A prosthetic ankle assembly including an astragalar component with an upper articular surface that forms part of an ankle joint prosthesis and a lower surface with a shape adapted to engage an upper face of an astragalus. An astragalocalcanean rod is positioned in an astragalocalcanean channel extending from the lower face of the calcaneus to the upper surface of the astragalus. A first end of the astragalocalcanean rod is engage with the lower surface of the astragalar component and a second end of the astragalocalcanean rod is engaged with a lower region of the calcaneus. A distance between the second end of the astragalocalcanean rod is adjustable relative to the lower surface of the astragalar component to adjustably compress the calcaneus against the astragalus.

Patent
   9101480
Priority
Oct 12 2007
Filed
Oct 12 2007
Issued
Aug 11 2015
Expiry
Jan 18 2032
Extension
1559 days
Assg.orig
Entity
unknown
0
35
EXPIRED
23. A prosthetic ankle assembly comprising:
an astragalar component comprising an upper articular surface that forms part of an ankle joint prosthesis, and a lower surface comprising a hollow bone anchoring stub configured to engage an upper face of an astragalus, wherein the hollow bone anchoring stub includes an internally threaded recess; and
an astragalocalcanean rod adapted to be positioned in a bore extending entirely through the astragalus and a calcaneus of an ankle via a lower face of the calcaneus, the astragalocalcanean rod comprising a first threaded end, which couples by screwing to the internally threaded recess, and a second threaded end adapted to engage with the lower face of the calcaneus, such that when progressively screwing the first threaded end into the internally threaded recess, the astragalocalcanean rod is fixed to the astragalar component resting on the astragalus, wherein the second end of the astragalocalcanean rod both approximates and engages the lower region of the calcaneus so as to progressively compress the calcaneus against the astragalus, resulting in an arthrodesis between the calcaneus and the astragalus.
1. A prosthetic ankle assembly comprising:
an astragalar component comprising an upper articular surface that forms part of an ankle joint prosthesis and a lower surface comprising a shape adapted to engage an upper face of an astragalus; and
an astragalocalcanean rod sized to be positioned in a bore extending completely through the astragalus and a calcaneus of an ankle, the astragalocalcanean rod comprising a first end, which is adapted to couple to the lower surface of the astragalar component, and a second end adapted to engage with a lower surface of the calcaneus,
such that during implantation, the astragalocalcanean rod is configured to be inserted through a lower face of the calcaneus so that the first end of the astragalocalcanean rod is coupled to the lower surface of the astragalar component that is engaging the upper face of the astragalus, and wherein the second end of the astragalocalcanean rod both approximates and engages the lower face of the calcaneus so as to progressively compress the calcaneus against the astragalus as the rod advances into the calcaneus from its lower face, resulting in an arthrodesis between the calcaneus and the astragalus.
21. A prosthetic ankle assembly comprising:
an astragalar component comprising an upper articular surface that forms part of an ankle joint prosthesis and a lower surface comprising an anchor structure for osseous anchoring in an astragalus; and
an astragalocalcanean rod sized to be positioned in a bore extending through the astragalus and a calcaneus of an ankle via a lower face of the calcaneus, the astragalocalcanean rod comprising a first end which comprises threads complementary with threads on the astragalar component for coupling by screwing the first end of the astragalocalcanean rod to the lower surface of the astragalar component, and a second end adapted to engage with the lower face of the calcaneus, such that when progressively screwing the first end of the astragalocalcanean rod into the lower surface of the astragalar component, the astragalocalcanean rod is fixed to the astragalar component resting on the astragalus, wherein the second end of the astragalocalcanean rod both approximates and engages the lower region of the calcaneus so as to progressivel compress the calcaneus against the astragalus resulting in an arthrodesis between the calcaneus and the astragalus.
22. A prosthetic ankle kit comprising:
an astragalar component comprising an upper articular surface that forms part of an ankle joint prosthesis and a lower surface comprising a shape adapted to engage an upper face of an astragalus;
an astragalocalcanean rod sized to be positioned in a bore extending through the astragalus and a calcaneus of an ankle via a lower face of the calcaneus, the astragalocalcanean rod comprising a first end adapted to couple to the lower surface of the astragalar component and a second end adapted to engage with the lower face of the calcaneus, such that when progressively coupling the first end of the astragalocalcanean rod to the lower surface of the astragalar component, the astragalocalcanean rod is fixed to the astragalar component resting on the astragalus, wherein the second end of the astragalocalcanean rod both approximates and engages the lower region of the calcaneus so as to progressively compress the calcaneus against the astragalus resulting in an arthrodesis between the calcaneus and the astragalus;
a tibial component of the ankle joint prosthesis adapted for fixation to a distal end of the tibia; and
a prosthetic bearing shaped to be interposed between the astragalar component and the tibial component.
2. The prosthetic assembly of claim 1 wherein the astragalocalcanean rod comprises a length corresponding to a distance between the upper face of the astragalus and the lower face of the calcaneus.
3. The prosthetic assembly of claim 1 wherein the second end of the astragalocalcanean rod comprises a plurality of threads configured to engage with the calcaneus when coupling the first end of the astragalocalcanean rod to the astragalar component.
4. The prosthetic assembly of claim 1, wherein the second end of the astragalocalcanean rod comprises a ring adapted to press against the lower face of the calcaneus so as to approximate and thereby compress the calcaneus against the astragalus when coupling the first end of the astragalocalcanean rod to the astragalar component.
5. The prosthetic assembly of claim 4, wherein the ring is fixedly secured to the second end of the astragalocalcanean rod.
6. The prosthetic assembly of claim 5, wherein the ring is integral with the second end of the astragalocalcanean rod.
7. The prosthetic assembly of claim 4, wherein the ring moveably surrounds the second end of the astragalocalcanean rod.
8. The prosthetic assembly of claim 1 wherein the first and second ends of the astragalocalcanean rod are linked to each other by a smooth intermediate part and wherein the second end of the astragalocalcanean rod comprises a diameter greater than a diameter of the intermediate part.
9. The prosthetic assembly of claim 1 wherein the lower surface of the astragalar component comprises threads complementary with threads on the first end of the astragalocalcanean rod for coupling by screwing the first end of the astragalocalcanean rod to the lower surface of the astragalar component.
10. The prosthetic assembly of claim 1 wherein the lower surface of the astragalar component comprises an anchor structure for osseous anchoring in the astragalus.
11. The prosthetic assembly of claim 1 wherein the lower surface of the astragalar component comprises an anchor structure for osseous anchoring in the astragalus and internal threads complementary to threads on the first end of the astragalocalcanean rod for coupling by screwing the first end of the astragalocalcanean rod to the lower surface of the astragalar component.
12. The prosthetic assembly of claim 1 wherein the second end of the astragalocalcanean rod is configured to receive a driving tool.
13. The prosthetic assembly of claim 1 wherein the astragalocalcanean rod is adapted to be removed from the ankle after fusion of the astragalus with the calcaneus.
14. The prosthetic assembly of claim 1, further comprising:
a tibial component of the ankle joint prosthesis adapted for fixation to a distal end of the tibia; and
a prosthetic bearing shaped to be interposed between the astragalar component and the tibial component.
15. The prosthetic assembly of claim 14 wherein the prosthetic bearing comprises one of a fixed bearing or a moveable bearing.
16. The prosthetic assembly of claim 1, wherein the second end of the astragalocalcanean rod includes a means for engaging the calcaneus.
17. The prosthetic assembly of claim 1, wherein the astragalar component includes a hollow bone-anchoring stub that extends downward from the lower surface.
18. The prosthetic assembly of claim 1, wherein the second end of astragalocalcanean rod includes a recess aligned with a longitudinal axis of the astragalocalcanean rod.
19. The prosthetic assembly of claim 18, wherein the recess has a transverse profile adapted to cooperate with a tool for driving the astragalocalcanean rod in rotation about the longitudinal axis.
20. The prosthetic assembly of claim 1, wherein the astragalocalcanean rod includes an externally smooth middle section located between the first end and the second end.
24. The prosthetic assembly of claim 23, wherein the internally threaded recess is aligned with a longitudinal axis of the hollow bone anchoring stub.
25. The prosthetic assembly of claim 23, wherein the astragalocalcanean rod includes an externally smooth middle section located between the first threaded end and the second threaded end.
26. The prosthetic assembly of claim 23, wherein the lower surface of the astragalar component comprises an arched profile.

The present application claims priority to prior French Application No. 06 09001, filed Oct. 13, 2006, entitled ANKLE PROSTHESIS FOR THE ARTHRODESIS OF THE CALCANEUM.

The present invention relates to a prosthetic ankle assembly and to a surgical method for implanting such an assembly, and in particular, to the treatment of an ankle in which the articulation between the astragalus and the calcaneus are damaged.

One possible treatment involves fusing the three bones represented by the calcaneus, astragalus and tibia, as is proposed in US-A-2005/0107791. A long compression screw internally connects the tibia and the calcaneus by passing through the astragalus, in such a way as to block these three bones relative to one another. This results in a considerable loss of mobility for the patient, since the ankle is totally blocked.

Another possible treatment involves fusing the calcaneus and astragalus, with the aid of a dedicated arthrodesis rod and re-establishing the articular capacity between the astragalus and tibia, by implanting an ankle joint prosthesis. However, the two articulations then have to be treated in two stages: the arthrodesis of the calcaneus and astragalus requires a consolidation period of at least six months, which delays the implantation of the articular prosthesis between the astragalus and the tibia.

US-A-2005/0288792 discloses an astragalar component of an ankle joint prosthesis with which it is possible to re-establish the articular capacity between the astragalus and the tibia, while at the same time using an astragalocalcanean rod that extends from a lower side of the astragalar component to the upper part of the calcaneus, in so doing passing right through the astragalus. In one embodiment, the upper end of this rod is screwed directly into internal threads of the astragalar component, which threads open out on the lower side of this component. Before being implanted, the component and the rod are firmly immobilized relative to each other by screwing. When this screwed assembly is implanted, the rod guarantees good anchoring of the astragalar component, since the latter is thus fixed both to the astragalus and also to the upper part of the calcaneus, which explains why the prosthetic assembly is more specifically intended for revision of an arthroplasty of the ankle. However, the assembly does not effectively block the articulation between the calcaneus and the astragalus, since relative movements around and/or along the rod remain possible and, in practice, appear quickly.

FR-A-2 220 235 proposes a prosthetic ankle assembly comprising an astragalar component of an ankle joint prosthesis in the form of a support designed to be fixed to the astragalus of a patient. This support is intended to cooperate in an articulated manner with a tibial rod, with interposition of an intermediate articulated component. In its lower part, the astragalar support is joined to three anchoring feet, namely two anterior feet and one posterior foot, which are intended respectively to be inserted into corresponding cavities formed in the astragalus and in the calcaneus. As regards the posterior foot, one embodiment entails this foot being formed by at least one sagittal screw that passes through the support from top to bottom, until bearing with its head on the support, while its stem is inserted, without being screwed, into the cavity of the calcaneus, plugged with cement. The benefit of using such a screw is that, if necessary, it can be unscrewed in order to facilitate the removal of the support. Thus, the posterior foot of this prosthetic assembly provides a stable means of bearing on the calcaneus, but, even in the form of a screw inserted into cement, this foot does not totally block the articulation between the astragalus and the calcaneus in an effective manner.

WO-A-01/30264 and US-A-2005/124995 for their part disclose a prosthetic ankle assembly comprising an astragalocalcanean rod that is introduced into a cavity formed beforehand through the astragalus and in the upper part of the calcaneus. This rod is used to anchor an astragalar plate, which is fitted in place and fixed to the astragalocalcanean rod after the rod has been placed in the aforementioned bone cavity. Hence, this rod does not provide any effective blocking of the articulation between the calcaneus and the astragalus so that, in order to limit the relative movements between these two bones, additional screws are fitted between the astragalar plate and the astragalocalcanean rod, in order to stabilize the position of the latter.

The present invention is directed to a method and apparatus that blocks the articulation between the calcaneus and the astragalus and to re-establish an articular capacity between the astragalus and the tibia of a patient, all in a single intervention.

To this end, the subject matter of the invention is a prosthetic ankle assembly, comprising an astragalar component which forms part of an ankle joint prosthesis and which is designed to be fixed to the astragalus of a patient. An astragalocalcanean rod of which a first longitudinal end is designed to be fixed to the astragalar component, by its shape complementing that of a dedicated part of the astragalar component. The dedicated part is provided on a lower side of this component intended to be directed towards an upper face of the astragalus. The astragalocalcanean rod is equipped, at its second longitudinal end, with an engagement feature for osseous engagement of the calcaneus of the patient, so as to approximate and thereby compress the calcaneus against the astragalus when the first end of the rod is fixed to the dedicated part of the astragalar component.

When the prosthetic assembly according to the invention is implanted, its astragalar component permits articular movements between the astragalus and the tibia of a patient, especially by being connected to a prosthetic tibial component fixed to the tibia, and to a prosthetic bearing interposed between the astragalar and tibial components. On the other hand, the astragalocalcanean rod blocks the articulation between the calcaneus and the astragalus, by these two bones being compressed against each other. In practice, this bone compression is obtained by fixing the first end of the rod in the astragalar component, which engages the second end of the rod directly with the calcaneus. For this purpose, a fixation means and the engagement means provided respectively at the ends of the rod are structurally configured to obtain a progressive compression effect between the calcaneus and the astragalus as the second end of the rod advances into the calcaneus, whilst the first end is coupled to the dedicated part of the astragalar component resting on the astragalus.

In practice, the rod is introduced from a lower face of the calcaneus into an astragalocalcanean channel that has been drilled beforehand through the calcaneus and the astragalus and that opens out on the dedicated part of the astragalar component when the latter is placed on an upper face of the astragalus. Thus, advantageously in a single surgical intervention, the astragalar component and the astragalocalcanean rod are implanted by being coupled to each other during the intervention, while the rod passes right through the calcaneus and the astragalus, in order to compress them and thereby immobilize them against each other. In other words, the operation of arthroplasty between the astragalus and the tibia and the operation of arthrodesis between the astragalus and the calcaneus are performed during the same surgical intervention, which limits the surgical risks faced by the patient and which allows the surgeon to use the same surgical routes for the two operations.

In addition, the astragalocalcanean rod ensures immobilization of the astragalar component relative to the astragalus and to the calcaneus, which improves the fit of the astragalar component. Moreover, in the event of revision of the prosthetic assembly according to the invention, the bearing action on the calcaneus is safe and reliable in the sense that this bone is firmly fused to the astragalus.

According to other advantageous characteristics of this prosthetic ankle assembly, taken either singly or in all the technically possible combinations:

The invention also relates to a surgical method for implanting a prosthetic ankle assembly, the assembly comprising an astragalar component of an ankle joint prosthesis, and an astragalocalcanean rod of which a first of its two longitudinal ends is designed to be fixed to the astragalar component, by its shape complementing that of a dedicated part of the component, and of which the second longitudinal end is equipped with an engagement means of osseous engagement. The method of implantation comprising steps of:

preparing an upper face of an astragalus to receive an astragalar component;

forming an astragalocalcanean channel between an the upper face of the astragalus and a lower face of a calcaneus;

locating the astragalar component on the upper face of the astragalus;

inserting an astragalocalcanean rod into the astragalocalcanean channel from the lower face of the calcaneus;

engaging a first end of the astragalo-calanean rod with the astragalar component and a second end of the astragalo-calanean rod with a lower region of the calcaneus; and

adjusting a distance between the second end of the astragalocalcanean rod relative to a lower surface of the astragalar component to adjustably compresses the calcaneus against the astragalus.

This method makes it possible, in a single surgical intervention, to implant a prosthetic ankle assembly of the kind defined above, in order to permit arthrodesis of the calcaneus and astragalus and, at the same time, arthroplasty between the astragalus and the tibia of a patient. Arthrodesis refers to a surgical fixation of a joint, ultimately resulting in bone fusion. Basically, the procedure is artificially induced ankylosis performed to relieve pain or provide support in a diseased or injured joint.

According to an advantageous embodiment of this method, during step i), a substantially cylindrical recess is hollowed out in the upper face of the astragalus in order to receive a hollow bone-anchoring stub which is provided on the astragalar component and in which the dedicated part is arranged, and, during step ii), the astragalocalcanean channel is drilled from the upper face of the astragalus, in a continuation of the recess.

In this case, to make matters easier, a drill bushing is used to drill the astragalocalcanean channel, by resting this bushing in the recess formed during step i).

Advantageously, in order to promote the fusion of the calcaneus and the astragalus, the method comprises, before step ii), an additional surgical step during which bone substance is inserted between the astragalus and the calcaneus by arthroscopy.

Moreover, after consolidation of the arthrodesis of the calcaneus and astragalus, the method advantageously comprises a postoperative step in which the astragalocalcanean rod is withdrawn by disconnecting its first end from the dedicated part of the astragalar component.

The invention can be better understood on reading the following description given purely by way of example and made with reference to the drawings, in which:

FIG. 1 is a front view, in partial cross section, of a prosthetic ankle assembly implanted in the left ankle of a patient in accordance with an embodiment of the present invention;

FIG. 2 is an exploded side view, according to the arrow II indicated in FIG. 1, of part of the prosthetic assembly, depicted without the bones of the ankle;

FIGS. 3A and 3B are schematic cross sections, along the line III-IIi in FIG. 1, illustrating two successive steps in the implantation of the prosthetic assembly; and

FIG. 4 is a view similar to FIG. 3B, illustrating a variant of the prosthetic ankle assembly in accordance with an embodiment of the present invention.

FIG. 1 shows schematically the lower ends of a tibia T and of a peroneal bone P or fibula of a human being, and also the corresponding astragalus A and calcaneus C, thereby illustrating the constituent bones of the left ankle of a patient. FIG. 1 also shows a prosthetic ankle assembly 1 comprising four separate components implanted in the ankle of the patient, namely a tibial component 10, an astragalar component 20, a prosthetic bearing 30, interposed between the tibial and astragalar components, and an astragalocalcanean rod 40. In FIG. 1, only the bearing 30 is shown in frontal section, whereas the broken lines are used to symbolize the contours of the components concealed by bone substance.

For convenience, the description that follows relates to the bones of the ankle in their anatomical position, that is to say the terms “posterior” or “rear”, “anterior” or “front”, “upper”, “lower”, etc., are to be understood in relation to the ankle of the patient when standing upright on a substantially horizontal surface.

The tibial component 10 comprises a plate 11 which is attached in a fixed manner to the lower end of the tibia T. For this purpose, the plate 11, on its upper face 11A, is joined, via a sagittal fin 12, to a hollow bone-anchoring stub 13. Additional and/or alternative means for anchoring the plate 11 are conceivable, provided that they effectively immobilize the tibial component at the lower end of the tibia T.

On its lower side, the plate 11 delimits a plane surface 11B intended to form a sliding support for the plane upper surface 30A of the bearing 30.

The astragalar component 20 comprises a main block 21 attached in a fixed manner to the upper end of the astragalus A. For this purpose, the block 21 is made integral with a hollow bone-anchoring stub 22 that extends downwards from the lower side 21B of the block 21, as is represented by broken lines in FIG. 1 and as can be clearly seen in FIG. 2.

On its upper side, the block 21 delimits an articular surface 21A intended to cooperate with a matching articular surface 30B delimited by the lower side of the bearing 30. In sagittal section, the surface 21A has an arched profile, with its concavity directed downwards, as can be seen in FIG. 2. The articular surfaces 21A and 30B are thus designed to slide against each other along this curved profile, in what is an essentially antero-posterior direction. Advantageously, these surfaces 21A and 30B between them permit a medio-lateral clearance, which combines with the curved movement of sliding in the antero-posterior direction.

As is shown in FIG. 2, the rod 40 extends lengthwise about a completely vertical central axis X-X. This rod comprises, in succession along its length, a first threaded end 41, an externally smooth and regular part 42, and a second threaded end 43. The end 41, the regular part 42 and the end 43 are successively of increasing size, such that, on the one hand, the maximum diameter d41 of the external thread 41A of the end 41, that is to say the maximum transverse dimension of this end 41 in the area of the crest of the thread, is less than or equal to the external diameter of the part 42, and, on the other hand, the maximum diameter d43 of the external thread 43A of the end 43, that is to say the maximum transverse dimension of this end 43 at the crest of the thread 43A, is strictly greater than the diameter of the regular part 42.

The external thread 41A of the end 41 is designed to be received by screwing into a complementary internal thread 22A which, as is indicated by broken lines in FIG. 2, is delimited by the inner face of the hollow stub 22 and is preferably centred on the central longitudinal axis of this stub.

At its end 43, the rod 40 delimits a recess 44 which is substantially centred on the axis X-X and opens out axially downwards to the outside, as is indicated by broken lines in FIG. 2. This recess 44 has a transverse profile 44A, for example of square shape, intended to cooperate with a complementary tool for driving the rod 40 in rotation on itself about the axis X-X.

A surgical method for implanting the prosthetic ankle assembly 1 will now be described.

In a first step, the bones of the patient's ankle have to be prepared. For this purpose, the surgeon uses cutting means (not shown) in such a way as to, on the one hand, resect the lower end of the tibia T and form a substantially plane surface T1, and, on the other hand, resect the upper end of the astragalus A and form a multi-facet surface A1 comprising two main surfaces which are inclined relative to each other, as can be seen in FIG. 3A. In the face A1, a cylindrical recess A2, indicated by broken lines in FIG. 3A, is hollowed out in an overall vertical direction, for example by means of a milling cutter. This recess A2 thus defines a central longitudinal axis A3.

At this stage of the surgical intervention, the upper face A1 of the astragalus A is in a configuration suitable for receiving the astragalar component 20, it being understood that the recess A2 is made substantially complementary to the stub 22 in order to anchor this component 20 on the astragalus. However, before fitting the astragalar component 20 in place, the surgeon drills through the astragalus A and calcaneus C, from the upper face A1 of the astragalus to a lower face C1 of the calcaneus, in such a way as to form an astragalocalcanean channel AC indicated by broken lines in FIG. 3A. This channel AC is drilled in a rectilinear continuation of the recess A2, by being substantially centred on the axis A3. To do this, the surgeon advantageously uses a drill bushing 50, indicated partially and schematically in FIG. 3A. This bushing 50 has a tubular shape designed to be received in a substantially complementary manner in the recess A2, substantially coaxial to the recess. In this way, the bushing 50 bears in the recess A2 in such a way as to guide the introduction and advance of a drill bit successively through the astragalus and the calcaneus, as is indicated by the arrow 51 in FIG. 3A. The surgeon thus drills the astragalocalcanean channel AC rapidly and with precision, using ancillary equipment traditional in the field of orthopaedic surgery.

After the astragalocalcanean channel AC has been drilled, the surgeon places the astragalar component 20 on the upper face A1 of the astragalus A and places the astragalocalcanean rod 40 in the channel AC. More precisely, the rod 40 is introduced into the channel AC from the lower face C1 of the calcaneus, with its end 41 directed upwards. The internal diameter of the channel AC is made substantially equal to the external diameter of the regular part 42, such that the rod is easily advanced through the channel in an upward translational movement and parallel to the axis A3, until the end 41 reaches the point where the channel AC opens into the recess A2. As this recess is occupied by the stub 22, advancing the rod 40 requires the latter to be driven in rotation on itself about the axis X-X, in such a way as to screw the external thread 41A into the internal thread 22A, as is indicated by the arrow 60. In practice, the rod is driven in rotation by means of a tool whose head, indicated only by broken lines and reference number 61 in FIG. 3B, is engaged with the profile 44A in the recess 44.

It will be understood that, by giving the rod 40 a suitable lengthwise dimension, the screwing of the end 41 into the stub 22 is accompanied by the screwing of the end 43 into the calcaneus, the external thread 43A engaging directly in the bone substance of the calcaneus at the point where the channel AC opens out on the lower face C1 of the calcaneus. In other words, the rod 40 has a length substantially equal to that of the astragalocalcanean channel AC, such that the rod can extend through the astragalus and the calcaneus with its end 41 in the area of the upper face A1 of the astragalus and with its end 43 in the area of the lower face C1 of the calcaneus.

The twin screwing of the external threads 41A and 43A causes the astragalus A and the calcaneus C to be gradually approximated to each other, thereby compressing these two bones against each other in the area of their respective contacting surfaces. It will be appreciated that the structural features of these external threads, in particular their respective pitch, are chosen so as to achieve compression values that are sufficient to efficiently block the astragalus and the calcaneus against each other, without generating excessive stress in the bones.

The other components of the prosthetic assembly 1 are implanted in parallel with this. The tibial component 10 is attached and immobilized on the lower end of the tibia T, with its plate 11 resting flat against the face T1, then the prosthetic bearing 30 is attached between the components 10 and 20. The assembly 1 is then in the implantation configuration illustrated in FIG. 1 and the surgical intervention is concluded.

After consolidation of the arthrodesis between the astragalus A and the calcaneus C, which generally takes between six and twelve months, the astragalocalcanean rod 40 can be withdrawn by unscrewing its ends 41 and 43. The surgeon then advantageously uses the profile 44A by introducing a suitable disconnecting tool into the latter. To promote and accelerate this arthrodesis, bone substance can advantageously be inserted between the astragalus and the calcaneus before implantation of the prosthetic assembly 1. Before jointly drilling right through the astragalus A and the calcaneus C, an arthroscope is inserted into the junction area between the astragalus and the calcaneus in order to place bone substance there.

FIG. 4 shows a variant of the astragalocalcanean rod 40, which differs from the embodiment considered in FIGS. 1 to 3B only at its lower end 43. The external thread 43A is cancelled, so that the external surface of the end 43 is smooth and extends in the straight continuation of the external surface of the regular part 42, except at its end area that forms a bulge 43B radially protruding externally from the rest of this surface. Unlike the embodiment of FIGS. 1 to 3B, the end 43 of the rod 40 of FIG. 4 is associated with a ring 45 externally surrounding this end. This ring has an internal diameter that is both substantially equal or greater than the external diameter of end 43, except at its end bulge 43B, and lower than the maximum external diameter of this bulge. In practice, the ring 45 is pulled around the rod 40 by being introduced from upper end 41 while the rod is still not introduced into the astragalocalcanean channel AC.

When the external thread 41A of the end 41 of the rod 40 is screwed into internal thread 22A of the astragalar component 20, by driving in rotation the rod by means of the tool whose head is engaged within the recess 44, the ring 45 is thus interposed between the lower face C1 of the calcaneus C and the end bulge 43B of the rod until this bulge drives the ring 45 in a pressed contact against the face C1 of the calcaneus. Thus, the ring 45 transmits and distributes the clamping stress on the face C1 of the calcaneus, in the same way as a washer. The calcaneus is thus compressed against the astragalus A, until to efficiently block the astragalus and the calcaneus against each other.

A radial clearance between the internal face of the ring 45 and the external face of the end 43, above its end bulge 43B, allows adjustment of the position of the ring with respect to the rod during its pressing against the calcaneus C. Thus, this relative mobility between the ring and the end 43 compensates for a potential misalignment between the central axis of the ring and the axis X-X of the rod.

According to a not shown variant, the ring 45 is fixedly secured at the lower end 43 of the rod 40, for example being directly integral with the rod. In this case, in order to increase the pressing surface of this fixed ring against the lower face C1 of the calcaneus C during the screwing of the external thread 41A into the astragalar component 20, this calcanean face C1 is, if necessary, beforehand wrought, so that a substantially plane surface, inscribed in a plane substantially perpendicular to the axis A3 of the astragalocalcanean channel AC, is delimitated around the point where this channel opens into the recess A2.

Configurations other than the external thread 43A and the ring 45 can be provided at the lower end 43 of the astragalocalcanean rod 40 in order to engage the calcaneus C and compress it against the astragalus A when screwing the upper end 41 into the astragalar component 20. For example, the lower end 43 can have an outer surface in the shape of a truncated cone or flare widening towards the bottom.

Other variations on the prosthetic ankle assembly 1 and on the implantation method that have been described above are also conceivable. By way of example:

The central axis of the internal thread 22A can be offset from the central axis of the stub 22, the drill bushing 50 then being provided with a similar offset in order to drill the astragalocalcanean channel AC in the possibly inclined continuation of the recess A2;

The structure of internal thread 22A and external thread 41A can be reversed, such that the end 41 of the rod 40 forms an internal thread that can be screwed around an external thread formed in the stub 22, for example delimited by a central pin internal to this stub; more generally, other types of means permitting coupling through complementary shapes between the upper end of the rod 40 and the lower side 21B of the astragalar component 20 are conceivable, provided that these means lead to engagement of the lower end of the rod with the calcaneus C in order to compress the latter against the astragalus A; thus, a coupling by means of a bayonet structure is possible, and also coupling structures with stressing obtained exclusively through rectilinear translation;

By virtue of the fact that they bear slidingly on each other at their surfaces 11A and 30A, the tibial component 10 and the bearing 30 are movable relative to each other, which generally leads the ankle prosthesis comprising the elements 10, 20 and 30 to be designated as a prosthesis with a “movable bearing”; however, the astragalar component 20 can alternatively be joined to a “fixed” bearing, that is to say a bearing placed fixedly against a tibial component;

The astragalar component 20 and the astragalocalcanean rod 40 are not necessarily to be used jointly with a tibial component and a prosthetic bearing such as the elements 10 and 30; the astragalar component can in fact be made to cooperate in an articulated manner directly with the lower anatomical end of the tibia T if the latter has sufficient articular capacity; the prosthetic ankle assembly can then be designated as a partial prosthetic assembly, whereas the prosthetic assembly 1 in FIG. 1 is to be considered as a total prosthetic assembly; and/or

If necessary, the fixation of the astragalar component 20 to the astragalus A can be strengthened by additional means.

Patents and patent applications disclosed herein, including those cited in the Background of the Invention, are hereby incorporated by reference. Other embodiments of the invention are possible. It is to be understood that the above description is intended to be illustrative, and not restrictive. Many other embodiments will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.

In practice, the rod is introduced from a lower face of the calcaneus into an astragalocalcanean channel that has been drilled beforehand through the calcaneus and the astragalus and that opens out on the dedicated part of the astragalar component when the latter is placed on an upper face of the astragalus. Thus, advantageously in a single surgical intervention, the astragalar component and the astragalocalcanean rod are implanted by being coupled to each other during the intervention, while the rod passes right through the calcaneus and the astragalus, in order to compress them and thereby immobilize them against each other. In other words, the operation of arthroplasty between the astragalus and the tibia and the operation of arthrodesis between the astragalus and the calcaneus are performed during the same surgical intervention, which limits the surgical risks faced by the patient and which allows the surgeon to use the same surgical routes for the two operations.

Weber, Michael, Ferrari, Irene

Patent Priority Assignee Title
Patent Priority Assignee Title
2511051,
4175555, Feb 24 1977 Interfix Limited Bone screw
5217462, Mar 05 1991 HOWMEDICA OSTEONICS CORP Screw and driver
5545228, Oct 23 1992 Altiva Corporation Offset bone bolt
5827285, Dec 12 1996 ORTHOPEDIC DESIGNS, INC Multipiece interfragmentary fixation assembly
6053920, Oct 12 1995 Cochlear Bone Anchored Solutions AB Holder element for implantation in bone tissue
6136032, Sep 04 1998 European Foot Platform Implant for correcting flat foot condition
6168631, Aug 29 1997 INTEGRA LIFESCIENCES CORPORATION Subtalar implant system and method for insertion and removal
6183519, Mar 10 1997 INTEGRA LIFESCIENCES CORPORATION Ankle prosthesis
6413260, Aug 17 1999 HOWMEDICA OSTEONICS CORP Bone connector system
6458134, Aug 17 1999 HOWMEDICA OSTEONICS CORP Bone connector system with anti-rotational feature
6508841, Nov 01 1993 Biomet Manufacturing, LLC Method and apparatus for segmental bone replacement
6517543, Aug 17 1999 HOWMEDICA OSTEONICS CORP Bone connector system with anti-rotational feature
6579293, Aug 02 2000 ARTHRODESIS TECHNOLOGY LLC Intramedullary rod with interlocking oblique screw for tibio-calcaneal arthrodesis
6648890, Nov 12 1996 INTERVENTIONAL SPINE, INC Bone fixation system with radially extendable anchor
6663669, Oct 22 1999 INBONE TECHNOLOGIES, INC Ankle replacement system
6860902, Oct 22 1999 INBONE TECHNOLOGIES, INC Ankle replacement system
6875236, Oct 22 1999 INBONE TECHNOLOGIES, INC Intramedullary guidance systems and methods for installing ankle replacement prostheses
6926739, May 13 1999 STRYKER EUROPEAN HOLDINGS III, LLC Prosthesis device for human articulations, in particular for the ankle articulation
7033398, Feb 19 2004 GRAHAM MEDICAL TECHNOLOGIES, LLC Sinus tarsi implant
7314488, Oct 22 1999 INBONE TECHNOLOGIES, INC Intramedullary guidance systems and methods for installing ankle replacement prostheses
8048164, Oct 22 1999 INBONE TECHNOLOGIES, INC Ankle replacement system
20050107791,
20050177243,
20060015105,
20070129808,
20070288097,
20090082875,
20100010490,
20110054473,
20120165701,
20150057665,
FR2220235,
WO130264,
WO9215257,
/
Executed onAssignorAssigneeConveyanceFrameReelDoc
Oct 12 2007Tornier(assignment on the face of the patent)
Date Maintenance Fee Events


Date Maintenance Schedule
Aug 11 20184 years fee payment window open
Feb 11 20196 months grace period start (w surcharge)
Aug 11 2019patent expiry (for year 4)
Aug 11 20212 years to revive unintentionally abandoned end. (for year 4)
Aug 11 20228 years fee payment window open
Feb 11 20236 months grace period start (w surcharge)
Aug 11 2023patent expiry (for year 8)
Aug 11 20252 years to revive unintentionally abandoned end. (for year 8)
Aug 11 202612 years fee payment window open
Feb 11 20276 months grace period start (w surcharge)
Aug 11 2027patent expiry (for year 12)
Aug 11 20292 years to revive unintentionally abandoned end. (for year 12)