 13A is shown in FIG. 4 in a detail of a cross section taken at the level of a thread rib of the thread 13.

[0042] Starting from the position shown in FIG. 5b), further insertion with minimal force is no longer possible on account of the axial lock 16, 26 described above. However, by insertion then carried out by force, the walls 18L, 18R are forced radially inward with elasticity, until the resistance is overcome and the projection 24 can enter the recess 14 at the level of the shoulder 26 with elastic recovery of the walls 18L, 18R. The assembly position shown in FIG. 5c) is then reached, which corresponds substantially to FIG. 1.

[0043] In this illustrative embodiment (FIG. 3), the azimuthal extent of the projections 24L, 24R is approximately 50°. Irrespective of the exact shape of the projection 24, in particular in a central region between its end regions, it is preferred that the azimuthal end regions of the projection region have an azimuthal distance in the above-described ranges, in order to achieve an as far as possible positionally stable guidance of the axial guide. For this purpose, the projection region could in terms of material accumulation also be shifted more to the azimuthal end regions, with, for example as shown in FIG. 6, more weight at the end regions 24′a, b, c, d than centrally 24′m.

[0044] As can be seen in the axial section in the enlarged bottom view in FIG. 5b), the lower surface 27 of the projection 24 and the upwardly facing surface 17 of the shoulder 16 are not designed orthogonally to the axial direction X, but instead conically, in order to make it easier to overcome the axial lock when producing the assembly state. Viewed in axial section, the projection 24 can thus have a step shape in terms of its basic shape, with a substantially 90° step for the upper surface 26 and an inclined gradation to the lower surface 27 (with reflex angle).

[0045] When viewed in cross section, a crescent-shaped configuration (FIG. 3) of the projection regions is preferred. Other configurations are conceivable (e.g. FIG. 6), wherein, as has been explained above, compliance with a minimum azimuthal distance is provided.

[0046] As will be clear from the above, the invention is not limited to the embodiments described with reference to the figures. Rather, the individual features of the description and also those of the attached claims are essential to the realization of the invention in its various embodiments.