TIBIAL COMPONENT

Abstract

A tibial knee joint prosthesis for attachment to a suitably prepared tibial bone, providing bearing portions in the lateral and medial compartments. The lateral and medial bearing surfaces of the component are inclined at different angles in the anterior to posterior direction of the knee, so that when mounted to the tibia, the lateral bearing surface of the prosthesis is higher than the medial bearing surface to the posterior side of the knee. In this way the lateral ligament is tightened progressively more than the medial ligament as the knee moves from extension to flexion, resulting in increased stability in the lateral compartment.

Claims

1. A prosthesis for implantation in the knee joint, said prosthesis comprising: a tibial component having a first, upper surface and a second, lower surface opposite said first surface for attachment to the tibia, said first surface including a lateral bearing region and a medial bearing region, wherein the respective angles of inclination of said lateral and said medial bearing regions of said first surface, with respect to said second surface, are dissimilar

2. A prosthesis according to claim 1 wherein the direction of inclination is between said anterior side and said posterior side.

3. A prosthesis according to claim 1 wherein the angle of inclination of the lateral bearing region is more positive than the angle of inclination of the medial bearing region.

4. A prosthesis according to claim 1 wherein the difference in angle of inclination between the lateral and medial bearing regions is within a range of approximately 2 to 4 degrees.

5. A prosthesis according to claim 1 wherein the height of the lateral bearing region increases from said anterior side to said posterior side.

6. A prosthesis according to claim 1 wherein the lateral bearing region is inclined at a positive angle to the second surface, and said medial bearing region is substantially parallel to said second surface.

7. A prosthesis according to claim 1 wherein the lateral bearing region is substantially parallel to the second surface, and said medial bearing region is inclined at a negative angle to said second surface.

8. A prosthesis according to claim 1 wherein the lateral bearing region is inclined at a positive angle to the second surface, and said medial bearing region is inclined at a lesser positive angle to said second surface.

9. A prosthesis according to claim 1, wherein the lateral and medial bearing regions are formed as flat plane plateaux.

10. A prosthesis according to claim 1, wherein the lateral and medial bearing regions have a convex, part-cylindrical form.

11. A prosthesis according to claim 1, wherein the lateral bearing region has a convex form and the medial bearing region has a flat form.

12. A prosthesis according to claim 1, wherein the lateral bearing region has a flat form and the medial bearing region has a concave form.

13. A prosthesis according to claim 1, wherein the lateral bearing region has a convex form and the medial bearing region has a concave form.

14. A prosthesis according to claim 1 wherein the angles of inclination of said lateral and said medial bearing regions are chosen such that, when attached to the tibia, the lateral bearing region is inclined downwards to the horizontal at a lesser angle than the medial bearing region, in an antero-posterior direction.

15. A method of implanting a prosthesis according to any of the previous claims comprising sawing the medial and lateral compartments of the tibial bone condyles and attaching the prosthesis to the prepared surface of the tibial bone, wherein the angle of the saw cut is chosen such that the posterior side of the lateral bearing region sits higher on the tibia than the posterior side of the medial bearing region.

16. A prosthesis for implantation in the knee, said prosthesis comprising: a tibial component for attachment to the tibia, having a first, upper surface and a second, lower surface opposite said first surface for attachment to the tibia, said first surface including a lateral bearing region and a medial bearing region, arranged such that the respective angles of inclination in sagittal planes of said lateral and said medial bearing regions of the component in situ when fitted to the tibia are different.

17. A prosthesis according to claim 16, wherein the lateral and medial bearing regions in situ are inclined downward to the horizontal from the anterior to the posterior side, the angle of downward inclination of said lateral bearing region to the horizontal being less than the angle of downward inclination of said medial bearing region, such that the posterior of the lateral bearing region is higher than the posterior of the medial bearing region.

18. A prosthesis comprising a tibial component having lateral and medial portions of differing height, wherein the difference in height of the lateral and medial portions increases posteriorly, such as to progressively tighten the lateral ligament more than the medial ligament as the joint moves from extension to flexion.

19. A prosthesis according to claim 16 further comprising an intermediate meniscal bearing component and a femoral component for attachment to the femur.

20. A tibial component having lateral and medial bearing portions and dimensioned such that a difference in the respective thicknesses of the lateral bearing portion and the medial bearing portion increases in an anterior to posterior direction.

21. A tibial component having lateral and medial bearing portions, wherein the thickness of at least one bearing portion changes progressively from the anterior side to the posterior side.

22. A tibial component according to claim 21, wherein the cross-sectional area of the lateral bearing portion in a sagittal plane that bisects the lateral bearing portion is greater than the cross-sectional area of the medial bearing portion in a corresponding sagittal plane.

23. A tibial component according to claim 21, wherein the change in thickness of the lateral and medial bearing portions in the anterior to posterior direction is described by the following expression:
t.sub.lat(p)t.sub.lat(a)>t.sub.med(p)t.sub.med(a) Where t.sub.lat(p) is the thickness of the lateral bearing portion to the posterior side, t.sub.lat(a) is the thickness of the lateral bearing portion to the anterior side, t.sub.med(p) is the thickness of the medial bearing portion to the posterior side and t.sub.med(a) is the thickness of the medial bearing portion to the anterior side.

24. A tibial component having a lateral and a medial bearing portion comprising means for tensioning the lateral ligaments progressively more than the medial ligament.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] To better illustrate the invention, it will now be described, by way of example, with reference to the accompanying drawings, in which:

[0022] FIGS. 1A, 1B and 1C illustrate a prior art tibial tray component in plan (1aA), side (1B) and posterior (1C) views.

[0023] FIGS. 2A, 2B and 2C depict plan, side and posterior views of a tibial component according to a first embodiment of the invention, for incorporation in a right-hand joint.

[0024] FIGS. 3A, 3B, and 3C depict plan, side and posterior views of a tibial component according to a first embodiment of the invention, for incorporation in a left-hand joint.

[0025] FIGS. 4A, 4B, 4C and 4D depict plan, side and posterior views of a tibial component according to a second embodiment of the invention, for incorporation in a right-hand joint.

[0026] FIG. 5 shows a side view of a tibial component according to a variant of the second embodiment, for incorporation in a right-hand joint.

[0027] FIG. 6 shows a side view of a tibial component according to an alternative variant of the second embodiment, for incorporation in a right-hand joint.

[0028] FIG. 7 shows a perspective view of a left-hand total knee prosthesis, incorporating a tibial component according to the second embodiment of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0029] The invention will be described in terms conventionally used to describe the geometry of the knee. The knee has an anterior side (A) and posterior side (P), and is divided laterally along sagittal planes (S) extending between the anterior and posterior sides. A central sagittal plane divides the knee into medial and lateral compartments.

[0030] The tibia has a vertical, major axis T.sub.M along its length, and a horizontal plane TN defined normal to its major axis. In the figures, (A) denotes the anterior side of the tibial component, (P) denotes the posterior side, (M) denotes the medial side, (L) denotes the lateral side, (S) denotes a sagittal plane, T.sub.M denotes the vertical axis of the tibia, and TN the horizontal plane of the tibia.

[0031] Referring to FIG. 1, the prior art tibial component 10 comprises a generally flat tray, shaped to correspond to the cross-sectional shape of the top of a typically prepared tibial bone, having an anterior side (A), a posterior side (P), and medial and lateral sides (M) and (L). S.sub.L and S.sub.M designate typical sagittal planes, in this case bisecting the lateral and medial bearing portions. The component has a first, upper, major surface 11, which acts as a bearing articulation surface, and a second, lower, major surface 12, opposite the first surface, for attachment to the tibia. A central cutout 13, open at the posterior side (P) of the component, is provided to allow the tray to be slid into position onto a suitably prepared tibia, without being hindered by the presence of the cruciate ligaments. To either side of the central cutout are defined lateral and medial bearing portions having flat meniscal bearing regions 14, 15 parallel to the lower surface 12. The thickness of the component (height of upper surface relative to lower surface) is constant across both bearing regions.

[0032] The tibia is typically prepared by sawing the top of the tibia in each compartment at an angle of 7.5 sloping downwards from the horizontal, relative to the front of the tibia. A saw guide is pinned to the exposed bone of the proximal tibia and rests on a shoe around the ankle at the distal end. The slope of the guiding surface is set at an angle of 7.5 to this guide. This guide is used to remove a sliver of bone from the top of the tibia. The tibial component is then attached to the prepared end of the tibia oriented with its cutout facing posteriorly.

[0033] With this arrangement, since the surfaces of the lateral and medial bearing regions are parallel to one another, the lateral collateral ligament is insufficiently constrained. A prosthesis with this arrangement will have a tendency to dislocate or lift off.

[0034] The inventors have established by 3d digitisation and modelling of the healthy knee joint that the articulating surfaces of the medial and lateral condyles of the tibia are not parallel. The medial tibial condyle of the healthy knee joint is slightly concave while the lateral condyle is slightly convex. Study of the digitised shapes of cadaver specimens has enabled the positions of planar surfaces which best fit the two condyles to be determined. A representative analysis of knee joints shows that on average, in the sagittal plane, the angle of posterior inclination (i.e. in an anterior to posterior direction) of the best-fit plane to the medial tibial condyle relative to the normal axis of the tibia is around 2 degrees greater than the angle of posterior inclination for the lateral tibial condyle, in other words, the upper surface of the medial condyle of the tibia slopes downward from front to back at an angle on average 2 degrees greater than the upper surface of the lateral condyle.

[0035] Basing their ideas on this realisation, the inventors have developed an improved prosthetic component, which takes into account the difference in posterior inclination between the lateral and medial condyles.

[0036] FIGS. 2 and 3 illustrate right and left versions of a bicompartmental tibial tray component 20 in accordance with a first embodiment of the invention, similar to the conventional tibial tray component illustrated in FIG. 1. The component also has a first, upper, major surface 21, which acts as a bearing articulation surface, and a second, lower, major surface 22, opposite the first surface, for attachment to the tibia (not shown). By adjusting the angle of inclination in the sagittal plane of the lateral and medial bearing regions (24,25) to be different, the behaviour of the prosthetic knee joint can be arranged to reduce the likelihood of dislocation in the lateral compartment.

[0037] FIGS. 2 and 3 show the plateaux (24, 25) as flat surfaces inclined to each other. In surgery, a single saw guide is used to saw the surfaces of the lateral and medial compartments of the tibia parallel to each other, preferably at an angle of approximately 7.5 to the horizontal plane, normal to the major axis of the tibia. The articulating bearing surface of the component in the medial compartment is inclined at an angle =0 i.e. is parallel to its under surface, so will also be inclined at an angle of 7.5, when mounted to the prepared tibia. The articulating bearing surface in the lateral compartment of the component is inclined at an angle , in the region of 3.5 to its lower surface, the component increasing in thickness in the antero-posterior direction. Thus when the component is mounted to the prepared tibia sawn at 7.5 to the horizontal it will provide a lateral bearing surface inclined at the lesser angle of 4 to the horizontal plane, and consequently the height difference between the medial and lateral bearing surfaces increases posteriorly. This will tend to keep the fibres of the lateral collateral ligament tighter than physiological as the joint flexes and the femoral condyles move backwards, increasing the contribution of the LCL to resisting bearing dislocation or lateral lift-off.

[0038] Although the relative inclination in the sagittal plane of the two bearing surfaces with the component in situ will most probably be in the region of 2 to 4 degrees, the essential element is an appropriate difference in slope between the bearing surfaces of the two compartments when the component is in situ, such that the height of the bearing surface on the lateral side reduces progressively at a lesser rate in the posterior direction than the height reduces on the medial side.

[0039] In FIGS. 2 and 3, the two plateaux are shown at the same level anteriorly and therefore at different levels posteriorly. The invention encompasses designs in which the lateral and medial bearing surfaces are at different levels both anteriorly and posteriorly; it may be appropriate to arrange the component such that both lateral and medial bearing regions are inclined relative to the lower surface of the component, but at different angles, as will be discussed later in this specification.

[0040] It may be appropriate to provide the tibial component with a raised side wall or flange at one side of the intercondylar cutout, as indicated at 26 in FIG. 2, in order to limit the extent of relative lateral/medial movement of the joint and to prevent contact between the meniscal bearings or femoral condyles and the exposed cut tibial bone.

[0041] FIG. 4 (a) to (c) shows a second embodiment of the invention incorporating a component (20) for a profiled meniscal bearing to provide added stability. In this embodiment, by making the bearing surfaces of convex, curved form, the resistance to dislocation can be further enhanced. The tibial plateaux are inclined to each other in the sagittal plane as in FIG. 2, such that, in situ, a plane fitted to the surface of the bearing region in the lateral compartment (24) will be inclined at a lesser angle to the horizontal than in the medial compartment (25). The curved bearing regions (24, 25) shown are defined by convex surfaces of part-cylindrical shape. The surfaces can also be defined by convex surfaces of part-spherical shape. As shown in FIG. 4 (d), if only one compartment is provided with a curved surface, advantageously, less bone removal may be required. The medial bearing region can be flat, with the lateral bearing region convex as shown in FIG. 4 (d), or alternatively, the lateral bearing region can be flat and the medial bearing region concave. It is also envisaged that bearing surfaces could be formed to more closely approximate the physiological tibial condyles, with the lateral bearing region having a convex form, and the medial bearing region having a concave form. Further improvements to stability may be provided by differentially inclining the surfaces in the frontal plane, such that each bearing region slopes downwards from the centre of the knee towards the exterior of the knee.

[0042] The radius of curvature of the cylindrical bearing surface is a function of the size of the prosthesis, and will increase for components destined for a larger knee. However, it is important that the radius be kept within limits, to keep the overall thickness of the tibial component as thin as possible, thus minimising the amount of tibial bone that has to be removed to accommodate the component.

[0043] It is to be appreciated that the actual angles of the articulating bearing surfaces of the tibial component are dependent on the angle of the saw cut in the tibia. A cut angle of 7.5 posterior tilt has been found to be ideal, especially where the femoral component is formed with spherical condyles, allowing the creation of equal flexion and extension gaps. However, the tibial bone could be sawn at other angles, provided that the relative change in thickness of the component in the posterior direction was greater in the lateral compartment than in the medial compartment, with the angles of inclination of the upper surfaces of the component correspondingly selected to achieve the desired differential inclination, when the component is in situ on the tibia. FIG. 5 illustrates a possible variant to the first embodiment. The bearing regions have different slopes but are inclined in the same direction, with the lateral bearing region inclined at 5 to the lower surface and the medial bearing region inclined at a lesser angle of 2. Provided the tibial saw cut is made at an increased angle of 9 the resulting position of the lateral and medial bearing regions in situ on the tibia will be the same as for the first embodiment. It is to be appreciated that with a reduced angle of cut, in order to produce the necessary differential inclination, the component could even have a lateral bearing portion where the upper and lower surfaces were parallel, and a medial bearing portion where the upper surface was inclined in an anterior direction, as illustrated in FIG. 6, where lateral and medial bearing regions have angles of inclination , of 0 and 3 (a negative angle indicating that the bearing region slopes toward the lower surface from the anterior side to the posterior sideas opposed to a positive angle where the bearing region slopes away from the lower surface from the anterior to the posterior side). In this case, a reduced angle of cut of 4 would be necessary to achieve the same overall differential inclination as in the first embodiment. It would also be possible to saw the tibial condyles at different angles, with the lateral compartment inclined at a lesser angle than the medial one, although this would necessitate a more complicated sawing arrangement. In this case a component with parallel medial and lateral plateaux could be employed, having a deformable central section, such that the lower surface of the component could conform to the differentially inclined tibial compartments, once affixed to the tibia. Where appropriate, separate lateral and medial bearing components could be employed.

[0044] FIG. 7 shows a complete left-hand 4-part knee prosthesis incorporating the tibial component of the second embodiment. The lateral (24) and medial (25) bearing regions of the tibial component are intended to co-operate in use with the lower bearing surfaces of the intermediate meniscal bearings (30,31). The upper bearing surfaces of the meniscal bearings cooperate in use with the bearing surfaces of a corresponding femoral component (40). As the joint moves from extension to flexion, the femoral component and meniscal bearings will move backwards on the bearing surfaces of the tibial component. Due to the differential inclination of the lateral and medial bearing surfaces, the lateral ligament will be progressively tightened, providing increasing resistance to dislocation as the knee is flexed.

[0045] Whilst FIGS. 1 to 6 do not show the means for fixing the tibial component to the bone, it is to be appreciated that this could be achieved in a number of ways. For example, a pin or pins could be applied centrally at the anterior side of the prosthesis, sloping downwards and backwards into the bone. Alternatively, pins or spikes could be applied laterally, as shown at (50) in FIG. 7. Such pins could either be formed as an integral part of the prosthesis, or as separate elements. Slots may be prepared in the tibia to accept the fixing means.

[0046] The component may be formed of any suitable surgically acceptable material, such as cobalt chrome vanadium, alumina or zirconia ceramic, or plastic, such as ultra-high molecular weight polyethylene (UHMWPE). Whilst the component described in the above embodiments is of unitary construction it is to be appreciated that it could also be constructed with separate lateral and medial bearing portions secured to one side of a tray element, with the other side of the tray element for attachment to the end of the tibia. Although the above embodiments have generally been described in the context of 3 component total knee prostheses, it is to be appreciated that the invention may also be applied with two component arrangements, where the femoral and tibial components bear directly against one another. In such arrangements, having a lateral tibial plateau which is higher posteriorly could prove particularly useful in reducing any problems of lift-off in extension of the joint. The tibial component in such arrangements may be formed from separate elements, as mentioned above, with bearing portions of a suitable material (e.g. UHMWPE) attached to a metal tray element. The differential inclination may be provided by adapting the tray or the individual bearing portions.