Source: https://patents.justia.com/patent/20030149485
Timestamp: 2020-07-08 23:55:18
Document Index: 87824038

Matched Legal Cases: ['art 37', 'arts 36', 'art 37', 'art 37', 'art 37', 'art 37', 'art 137']

US Patent Application for Prosthetic element comprising two components and process for assembling such a prosthetic element Patent Application (Application #20030149485 issued August 7, 2003) - Justia Patents Search
Justia Patents Joint BoneUS Patent Application for Prosthetic element comprising two components and process for assembling such a prosthetic element Patent Application (Application #20030149485)
Feb 4, 2003 - TORNIER SA
Device for setting and removing an implant such as a suture anchor
[0001] The present invention relates to a prosthetic element comprising two principal components, to the use of such an element, and to processes for assembly of such an element.
[0002] A prosthetic element most often comprises a part intended to constitute an articular surface and a part for anchorage in the patient's bone. Taking into account their respective mechanical functions, these parts are sometimes composed of distinct components, such components each being optimalized as far as the choice of their constituent materials and their mode of manufacture are concerned. These components should then be able to be assembled precisely and easily. For example, an anchoring component may be fixed in the bone and a component forming an articular surface added thereon.
[0003] In certain prior art devices, such as disclosed in FR-A-2 605 514 for example, it is known to use a screw for locking one part of a prosthesis on another part provided with a corresponding tapping. It is also known from FR-A-2 689 756 to use a screw for locking a shank fast with an articular head inside a bore made in a prosthesis anchoring part. It is also possible, as in FR-A-2 737 107, to provide using a screw captive in a housing made on one of the parts and intended to cooperate with a tapping made in the other part.
[0004] The known devices require precise positioning and alignment of the components constituting a prosthetic element, which is not always possible as the operative field is difficult to access and as it is delicate to visualize due to the traumatic depression of the glenoid cavity. In addition, the screws used in the known system may be displaced or poorly aligned with respect to the parts with which they are to cooperate, hence a risk of distorting their threads or the tapping with which they are to cooperate.
[0005] It is a more particular object of the present invention to overcome these drawbacks by proposing a prosthetic element that may be assembled in particularly easy and precise manner, while remaining very practical to use.
[0006] To that end, the present invention relates to a prosthetic element which comprises two principal components intended to be assembled together and immobilized with respect to each other by means of a screw, this prosthetic element being characterized in that the screw is adapted to be screwed by means of at least one thread in two tappings which are respectively fast or intended to be rendered fast with one and the other principal components and in that the screw comprises at least one radial element in relief adapted to come into abutment against a stop surface fast with a first component, and a non-threaded end forming guide finger and adapted to slide in a housing made in the second component.
[0007] Thanks to the invention, the locking screw may be immobilized with respect to one of the principal components, this guaranteeing its positioning and orientation with respect thereto. Then, when its guide finger is inserted in the housing of the second component which has a transverse section corresponding to that of the finger, the components are guided with respect to one another in a movement of mutual approach. The radial element in relief provided on the screw allows it to exert on the stop surface an effort directed towards the second component, in order to firmly apply these components against one another and thus to contribute to their relative immobilization, after screwing of the screw in the second tapping.
[0008] According to advantageous but non-obligatory aspects of the invention, this prosthetic element incorporates one or more of the following characteristics:
[0009] the element of the screw in relief is formed by a radial flange made on the screw between the two threads thereof.
[0010] the stop surface is annular and surrounds this screw. In that case, this stop surface may be provided to be formed by the face of a ring surrounding the screw, this ring being rigidly connected to a bush screwed in the first component. This ring and this bush allow an efficient transmission of effort between the screw and the first component.
[0011] the first and second components are respectively provided with truncated bearing surfaces, the screw being adapted to apply, by its screwing, these surfaces against each other. This aspect of the invention takes advantage of the fact that the screw of the invention guarantees satisfactory positioning and movement of approach of the truncated bearing surfaces provided respectively on the first and second components, this limiting the risks of misalignment of these surfaces. These bearing surfaces are advantageously respectively centred on the central axis of the screw, when the latter is screwed in the first component, and on the central axis of the housing for slide of the centering finger.
[0012] the tapping which is fast or intended to be rendered fast with the second component is formed in the housing for slide of the centering finger, towards an inlet zone of the screw.
[0013] the first component forms a convex articular surface and defines a volume in which the screw may be mounted and the second component engaged, at least partially. The first component may for example be in the form of a portion of sphere.
[0014] the housing for slide of the guide finger is made in a shank for anchoring the second component in a bone.
[0015] According to a first advantageous form of embodiment of the invention, the screw is provided with two threads adapted to cooperate successively with two tappings respectively fast with one and the other principal components.
[0016] According to a second advantageous form of embodiment of the invention, the screw is provided with a single thread adapted to cooperate successively with two tappings which are respectively fast or intended to be rendered fast with one and the other of the principal components.
[0017] A prosthetic element as described hereinabove can be used in particular in the production of the glenoid part of a total shoulder prosthesis.
[0018] The invention also relates to a first process for assembling a prosthetic element as described hereinabove and, more precisely, to a process which comprises steps consisting in:
[0019] immobilizing the screw with respect to a first principal component of the prosthetic element by screwing this screw in a first tapping fast or intended to be rendered fast with the first principal component, a surface forming stop, at a distance from the screw with respect to the first component, being arranged around this screw after or before this immobilization;
[0020] covering with a housing made on a second component, a free end of the screw projecting with respect to the first component;
[0021] pushing the first and second components towards each other, causing the end of the screw to slide in the afore-mentioned housing;
[0022] unscrewing the screw with respect to the first tapping, and
[0023] screwing the screw in a second tapping made in the second component, exerting on the afore-mentioned stop surface an effort of approach of the first and second components.
[0024] According to a second process of assembly in accordance with the invention, the screw is immobilized and its free end is covered as indicated hereinabove, following which:
[0025] one of the principal components is impacted in the direction of the other so as to bring them closer, causing the free end of the screw to slide in the housing, until the components are brought into contact with each other;
[0026] the screw is unscrewed with respect to the first tapping, and
[0027] the screw is screwed in a second tapping made in the second component until an effort of relative immobilization of the components is obtained in their position in contact, this effort being exerted on the afore-mentioned stop surface.
[0028] Thanks to the processes of the invention, the screw is permanently correctly positioned with respect to the components constituting the prosthetic element, this ensuring for the surgeon precision of assembly.
[0029] The invention will be more readily understood on reading the following description of two forms of embodiment of a prosthetic element and of its process of assembly in accordance with its principle, given solely by way of example and with reference to the accompanying drawings, in which:
[0030] FIG. 1 is an exploded side view of a prosthetic element in accordance with a first form of embodiment of the invention.
[0031] FIG. 2 is an axial section of the prosthetic element of FIG. 1, during a first step of its assembly.
[0032] FIG. 3 is a section similar to FIG. 2, during a second step of assembly.
[0033] FIG. 4 is a section similar to FIG. 2, during a third step of assembly.
[0034] FIG. 5 is a section similar to FIG. 2, when assembly is terminated.
[0035] FIG. 6 is a view similar to FIG. 3 for a prosthetic element in accordance with a second form of embodiment of the invention, and
[0036] FIG. 7 is a view similar to FIG. 5 for the element of FIG. 6.
[0037] Referring now to the drawings, the prosthetic element E shown in the Figures is intended to be mounted on a shoulder in order to constitute an articular surface S intended to cooperate with a cupule (not shown) belonging to a complementary prosthetic element anchored in the patient's humerus.
[0038] The surface S is approximately in the form of a portion of sphere and constitutes the outer surface of a first principal component 1 made of a material compatible with the movements of articulation on the cupule associated therewith.
[0039] X1 denotes a central axis of the component 1 which constitutes a diameter of the surface S. The component 1 is provided with a central recess 11 centred on axis X1 and of which 12 denotes the peripheral surface, this surface being of truncated shape.
[0040] A tapping 13 is provided at the bottom of the recess 11, centred on axis X1
[0041] A second tapping 14 is centred on axis X1 and opens to the outside, at the level of surface S.
[0042] A circular bore 15 is made between the tappings 13 and 14, the radius R15 of this bore being included between the radii of the tappings 13 and 14.
[0043] A second principal component 2 is provided to be anchored in the glenoid cavity of the shoulder and, to that end, comprises a shank 21 provided with grooves 22. X2 denotes the axis of the shank 21 which is substantially cylindrical and of circular cross-section.
[0044] The component 2 also comprises a plate 23 which is solid and in one piece with the shank 21, this plate being provided with a truncated outer surface 24 centred on axis X2.
[0045] The maximum radii of the surfaces 12 and 24 are substantially identical and their respective taper angles &agr; and &bgr; are identical, this making it possible to provide a surface bearing of these surfaces against each other.
[0046] The shank 21 is provided with a central bore 25, of cylindrical shape and which extends in the plate 23 via a tapping 26.
[0047] The element E also comprises a screw 3 of which X3 denotes the longitudinal axis. This screw is provided with a first thread 31 intended to cooperate with the tapping 14 in order to immobilize the screw 3 on the component 1, axes X1 and X3 in that case merging.
[0049] The screw 3 is also provided with an outer radial flange 34 of which R34 denotes the radius.
[0050] A second thread 35 is also provided on the screw 3, opposite thread 31 with respect to the flange 34. In other words, the flange 34 is disposed axially, along the screw 3, between the threads 31 and 35.
[0051] R31 and R35 respectively denote the radii of the threads 31 and 35. Radius R34 is greater than radii R31 and R35, with the result that the flange 34 constitutes a radial element of the screw 3 in relief, particularly with respect to the threads 31 and 35.
[0052] The screw 3 comprises, towards its rounded end 36 opposite end 32, a cylindrical part 37 of circular cross-section of which R37 denotes the radius.
[0053] Parts 36 and 37 of the screw 3 form a guiding and centering finger intended to slide in the bore 25 which is of circular cross-section and of which R25 denotes the radius, this radius itself being slightly greater than radius R37. The respective transverse sections of the housing 25 and of the part 37 correspond to each other, this making it possible to guide part 37, and consequently the centering finger, in translation when it slides in the housing 25.
[0054] The tapping 26 and the thread 35 are provided to cooperate so as to allow the screw 3 to be screwed in the component 2 after introduction of the centering finger in the bore 25.
[0055] The tapping 26 is formed in the plate 23, i.e. on the side of introduction of the screw 3 in the housing 25. The inlet zone 25a of the housing 25 is of rounded and concave shape, which makes it possible to pre-center the end 36 when it is introduced in the housing 25.
[0056] In a variant embodiment, the zone 25a may be replaced by a truncated chamfer.
[0057] A threaded bush 4 is also provided. X4 denotes its central axis and 41 its outer thread which is provided to cooperate with the tapping 13, in order to immobilize the bush 4 on the component 1, axes X1 and X4 in that case merging.
[0058] This bush comprises a ring 42 of which 421 denotes the inner radial surface and 422 the lateral surface facing the flange 34 when the pieces 3 and 4 are in the configuration of FIG. 1. The ring 42 is in one piece with the rest of the bush 4 and connected thereto by tabs 43 which may take any shape adapted to their function.
[0059] The bush 4 is provided with a central bore 44 of which R44 denotes the radius, this radius being greater than radius R34.
[0060] The prosthetic element E is assembled in the following manner:
[0061] The screw 3 is firstly introduced in the recess 11, in the direction of arrow F1, until its thread 31 is taken in the tapping 14. It is then possible to manoeuvre the screw 3, causing it to undergo a movement of rotation represented by arrow R1, by means of a male wrench (not shown) introduced in the housing 33, from outside the component 1.
[0062] This operation makes it possible to immobilize the screw 3 on the component 1 by aligning axes X1 and X3.
[0063] The flange 34 is then received in the bore 15 and bears against the bottom 15a thereof. To that end, the radius R15 is slightly greater than radius R34.
[0064] It is then possible to screw the bush 4 in the tapping 13, as represented by arrow R′1, the ring 42 in that case being disposed around the screw 3.
[0065] The components 1 and 2 may then be brought closer to each other as represented by arrows F2 in FIG. 2, which means causing the guiding and centering finger 36-37 to penetrate and slide in the bore 25, as represented by the arrow of slide C. This induces an alignment of axis X2 on axes X1 and X3.
[0066] Components 1 and 2 may then be respectively advanced in the directions of arrows F2 until surfaces 12 and 24 are brought into contact, as shown in FIG. 3.
[0067] It is then possible to unscrew the screw 3 with respect to the tapping 14, as represented by arrow R2 in FIG. 3, then to push the screw 3 in the direction of the component 2 as represented by arrow F3, which has the effect of bringing the thread 35 into contact with the tapping 26, the flange 34 in that case being in abutment against the surface 422 of the ring 42, as shown in FIG. 4.
[0068] It is then possible to screw the screw 3 in the component 2 thanks to the thread 35 and to the tapping 26, as represented by arrow R3 in FIG. 4, which has the effect of further approaching components 1 and 2 towards each other, as represented by arrows F2. This makes it possible to pass from the configuration of FIG. 4 to that of FIG. 5, where the surfaces 12 and 24 are in firm abutment against each other, this guaranteeing the relative immobilization of components 1 and 2.
[0069] The threads 35 and 41 are of opposite directions, which avoids an untimely unscrewing of the bush 4 during screwing of the screw 3 in the tapping 26.
[0070] During screwing of the screw 3 on the component 2, the flange 34 exerts on the surface 422 of the ring 42 an effort E1 parallel to axes X1, X2 and X3 and directed towards the component 2, this effort being transmitted by the bush 4 to the component 1 which thus advances in the direction of the plate 23.
[0071] In a variant embodiment, in the position of contact between the thread 35 and the tapping 26, the flange 34 may be in the vicinity of the surface 422. In that case, the beginning of screwing of screw 3 on the component 2 causes the flange 34 and the ring 42 to approach each other, before the effort E1 is applied.
[0072] In the course of the phases of assembly of the element E shown respectively in FIGS. 2 to 5, and as represented by arrow C, the guide finger constituted in essence by the cylindrical part 37 of the screw 3, slides in the bore 25, efficiently guiding the screw 3 with respect to the component 2, this avoiding misalignment of the axes X1, X2 and X3 and thus guaranteeing a correct relative positioning of the truncated bearing surfaces 12 and 24.
[0073] According to another approach, the element E may be assembled, from the configuration of FIG. 2, by impacting the principal component 1 in the direction of the principal component 2 so that the cylindrical part 37 of the screw 3 is in essence driven in the housing 25. Impaction takes place until the components 1 and 2 come into contact. It is then possible to unscrew the screw 3 with respect to the component 1 and to screw it in the tapping 26, which enables an effort of relative immobilization of components 1 and 2 to be exerted on the surface 422, and thanks to the flange 34.
[0074] In the second form of embodiment of the invention, shown in FIGS. 6 and 7, elements similar to those of the first embodiment bear identical references increased by 100. The prosthetic element E of this embodiment comprises two principal components 101 and 102 as well as a screw 103 and a bush 104. The component 102 is provided to be engaged in a central recess 111 of the component 101. X101, X102, X103 and X104 respectively denote the central axes of the elements 101 to 104. These axes merge in the positions of FIGS. 6 and 7. The bush 104 is provided with a thread 141 allowing it to be screwed in a tapping 113 provided in the component 101. The bush 104 is also provided with a central tapping 145 provided to cooperate with a thread 131 made on the screw 103.
[0075] As previously, the screw 103 is provided, at the level of its upper end 132, with a housing 133 for a manoeuvring wrench. A flange 134 of relatively great radius R134 is also provided on the screw 103, this flange being able to come into abutment against a lateral surface 522 of a ring 142 formed by the bush 104.
[0076] A bore 125 is made in the anchoring shank 121 of the component 102 and passes through a plate 123 intended to be engaged in a central recess 111 of the component 101.
[0077] The bore 125 is provided, in the vicinity of its inlet zone 125a, with a tapping 126 oriented and configured in order to be able to cooperate with the thread 131 of the screw 103.
[0078] A cylindrical part 137 and an end 136 of the screw 103 constitute a finger for guiding and centering this screw in the housing 125.
[0079] Functioning is as follows:
[0080] In order to assemble the element E, the screw 103 is introduced in the bush 104, causing end 136 to traverse a central recess of the bush 104, this recess being bordered by the tapping 145. The screw 103 is then screwed in the tapping 145 and the sub-assembly 103-104 thus produced is screwed on the component 101 thanks to the thread 141 and the tapping 113. It is then possible to pre-centre the component 101 with respect to the component 102, possibly already in place on a patient, by the cooperation of the finger 136-137 and the housing 125, then to approach these elements towards each other as represented by arrows F2 in FIG. 6.
[0081] It is then possible to unscrew the screw 103 with respect to the bush 104 while pushing it in the direction of the plate 123, the translation of the screw 103 with respect to the component 102 being guided by the finger 136-137. The components 101 and 102 may then be approached towards each other, as shown in FIG. 6, and the screw 103 screwed in the tapping 126 thanks to the thread 131, which makes it possible to obtain a firm immobilization of the elements 102 and 103 with respect to each other, thanks to an effort E1 exerted by the flange 134 on the surface 522.
[0082] As mentioned with reference to the first form of embodiment, another process of assembly may consist, from the position of FIG. 6, in impacting the component 101 in the direction of the component 102 so as to bring these components into contact. The screw 103 is then unscrewed with respect to the bush 4 then screwed in the tapping 126 in order to maintain these components in contact with each other, thanks to the effort E1.
[0083] The thread 131 of the second form of embodiment performs the functions of the threads 31 and 35 of the first embodiment.
[0084] The invention has been represented with a prosthetic component intended to equip the glenoid cavity of a shoulder. However, it is applicable to any type of prosthetic element comprising two principal components.
Publication number: 20030149485
Patent Grant number: 6969406
Applicant: TORNIER SA (Saint Ismier)
Application Number: 10357384
Current U.S. Class: Joint Bone (623/18.11); Shoulder Joint Bone (623/19.11); Femoral Screw (606/65)