Source: https://patents.google.com/patent/ES2364047T3/en
Timestamp: 2019-12-14 03:02:37
Document Index: 44203535

Matched Legal Cases: ['art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 3', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 15', 'art 15', 'art 15', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'art 5', 'arts 5', 'art 5', 'art 5', 'art 5', 'art 16']

ES2364047T3 - Glenoid anchor. - Google Patents
Glenoid anchor. Download PDF
ES2364047T3
ES2364047T3 ES04011960T ES04011960T ES2364047T3 ES 2364047 T3 ES2364047 T3 ES 2364047T3 ES 04011960 T ES04011960 T ES 04011960T ES 04011960 T ES04011960 T ES 04011960T ES 2364047 T3 ES2364047 T3 ES 2364047T3
ES04011960T
2011-08-23 Publication of ES2364047T3 publication Critical patent/ES2364047T3/en
Joint joint for a shoulder stent with a glenoid anchor for a joint part (5) and with a hemispherical shaped joint part (5), which can be fixed in the glenoid anchor, in which the glenoid anchor comprises a plate (1) that can be placed in the resected glenoid bone (2) and which has holes (3) for fixation elements (8) for anchoring in the glenoid bone (2), and a trunk (4) for fixation of the articulation part (5), in which the trunk (4) is fixedly connected with the plate (1), characterized in that the trunk (4) has on its inner side a housing (31) with a conical surface (6 ) for a pressure seat with a conical pivot (7) of the articulation part (5), and because the articulation part (5) ends flush with an upper edge (17) of the plate (1) or protrudes only in an insignificant measure above it and protrudes above a lower edge (16) of the plate (1) more than above the upper edge (17).
The invention relates to a joint joint for a shoulder stent with a glenoid anchor for a joint part and with a hemispherically shaped joint part, which can be fixed on the glenoid anchor. The glenoid anchor comprises a plate that can be placed in the resected glenoid bone and which has holes for fixation elements for anchoring in the glenoid bone, and a trunk for the fixation of the joint part, in which the trunk is attached staring with the plate. A joint joint of this type is known from US 2003/0114933 A1.
Artificial shoulder joints are used, for example, in osteoarthritis with progressive wear of the joint surfaces of the shoulder joint or in complex fractures of the humeral head. In a total stent, the articulation surfaces of both the humeral head and the glenoid cavity are replaced. In the case of a damaged rotary cuff or obvious wrong provision with a conventional shoulder prosthesis, a reverse shoulder stent may be used, in which the artificial prosthesis head and the artificial spherical cavity are interchanged with respect to their positions with a natural shoulder joint.
For fixing the artificial spherical cavity or the artificial prosthesis head in a conventional or reverse shoulder stent in the glenoid, a separate glenoid anchor of the type mentioned at the beginning is usually provided, which can be tied in the glenoid by means of bone screws The respective joint part to be placed on the side of the glenoid, the spherical cavity or the head of the prosthesis can then be placed again on the plate and can be fixed by means of a threaded joint in such a glenoid anchor. To this end, the known glenoid anchor trunk has an internal thread and a pivot of the joint part to be installed has a corresponding external thread.
However, in such a glenoid anchor it is an inconvenience that in the case of a threaded joint, premature loosening of the joint part joint with respect to the glenoid anchor may occur. In particular, in the case of a threaded joint, particles or chips can be eroded, which can lead to inflammations and / or can cause the premature loosening mentioned above.
The invention is based on the problem of creating a joint joint with a glenoid anchor of the type mentioned at the beginning, which guarantees a secure anchor in the glenoid and at the same time a reliable joint of a shoulder stent.
The solution of this problem is carried out through the features of claim 1 and, in particular, because the trunk has on its inner side a housing with a conical surface for a pressure seat with a conical pivot of the articulation part.
The invention is characterized, as depicted in claim 1, because a conical housing is configured in the trunk, that is, an inner cone, in which a pivot of an articulation part can be engaged, which is also conically shaped. In this way, a pressure seat can be created between the glenoid anchor and the articulation part, which guarantees a particularly stable and stable joint, in which the danger of particle erosion and / or premature loosening is especially reduced. .
The glenoid anchor also has the advantage that the conical housing of the trunk and the conical pivot of the articulation part can be manufactured in a particularly simple way. In particular, the trunk and the pivot can be made of different materials, without there being a high danger, conditioned by different degrees of hardness, from an erosion of softer material particles. The plate and the trunk are preferably made of metal, respectively.
Furthermore, according to the invention, the conical connection between the trunk and the pivot can be created in a particularly simple way, for example by means of a single impact with defined impact force, especially by means of a firing pin, in which as opposed to a threaded joint in a conical joint, uniform tension can be achieved along the entire inner side of the trunk.
Advantageous embodiments of the invention are indicated in the dependent claims, in the description as well as in the drawing.
The glenoid anchor housing preferably has a total conical angle between 3º and 5º, in which the conical pivot of the articulation part can engage with identical conical angle under the configuration of a pressure seat. In addition, an average conical diameter between 5 and 8 mm is preferably provided. Such a conical angle and such a conical diameter have been found to be especially suitable with respect to the limited anchoring possibilities in the glenoid bone and at the same time guarantee an especially strong retention of the pressure seat.
The average wall thickness of the trunk is preferably between 0.3 and 2 mm. With an average wall thickness of this type, which also takes into account the limited anchoring possibilities in the glenoid bone and which has also been revealed as especially suitable, the trunk, which preferably distances itself from the plate towards the glenoid bone, it can be used for additional anchoring of the glenoid anchor in the glenoid bone, since when the pivot of the joint part is inserted or struck for the conical joint configuration, the trunk diameter is enlarged at least to an insignificant extent and in this way an anchorage of the trunk can be achieved in the glenoid bone.
Moreover, according to the invention it is proposed that the plaque be curved towards the glenoid bone. The plaque is preferably tied in the area of the natural shoulder cavity in the resected glenoid bone. In the case of a plate curved towards the glenoid bone, which resembles the natural curvature of the shoulder cavity, the erosion of the bone in the resected glenoid bone can be reduced. In addition, a curved plate, which is placed in the correspondingly configured resected glenoid bone, can be tied by virtue of the curvature more securely in the glenoid bone than a flat plate, which is placed on a flat place of the glenoid bone.
According to a preferred embodiment of the invention, for the configuration of the curvature, the plate is provided with an outer surface and an inner surface, which are recesses of spherical surfaces with a radius between 2 and 40 mm. The midpoints of the two spherical surfaces can be distanced from each other and the radii of the outer surface and the inner surface can be differentiated from each other.
In addition, it is preferred that in the case of an oval plate, the edges of the plate ending in the longitudinal direction have a distance between 25 and 50 mm. An oval plate can be understood as any plate, which deviates from a basic circular shape, bypassing the curvature of the plate. To it belong, for example, an ellipsoidal shaped plate, an egg-shaped plate or a longitudinal round plate and any other discretionary plate to which a longitudinal direction can be assigned. The distance of the edges set in the longitudinal direction of the plate defines in this case the maximum extension of the plate.
According to a special configuration of the invention, the trunk is positioned eccentrically with respect to the plate, so that the plate can present, for example, any form explained above or any other discretionary form, to which a longitudinal direction Through the configuration of the trunk outside a midpoint or a polar axis of the plate, the glenoid anchor can be adapted particularly advantageously to the natural geometry of the glenoid bone and / or to the limited possibilities of anchoring in the glenoid bone .
Preferably, the point of intersection of the longitudinal axis of the trunk with a straight line of the edges of the plate is displaced in a measure of 2 to 8 mm from the center of the straight line towards a lower edge. For the rest, the longitudinal axis of the trunk is inclined with respect to a perpendicular to a straight line of union of the edges of the plate at an angle β of 3º to 7º downwards. In the edges, the edges that end in the longitudinal direction of an oval plate are preferably treated in each case, so that the longitudinal direction is especially oriented upper-lower.
It is especially advantageous that the longitudinal axis of the conical surface coincides with the longitudinal axis of the trunk. In this way, an asymmetrical configuration of the pressure seat is achieved, which can guarantee an especially reliable fixation of the articulation part in the glenoid anchor. This especially means that the longitudinal axis of the pivot of the articulation part also coincides with the longitudinal axis of the trunk. According to another preferred embodiment of the invention, the trunk has several longitudinal ribs, especially of the knife type, for secure anchorage against rotation on its outer side. The longitudinal ribs extend in this case essentially parallel to the longitudinal axis of the grunt and are distanced as fins from this trunk radially outward. The longitudinal ribs extend in this case preferably over the entire height of the trunk and can be fitted during the glenoid anchor mooring in the glenoid bone to counteract a possible rotation of the glenoid anchor.
In addition, according to the invention, several cuts can protrude from the plate to the glenoid bone, in particular annularly with openings for the growth of bone material within them. The ring-shaped cuts are preferably placed on the plate through the introduction of pressurized holes provided for this purpose. Through the bone material grown inside the openings, the resistance of the glenoid anchor mooring in the glenoid bone can be further increased.
For the realization of a reverse shoulder stent, the articulation part is configured hemispherically and ends up flush with an upper edge of the plate or over comes out only to an insignificant extent above it and protrudes above a lower edge of the plate rather than the upper edge, so that preferably the upper edge is arranged above and the lower edge is arranged below. In this way, a greater area of articulation can be made possible to a spherical bearing shell, which slides over the spherical surface of the articulation part and which can be fixed in the humerus, or to a spherical cavity on the lower side of The joint part. In particular, this impact can prevent an impact of the humerus on the glenoid bone.
Preferably, different articulation parts are provided hemispherically with different dial diameters. In this case, the operator can select from that set of articulation parts different from each other that joint part that seems more suitable with respect to the diameter of the ball for the respective patient.
Preferably, the plate can be lowered in a recess of the hemispherically shaped joint part, which deviates from a circular shape, in particular corresponding to the oval outer contour of the plate. The especially oval plate can be lowered with its outer contour in the proper recess of the hemispherical joint part, to fix the angular position of the plate with respect to the hemispherical joint part, when the pressure seat is made between the pivot of the articulation part and the conical surface of the trunk housing.
The plate and the trunk may be constituted of a material especially compatible with the body, in particular of titanium or of a titanium alloy and the hemispherically shaped joint part may be constituted of a wear-resistant material, for example of an alloy of Cr-Mo, to which Ta can be additionally mixed.
In particular, the hemispherically shaped articulation part can be constituted of a Cr-Mo alloy and can be paired with a spherical shaped bearing shell, which can be fixed in the humerus, which is constituted of a Cr-alloy. Mo. A reverse shoulder stent is usually configured in such a way that the hemispherically shaped joint part and the spherically shaped bearing shell engage exactly in each other, such that as opposed to a natural shoulder joint or a conventional shoulder stent, a displacement of the spherical head in the cavity is not allowed to prevent subluxation. Therefore, in a reverse shoulder stent, two components can also be matched together, which in each case consist of a Cr-Mo alloy. However, in principle, the spherical bearing shell may also be made of a plastic, for example polyethylene, and the hemispherically shaped joint part may be made of ceramic due to the conical joint.
For the performance of a conventional shoulder stent, a shell-shaped joint part can be fixed with an outline on the plate, which corresponds especially to the outer contour of the plate. In the shell-shaped joint part, which is preferably constituted of plastic, for example of polyethylene, a joint head placed in the humerus can then fit.
The invention is described below by way of example with reference to the drawing. In this case:
Figure 1 shows a perspective view of a glenoid anchor with a plate and a trunk.
Figures 2a, b show a front view and a side view, respectively, of the glenoid anchor of Figure 1.
Figure 3 shows the cross section through the glenoid anchor of Figure 2a along the line IV-IV.
Figure 4 shows an enlarged representation of an annular cut, placed on the plate, with openings.
Figure 5 shows a cross section through the glenoid anchor of Figure 2a.
Figures 6a-d show different views and a cross section of a hemispherically shaped joint part with a first spherical diameter.
Figures 7a-d show different views and a cross section of a hemispherical articulation part with a second spherical diameter.
Figures 8a-c show an articulation joint according to the invention with the glenoid anchor according to Figures 1 to 5 and the hemispherically shaped joint part according to Figures 6 and 7, respectively, in the assembled state , Y
Figure 9 shows an articulated joint with the glenoid anchor according to Figures 1 to 5 and with a shell-shaped joint part in the assembled state.
Figures 1 to 5 show a glenoid anchor for a joint part explained in detail elsewhere with a metal plate 1, which is placed in a resected glenoid bone 2, in which the glenoid bone 2 is represented in the cross section in Figure 2a for simplicity. In the metal plate 1, two holes 3 are provided, respectively, for a bone screw 8, which in each case serve to tie the glenoid anchor in the glenoid bone 2, so that in figure 2a only a bone screw 8 is represented .
The plate 1 made of titanium or a titanium alloy, which is configured in image symmetry with respect to a mirror plane, has in the front view of Figure 2b an oval basic shape, through which the longitudinal direction 14 of the plate 1. The two holes 3 are disposed in the area of the ends of the oval plate 1 which are chlorinated in the longitudinal direction 14, which are closed by an upper edge 17 and a lower edge 16. The edges 16, 17 that close the plate 1 in the longitudinal direction 14 have a mutual distance a, which can be between 25 and 50 mm.
The plate 1 is also curved towards the glenoid bone 2. The plate 1 has an outer surface 10, which is directed towards the glenoid bone 2 and an inner surface 11, which is away from the glenoid bone 2. For the configuration of the curvature of the plate 1, the outer surface 10 and the inner surface 11 are designed, respectively, as recesses or spherical surface sections. The radii r1, r2 of the spherical surfaces associated with the outer surface and the inner surface 10, 11, which can be between 22 and 40 mm, are spaced in an insignificant distance from each other, so that additionally the midpoints of the two spherical surfaces are displaced from each other.
In addition, on the outer surface 10 of the plate 1, several annular shaped cuts 21 are placed, which are distanced in the direction of the glenoid bone 2 from the plate 1. The annular shaped cuts 21 each have a plurality of openings 22, in whose interior bone material grows after the glenoid anchor mooring in the glenoid bone 2, to increase the resistance of the glenoid anchor mooring.
The glenoid anchor further comprises a thimble shaped trunk 4, which is fixedly connected with the plate 1 and is eccentrically placed in this plate. The trunk 4, which is made of titanium or a titanium alloy, is distanced from the oval plate 1 in the direction of the glenoid bone 2 and has on its conical outer side several longitudinal ribs 20 of the blade type, which are essentially oriented parallel to a longitudinal axis 18 of the trunk 4 and that ensure the glenoid anchor against a rotation around the longitudinal axis 18 of the trunk 4.
Between the upper edge 16 and the lower edge 17 of the plate 1 a connecting line 19 is defined. The longitudinal axis 18 of the trunk 4 is inclined downwardly from a perpendicular 33 to the connection line 19 with an inclination angle. β, which can be between 3rd and 7th. The point of intersection of the longitudinal axis 18 of the trunk with the joint line 19 of the two edges 16, 17 can be displaced in this case in a measure b, which can be between 2 and 8 mm, from the center of the line of junction 19 in the direction of the bottom edge 16 of the plate 1.
The trunk 4 has on its inner side a housing 31 with a conical surface 6. The longitudinal axis 18 of the conical surface 6 coincides in this case with the longitudinal axis 18 of the trunk 4. The cone configured in the housing 31 has an average diameter d of the cone between 5 and 8 mm and a total angle of the cone or opening angle α between 3º and 5º. The average thickness of the wall s of the trunk 4 in the area of the conical surface 6 is between 0.3 and 2 mm.
The trunk 4 is designed for fixing a joint part 5 hemispherically, as shown in Figures 6 and 7 in two different sizes. To this end, a conical cone 7 of the articulation part 5 is connected to the conical surface 6 of the housing 31 of the trunk 4 as a pressure seat, as shown in Figure 8, so that a joint is configured of articulation according to the invention. The hemispherically shaped articulation part 5 is made from a Cr-Mo alloy and can be paired with a spherical bearing shell, not shown, which can be fixed in the humerus and which is also made of an alloy from Cr-Mo. A joint joint of this type corresponds to a reverse shoulder stent.
The average diameter of the cone and the total conical angle of the pivot 7 correspond to the diameter of the cone d and the total conical angle α of the housing 31. The longitudinal axis of the pivot 7 coincides in the assembled state of the joint with the longitudinal axis 18 of the trunk 4. In a manner similar to the longitudinal axis of the trunk 4 of the glenoid anchor, the longitudinal pivot axis 7 of the articulation part 5 is inclined downwardly facing a polar axis 33 of the articulation part 5 hemispherically around at angle β and its point of intersection with a base plane 34 of the articulation part 5 hemispherically displaced downwards in the measure b.
The hemispherically shaped articulation part 5 comprises a recess 25, whose contour corresponds to the outer contour of the oval plate 1, so that the plate 1 can be lowered during the assembly of the articulation joint with exact adjustment in the recess 25 the articulation part 5 hemispherically. By virtue of the oval shape of the plate 1, whose ends placed in the longitudinal direction 14 are not symmetrical, only an angular position of the oval plate 1 with respect to the articulation part 3 can be achieved hemispherically.
The hemispherically shaped joint part 5 shown in figure 6 with a first diameter of the sphere D1 ends, in the assembled state of the joint joint according to figure 8a, flush in the upper edge 17 of the plate 1 with this edge and protrudes in an insignificant measure on the lower edge 16 of the plate 1 under the configuration of a projection u1. The articulation part 5 has an auxiliary bore 29, which serves together with the pivot 7 for the retention of the articulation part 5 during the machining of the conical surface during the manufacture of the articulation part 5.
The assembled state of an articulation joint with a hemispherically shaped articulation part 5 shown in Figure 7 with a second diameter of the sphere D2, which is larger than the diameter of the sphere D1, is shown in Figure 8b. The articulation part 5 of Figure 7 is in an insignificant measure above the upper edge 17 of the plate 1 and protrudes above the lower edge 16 of the plate 1 under the configuration of a projection u2 rather than above the upper edge 17. Figure 8c shows an overlap of the assembled joint joints of Figures 8a and 8b, illustrating Figure 8c especially different wall thicknesses s1 and s2 of the trunk 4.
Figure 9 shows another embodiment of an articulation joint, in which, however, only the differences of this embodiment should be explained with respect to the embodiment shown in Figures 1 to 8. The same or corresponding parts in this case they are designated with the same reference signs.
In opposition to Figure 8, a joint joint is shown in Figure 9, which presents instead of a hemispherical shaped joint part., A shell-shaped joint part 15, into which a head of Joint not shown, placed in the humerus, so that a conventional shoulder stent is configured. The shell-shaped joint part 15 made of polyethylene has in this case an outer contour, which corresponds to the outer contour of the oval plate 1, such that the shell-shaped joint part 15 does not protrude above the plate oval 1.
The following describes the mooring of the glenoid anchor in the glenoid bone and the joint joint assembly according to the invention with reference to Figures 1 to 9.
First, the glenoid bone 2 is resected with a spherical burr, such that a support surface, corresponding to the curvature of the plate 1, is obtained for the plate 1. Then it is drilled on the support surface by middle of a central drill a drill for the trunk 4 of the glenoid anchor. Then the glenoid anchor can be placed. To fix the glenoid anchor, holes are drilled for the bone screws 8, in which the bone screws 8 are finally screwed. The glenoid anchor is now fixedly connected with the glenoid bone 2.
The joint part 5, 15 can then be fixed in the glenoid anchor. To this end, the pivot 7 of the articulation part 5, 15 in the trunk housing 31 is pressed and the articulation part 5, 15 is oriented such that the outer contour of the plate 1 can fit into the recess 25 of the articulation part 5, 15. After pressing lightly, the articulation part 5, 15 is then introduced by means of a firing pin. The articulation part 5, 15 is now connected through a pressure seat fixedly with the glenoid anchor.
In the case of a reverse shoulder stent, different articulation parts 5 of hemispherical shape with different diameters of the sphere D are available to the operator, from which the operator can select the appropriate joint part 5 in each case for the patient The selection of the appropriate articulation part 5 can be carried out by means of test joint parts.
The glenoid anchor comprises a trunk 4, which is designed both for the mooring of the glenoid anchor in the glenoid bone 2 and also for the fixation of the joint part 5, 15 in the glenoid anchor, and the joint part can be fixed 5, 15 in a particularly simple way and at the same time in a particularly reliable way by means of a pressure seat. The trunk 4 has in this case an outer shape, which has proved especially suitable for a pressure seat for a shoulder stent.
1 Oval plate 2 Glenoid bone 3 Drill 4 Trunk 5 Joint part hemispherical 6 Conical surface 7 Conical pivot 8 Bone screw 10 Outside surface 11 Inside surface 14 Longitudinal direction 15 Shell-shaped joint part 16 Lower edge 17 Upper edge 18 Longitudinal axis 19 Straight connection 20 Longitudinal rib 21 Ring-shaped cut 22 Opening 25 Cut-out 29 Auxiliary bore 31 Housing 32 Perpendicular 33 Polar axis 34 Base plane at Distance b Magnitude d Diameter of cone D Diameter of sphere r Radius s Thickness of the wall u Overhang α Opening angle β Tilt angle
1.- Joint joint for a shoulder stent with a glenoid anchor for a joint part
(5) and with a hemispherical articulation part (5), which can be fixed in the glenoid anchor, in which the glenoid anchor comprises a plate (1) that can be placed in the resected glenoid bone (2) and which has holes (3) for fasteners (8) for anchoring in the glenoid bone (2), and a trunk (4) for fixing the joint part (5), in which the trunk (4) it is fixedly connected with the plate (1), characterized in that the trunk (4) has on its inner side a housing (31) with a conical surface (6) for a pressure seat with a conical pivot (7) of the part of articulation (5), and because the articulation part (5) ends flush with an upper edge (17) of the plate (1) or protrudes only in an insignificant measure above it and protrudes above a lower edge (16 ) of the plate (1) more than above the upper edge (17).
2. Joint joint according to claim 1, characterized in that the housing (31) has a central conical diameter (d) between 5 and 8 mm.
3. Joint joint according to claim 1 or 2, characterized in that the housing (31) has a total conical angle (α) between 3rd and 5th.
4. Joint joint according to one of claims 1 to 3, characterized in that the average thickness of the trunk wall (s) (4) in the area of the conical surface (6) is between 0.3 and 2 mm
5. Joint joint according to one of claims 1 to 4, characterized in that the plate (1) is curved towards the glenoid bone (2).
6. Joint joint according to claim 5, characterized in that the plate (1) is provided with an outer surface (10) and an inner surface (11), which are recesses of spherical surfaces with a radius (r1, R2) between 22 and 40 mm.
7. Joint joint according to one of claims 1 to 6, characterized in that in the case of an oval plate (1), the edges (16, 17) of the plate (1) ending in the longitudinal direction (14 ) have a distance (a) between 25 and 50 mm.
8. Joint joint according to one of claims 1 to 7, characterized in that the trunk (4) is placed eccentrically on the plate (1).
9. Joint joint according to one of claims 1 to 8, characterized in that the point of intersection of the longitudinal axis (18) of the trunk (4) with a straight line (19) of the edges (16, 17) of the plate (1) is displaced in a measure (b) from 2 to 8 mm from the center of the straight line (19) towards a lower edge (16).
10. Joint joint according to one of claims 1 to 9, characterized in that the longitudinal axis
of the trunk (4) is inclined with respect to a perpendicular (32) to a straight line (19) of the edges (16, 17) of the plate (1) at an angle (β) of 3º to 7º down.
11. Joint joint according to one of claims 1 to 10, characterized in that the longitudinal axis
of the conical surface (6) coincides with the longitudinal axis (18) of the trunk (4).
12. Joint joint according to one of claims 1 to 11, characterized in that the trunk (4) has several longitudinal ribs (20) especially for the type of blade for the secure anchorage against rotation on its outer side.
13. Joint joint according to one of claims 1 to 12, characterized in that from the plate
(1) towards the glenoid bone (2) several cuts (21) stand out, in particular annularly with openings (22) for the growth of bone material inside them.
14. Joint joint according to one of claims 1 to 13, characterized in that different articulation parts (5) are provided hemispherically with different diameters of the sphere (D).
15. Joint joint according to one of claims 1 to 14, characterized in that the plate (1) can be lowered in a recess (25) of the articulation part (5) hemispherically, which deviates from a circular shape, in particular corresponding to the oval outer contour of the plate (1).
16. Joint joint according to one of claims 1 to 15, characterized in that the plate (12) and the trunk (4) are constituted of titanium or a titanium alloy and the articulation part (5) of form Hemispheric is made of a wear-resistant material, for example a Cr-Mo alloy.
17. Joint joint according to one of claims 1 to 16, characterized in that the hemispherically shaped joint part (5) is constituted of a Cr-Mo alloy and is paired with a spherical bearing shell, which can be fixed in the humerus, which is made of a Cr-Mo alloy.
18. Joint joint according to one of claims 1 to 17, characterized in that the hemispherically shaped joint part (5) is constituted of a Cr-Mo or ceramic alloy and is paired with a bearing shell of spherical shape, which can be fixed in the humerus, made of plastic, for example polyethylene.
ES04011960T 2004-05-19 2004-05-19 Glenoid anchor. Active ES2364047T3 (en)
ES2364047T3 true ES2364047T3 (en) 2011-08-23
ES04011960T Active ES2364047T3 (en) 2004-05-19 2004-05-19 Glenoid anchor.
FR2944694B1 (en) * 2009-04-22 2012-05-18 Tornier Sa Device for fixing the glene of a glenoidal articular component for a shoulder prosthesis and corresponding shoulder prosthesis
2004-05-19 EP EP20040011960 patent/EP1598034B1/en not_active Expired - Fee Related
AT503442T (en) 2011-04-15
JP3810088B2 (en) 2006-08-16 Acetabular cup body prosthesis