DE4109941A1 - Flexible prosthesis for backbone - comprises flexible spring forming supporting element connected to two fixing elements attached to adjacent vertebrae - Google Patents

Abstract

An endoprosthesis for a backbone comprises at least one flexible supporting member (14) attached to two fixing members, which are themselves attached to adjacent vertebrae of the backbone. Each supporting member is formed by a coil spring (14). In one of several forms of the prosthesis a protective cover (70) around the spring coils (14) prevents entry by nerve fibres when the coils open during bending of the spring (14). The protective cover is formed by a 'Teflon' (RTM) ring (70). USE/ADVANTAGE - The prosthesis forms part of the backbone, is reliable in operation and maintains the relative movement of adjacent vertebrae.

Description

The invention relates to an endoprosthesis for vertebrae.

Spinal injuries, as well as pathological changes changes, in particular degenerative changes in the Spine, are so far only very limited delbar. So for several decades at surgical treatment of bone fractures (Osteosynthesis) special plates are used, which are attached to a or several vertebrae fastened with screws that are in the vertebral body either by behind (transpenducular) or from the front from the side are screwed into the corresponding vertebral body. These plates lead to immobilization of the ent speaking vortex. You also have one in many cases Loosen the connection between the plate and the body mainly due to screw breakage. Younger Transpenducular fixators are used at which also breaks, especially the transpenducular "pins" at the exit from the bone. A Known procedure for decompression of the nerve sausage intervertebral forms exists in the operative stiffening of certain spinal segments by obliteration of the small vertebral joints, more autoplastic Chip attachment to the spinous processes and filling the Interstices with cancellous bone (spinal fusion).

The disadvantage of all these known procedures is common that the affected vertebrae at least temporarily are immobilized, which corresponds to the Gypsum immobilization after bone fractures is known to be disadvantageous is. Finally, in the known fixators Possibility of loosening the connection with the vertebra, especially due to screw breakage, especially Disadvantage.

The invention has for its object a Provide endoprosthesis for dorsal vertebrae at reliable function the mobility of neighboring Vortexes relative to each other, at least for the most part maintains.

This problem is solved by at least on all sides bendable support element, which with two fastening elements is provided for anchoring to one of the two opposing body articular surfaces consecutive vertebrae.

The support element according to the invention thus extends successive between the articular surfaces Dorsal vertebrae so that the axially (i.e. towards the Forces along the longitudinal axis of the spine) bar from one vertebral body to the following vertebral body with essentially vertical introduction of force into the respective joint surface are transferred. Bending moments therefore do not occur at least in the first approximation, so that the attachment of the fasteners to the respective Body is unproblematic. Because of the all-round The flexibility of the support element is the mobility successive vertebrae guaranteed.

In a particularly preferred embodiment, the Endoprosthesis made of two flexible support elements with a middle connecting both support elements Fastening element and one end fastening element ment on the opposite ends of the support ele ment. The one to attach to the middle fastener Vortex is therefore the closest to each other on both sides following vertebrae from the respective support element. In addition, the middle fastener attached vertebrae or vertebral part entirely by force relieved that between the two following on both sides Eddies work due to the forceful connection of these  two vertebrae over the end fasteners that two support elements and the middle fastener.

The middle support element could match the associated vertebral Grasp the body like a clamp; this is particularly preferred middle support element for crossing a vertebrae pus trained, what simple design and largely axial power flow guaranteed.

In the event that the middle vertebral body due to No more fractures or signs of degeneration is complete, it is envisaged that the middle befe Stigungselement for attaching a vertebral arch out forms is.

It is preferably provided here that the middle befe Stigungselement with at least one, preferably two, Recesses for receiving fastening elements, especially screws, for fastening the vertebral arch is formed, wherein the at least one recess as Elongated hole can be designed to adjust the height to be able to make.

To ensure a reliable attachment of the respective end piece on the associated vertebral body with increased security ensure it is suggested that the end fasteners tion elements as insert parts for insertion in a complementary recess in the respective body joint surfaces are formed.

To reduce the pressure load on the vertebral body, it is proposed that the middle fastener and / or the end fasteners with a radial protruding outwards on the respective body joint Collar are formed surface.  

It can preferably be provided that the collar with Recesses is provided to accommodate fasteners elements, especially screws, for fastening the Collar on the body. These screws are not under the Load the spine in the section in question has to be recorded so that there is no risk of breakage.

To hold the respective fastener in the we to improve the bel body even further, it is proposed that at least one of the support elements with circumferential grooves is provided.

In a development of the invention it is provided that the support element can be twisted at least to a limited extent. On this measure is due to full normal mobility guaranteed between successive vertebrae.

As a support element with a particularly simple structure, the is bendable on all sides and, if necessary, is twistable to a limited extent, a spiral spring is provided beat.

From a certain free length of this coil spring and at high forces occurring between successive There may be a risk of whirling that Spiral spring ends ver laterally relative to each other push. To rule this out from the outset, suggested that in the coil spring two rigid cores are used, which are like a ball joint support, with one core on one of the two through the support element interconnected fastening elements elements and the other core on the other fastening supply element is attached. The two nuclei stabilize the coil spring by moving this side shift Exercise or unwanted bulges of the coil spring exclude. The desired mobility remains due the ball joint-like support. Is preferred a joint ball is provided for this.  

In a development of the invention it is proposed that the Coil spring in the area between the two support elements is provided with an anti-trap device to prevent it from being bent Support element an intrusion of nerve fibers or the are the same between windings spread apart from one another Exclude coil spring.

This pinch protection could, for example, by a Spiral spring surrounding hose can be formed. Especially however, it is preferably provided that the pinch protection one of the spiral springs, preferably in the area of Joint ball, encompassing ring is formed. That ring serves as a repelling ring for the nerve fibers or the like Chen and can in its outline the outline of the body Ge steering surfaces correspond essentially. The ring prevents This generally prevents nerve damage from occurring sern or the like in the area of the endoprosthesis between the two successive body joints surfaces.

The ring is preferably a Teflon ring because it is is physiologically compatible.

For the mechanically stable connection of the coil spring with the respective fastener is proposed that the End fastening elements are pot-shaped Screw-in internal thread for the spiral spring of the respective Support element and that the middle fastener from two interconnectable, cylindrical half-shells is formed, which is common to both axial ends a receiving opening with screw-in internal thread for the form the respective coil spring.

The invention is in the following preferred Ausfüh Rungsbeispiele explained using the drawing. It shows:

Figure 1 is a side view of a first embodiment of the endoprosthesis for Rückwir bel.

Fig. 2 is a sectional view of the arrangement in Figure 1 along line II-II.

Fig. 3 is a side view of a second embodiment;

FIG. 4 shows a section of the arrangement in FIG. 3 along line IV-IV;

Fig. 5 is a sectional view of another embodiment;

Fig. 6 is a side view of a final embodiment;

Fig. 7 is a section along line VII-VII of the arrangement in Figure 6 in the implanted state.

Fig. 8 shows a section of the arrangement in Fig. 6 along line VIII-VIII also in the implanted state and

Fig. 9 is a side view of the arrangement according to FIG. 1 and 2 in the implanted state.

The endoprosthesis for back vertebrae according to the invention is before especially for installation in dynamic vertebral segments determined, i.e. in vertebrae with a certain degree of mobility relative to each other, because here the special advantages of Invention, namely the extensive imitation of the movement of the corresponding vertebral segment to bear come. The simple structure and the hassle-free Force transmission in the endoprosthesis according to the invention However, they also come into play when the Endoprosthesis according to the invention in nature only a little  movable or immobile vertebral segments used becomes.

An essential part of the invention is a supporting element which supports two successive vertebrae against one another and which can be bent on all sides in order to emulate the corresponding vertebral mobility. In the preferred embodiments shown, this support element is formed by a spiral spring 14 , which is supported on corresponding fastening elements on both ends. With the help of a single support element, two successive vertebrae can be mutually supported in this way. With the help of several support elements, each of which is connected to one another via common fastening elements, a corresponding number of vertebrae can be coupled to one another. In most cases, however, it is sufficient if a single defective vertebra is relieved, which is possible with the endoprostheses shown in the figures, each having two support elements 12 .

The endoprosthesis for three successive vertebrae shown in simplified form in FIGS. 1 and 2 is generally designated 10 . It consists of an upper and lower end fastening element 16 , a middle fastening element 18 and the already mentioned support elements 12 , each of which one of the two end fastening elements 16 connect to the middle fastening element 18 .

The two end fastening elements 16 are approximately pot-shaped, with circumferential grooves 20 on the cylindrical outer circumference to reinforce cohesion with the vertebral body (see also FIG. 9), a radially outwardly projecting, approximately oval collar 22 with three holes 24 for fastening screws 26 (see FIG. 7) and a screw-in internal thread 28 in the pot opening 31 for the corresponding end of the spiral spring 14 .

The middle fastening element 18 is formed by two mitein other about four screws (screw holes 30 in Fig. 1) interconnectable cylindrical half-shells 32 . After screwing them together, they form a receptacle opening 34 with screw-in internal thread 36 for the respective spiral spring at both axial ends.

Fig. 9 shows a rough schematic of the installation situation. It can be seen that the upper fastening element 16 is inserted from below into a corresponding receiving opening 38 in the vertebral body 40 of an upper vertebra 42 . This opening 38 opens into the lower body articular surface 44 , on which the corresponding intervertebral disc is normally arranged. The collar 22 rests on this surface 44 and is also BEFE Stigt with the help of screws 26 on the body 40 .

The middle support element 18 passes through the body 46 of the vertebra 44 in FIG. 9, which for this purpose is to be provided with a corresponding axial cylindrical through opening 48 . An axial fixation of the middle fastening element 18 in the body 46 is not necessary per se, since the middle vertebra 44 is completely relieved of forces which act between the vertebrae 42 and 50 on both sides of the middle vertebra 44 . The continuous middle fastening element 18 transmits these forces directly. Under certain circumstances, however, an additional axial fixation can be provided with the aid of a collar 52 corresponding to the collar 22 , as is realized in the embodiments to be described below.

The lower end fastener 16 is installed and fixed in the body 54 from above in the same manner as the upper end fastener 16 in the body 40 .

After insertion of the two coil springs 14 , the endoprosthesis 10 is fully functional. It transmits the vertical forces emanating from the upper vertebra 52 to the lower vertebra 50 with complete relief of the middle vertebra 44 . The three vertebrae can be pivoted relative to one another about an arbitrarily oriented horizontal pivot axis, owing to the fact that the spiral springs 14 oriented parallel to the longitudinal direction of the spine can be bent on all sides. Finally, the spiral springs 14 also allow a limited but sufficient torsional movement of the vertebrae relative to one another about the longitudinal backbone axis 56 .

Due to the direct application of force in the Kor pus-articular surfaces larger loads of fastening elements, for example the screws 26 , are avoided from the outset, so that there is no risk of breakage.

In Figs. 3 and 4 is a second 10 'described embodiment of the endoprosthesis according to the invention illustrated, the fundamentally same construction as that of the embodiment 10 according to Figures 1 and 2. In the following, only the differences are addressed. for the rest, reference is made to the explanations of FIGS. 1 and 2.

In order to exclude a lateral displacement of the support elements 16 and 18 , that is to say transversely to the longitudinal axis 56 of the endoprosthesis, two cylindrical cores are fitted in each of the spiral springs 14 , which are supported on one another in the manner of a ball and socket joint. Thus, 4 seen in FIG. Above an up into the upper end fixing member 16 extending into core 58 as well as a following to this core 60, which extends up into the center fixing member 18 inside. The mutual support takes place here by means of a joint ball 62 , against which the upper core 58 rests with a concave end face 64 designed accordingly in the form of a spherical cap. The lower core 60 also lies against the ball 62 with a concave end face 66 . The upper core 58 is rigidly connected to the upper fastening element 16 , namely in that it is screwed into the spiral spring 14 from above with essentially no play, with a flush end with the upper end of the spiral spring. The upper end of the coil spring is in turn screwed a little into the receiving opening 31 of the upper end piece 16 . To improve the backlash-free cohesion, the core can, as shown, be provided with an external thread 68 adapted to the spiral spring 14 .

Another difference from the first embodiment 10 is that the outer circumference of the two end fastening elements 16 is continuously smooth cylindrical, that is to say does not have any grooves 20 , which facilitates the insertion of the end pieces into the corresponding receiving openings 38 of the vertebrae and, due to the prevailing axial compression force, also in all Usually provides sufficient cohesion between the endoprosthesis and the vertebrae.

Due to the described use of the cores 58 , 60 both in the upper support element 12 and in the lower support element 12 , the mentioned transverse movements are excluded from the outset. The possible all-round pivoting movements necessarily take place around an axis intersecting the center M of the respective joint ball 62 .

FIGS. 5 and 6 show two other 10 '' and 10 '''described embodiments of the invention. The basic structure of these embodiments in turn corresponds to that of the previously described embodiments 10 and 10 ', so that in this respect reference is made to the description of the embodiments 10 and 10 '.

The embodiment 10 '' has the same internal structure as the embodiment 10 ', but additionally uses a Teflon ring 70 , which is pushed onto the respective spiral spring 14 self-locking, at the level of the respective joint ball 62 . The axial length a of the inner circumferential surface 72 lying against the outer circumference of the spiral spring 14 is dimensioned somewhat larger than the clear distance between the mutually facing end surfaces 60 of the cores 58 and 60 involved . In this way, it is reliably prevented that when bending the endoprosthesis 10 'from the stretched position around the respective ball 62 between the inevitably forming on the outside of the bend slight gap between successive spring turns tissue parts, nerve strands or the like can penetrate. In addition, the Teflon ring 70 due to its comparatively large radius r (in the area of the radius of the respective joint surface) ensures that longer fiber strands or the like get into the area between two successive vertebral bodies. This protective effect is independent of whether the ring is exactly at the level of the joint ball 62 or not.

The embodiment 10 '''according to FIG. 6 differs from those described so far by the design of the central support element. While a more or less complete vertebral body is assumed in the embodiments described so far, which is then traversed by the central support element over its entire axial length, it is sufficient in the embodiment 10 '''if the vertebra is still somewhat completely present only on the vertebral arch side. This in Fig. 8 designated 74 remaining vertebral part can namely laterally brought up to the central support element 18 'and rigidly connected to it, in particular screwed. For this purpose, the middle fastening element 18 'is provided on two diametrically opposite sides with radially outwardly projecting webs 76 , in each of which a slot 78 extending parallel to the longitudinal axis 56 is provided for receiving a correspondingly speaking fastening screw 80 ( FIG. 8).

Draw the embodiments described above simple and therefore inexpensive construction, good implantability, high mechanical stability and Reliability as well as natural mobility largely approximated mobility. The The endoprosthesis according to the invention can still be used be used if a vertebra is badly deformed or even only parts including the Vertebral arch are available. By attaching this Parts on the middle fastener ensures that these parts are in the correct location the spine are held, even with usual Movements of the spine, with complete relief of those that normally act between the vertebrae Forces, especially weight, since the endoprosthesis the middle vertebra or the corresponding parts of the vertebra bridged by force.

The middle support element consists of several components composed in the middle vertebra individually introduced and firmly connected there can, which facilitates the surgical installation.

Claims (19)

1. Endoprosthesis for dorsal vertebrae, characterized by at least one support element ( 12 ) which can be bent on all sides and which is provided with two fastening elements ( 16 , 18 ) for anchoring to one of the two opposing body joint surfaces of successive dorsal vertebrae ( 42 , 44 , 50 ) . 2. Endoprosthesis according to claim 1, characterized in that it consists of two bendable support elements ( 12 ) with a two support elements ( 12 ) connecting middle fastening element ( 18 ) and one end fastening element ( 16 ) at the ends facing away from each other Support elements ( 12 ). 3. Endoprosthesis according to claim 2, characterized in that the central support element ( 18 ) is designed to cross a vertebral body ( 46 ). 4, endoprosthesis according to claim 2, characterized in that the central fastening element ( 18 ) is designed for fastening a vertebral arch ( 74 ). 5. Endoprosthesis according to claim 4, characterized in that the middle fastening element ( 18 ) is formed with at least one, preferably two, recesses for receiving fastening elements, in particular screws ( 80 ), for fastening the vertebral arch. 6. Endoprosthesis according to claim 3, characterized in that the at least one recess is designed as an elongated hole ( 78 ). 7. Endoprosthesis according to one of the preceding claims, characterized in that the end fastening elements ( 16 ) are designed as insert parts for insertion into a complementary recess ( 38 ) in the respective body articular surface ( 40 ). 8. Endoprosthesis according to one of claims 2-7, characterized in that the central fastening element ( 18 ) and / or the end fastening elements ( 16 ) with a radially outwardly projecting collar ( 44 ) abutting the respective body articular surface ( 44 ) 22 , 52 ) are formed. 9. Endoprosthesis according to claim 8, characterized in that the collar ( 22 , 52 ) is provided with recesses ( 24 ) for receiving fastening elements, in particular screws ( 26 ), for fastening the collar ( 22 , 52 ) to the body. 10. Endoprosthesis according to one of the preceding claims, characterized in that at least one of the fastening elements ( 16 ) which can be used in a vertebral body ( 40 ) is provided with a surface structure, preferably in the form of circumferential grooves ( 20 ). 11. Endoprosthesis according to one of the preceding claims, characterized in that the support element ( 12 ) can be twisted at least to a limited extent. 12. Endoprosthesis according to one of the preceding claims, characterized in that the support element ( 12 ) comprises a spiral spring ( 14 ). 13. Endoprosthesis according to claim 12, characterized in that in the spiral spring ( 14 ) two rigid cores ( 58 , 60 ) are inserted, which are supported on each other like a ball joint, the one core ( 58 ) on one of the two by the support element ( 12 ) interconnected fasteners ( 16 , 18 ) and the other core ( 60 ) is attached to the other fastener ( 18 ). 14. Endoprosthesis according to claim 13, characterized in that a joint ball ( 62 ) is arranged between the two cores ( 58 , 60 ). 15. Endoprosthesis according to any one of claims 12-14, characterized in that the spiral spring ( 14 ) in the region between the two support elements ( 16, 18 ) is provided with an anti-trap device to prevent nerve fibers or the like from spreading apart when the support element is bent Exclude coils of the spiral spring ( 14 ). 16. Endoprosthesis according to claim 15, characterized in that the pinch protection is formed by a coil spring ( 16 ), preferably in the region of the joint ball ( 62 ), encompassing ring. 17. Endoprosthesis according to claim 16, characterized in that the ring is a Teflon ring ( 70 ). 18. Endoprosthesis according to one of claims 12-17, characterized in that the end fastening elements ( 16 ) are cup-shaped with screw-in internal thread ( 28 ) for the spiral spring ( 14 ) of the respective support element ( 12 ). 19. Endoprosthesis according to one of claims 2-18, characterized in that the central fastening element is formed from two interconnectable, cylindrical half-shells ( 32 ), each of which has a receiving opening ( 38 ) with a screw-in internal thread ( 36 ) for both axial ends form the respective coil spring ( 14 ).