Prosthesis, and Associated Methods of Implanting A Joint Replacement and Implanting A Prosthetic Bone Joint Replacement as For Ankle Replacement With Press-Fit Tibia Component, Spherical Articulation and Method of Implantation

Abstract

Prosthetic ankle replacements, prostheses, and associated methods of implanting prosthetic ankle and other joint replacements. In one form, a tibia stem has a geometry to facilitate implant installation while providing means to transfer load over a larger surface area through a “press-fit,” “scratch-fit” or “cortical fit”, thus lowering the contact stresses at the tibia-metal implant interface. The design and its implantation procedure also address minimization of misalignment. A talus element presents a partial-hemispherical surface; a tibial element which is to be affixed within the tibia, having an elongated stem part which extends into and within a canal of the tibial inner cortex, an intermediate body part which smoothly widens in radius toward an end which is a base to the tibial element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the talus element with a plastic cap between the two.

Claims

1. A prosthetic ankle replacement comprising: a talus element which is to be affixed to the surface of the talus, the talus element presenting a partial-hemispherical surface; a tibial element which is to be affixed within the tibia, the tibial element having an elongated stem part which extends into and within a canal of the tibial inner cortex, an intermediate body part which smoothly widens in radius toward an end which is a base to the tibial element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the talus element; the tibial element being adapted to conform to a shape formed in the tibia so as to be press fit into the tibial canal with a designed axial load.

2. The prosthetic ankle replacement of claim 1, further including a hard plastic cap component which provides an interface between the talus element partial-hemispherical surface and the tibial base concavity.

3. The prosthetic ankle replacement of claim 2, wherein the hard plastic cap is formed as a hemispherical dome and further including a projection at a periphery to the cap to limit the outward flow of synovial fluid exiting a space between the plastic cap and metal talus component in order to maintain a cushioning boundary layer under dynamic impact loads.

4. A method for implantation of a prosthetic ankle replacement, comprising: providing a prosthesis of a talus element which is to be affixed to the prepared surface of the talus, the talus element presenting a partial-hemispherical surface; a tibial element which is to be affixed within the tibia, the tibial element having an elongated stem part which extends into and within a canal of the tibial inner cortex, an intermediate body part which smoothly widens in radius toward an end which is a base to the tibial element, the base having a concavity formed therein shaped to match the convex surface of the hemispherical hard plastic cap while the partial-hemispherical surface of the talus element matches the concave surface of the hemispherical hard plastic cap; cutting an end of the tibia to expose the inner tibial canal, and successively widening the canal through removal of intramedullary bone therein so as to match the external shape of the tibial element; affixing the talus element to the prepared surface of the talus so as to present the partial-hemispherical surface toward the concavity of the tibial element; press fitting the tibial element into the tibial canal with a designed axial load; and seating the talus element within the concavity of the hard plastic cap while seating the hard plastic cap within the concavity of the tibial element.

5. The prosthetic ankle replacement of claim 1, wherein at least one of the tibial and talus elements are made using a sintering process or an additive manufacturing layer wise build process to have connected porosity from channels extending from an exterior of the element and into the element to allow diffusion of fluid to function like a bone under transient dynamic loading conditions.

6. A prosthetic for implantation in a joint of a human or animal comprising: a first element which is to be affixed to the surface of a first end of a joint, the first element presenting a partial-hemispherical surface; and a second element which is to be affixed within an second end of the joint opposed to the first end, the second element having an elongated stem part which extends into and within a canal of the second end of the joint, an intermediate body part which widens in radius toward an end which is a base to the second element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the first element; the second element being adapted to conform to a shape formed in the canal so as to be press fit into the canal.

7. The prosthetic of claim 6, further including a hard plastic cap component which provides an interface between the first element partial-hemispherical surface and the second element base concavity.

8. The prosthetic of claim 6 wherein the first element is adapted for a talus element, and the second element is adapted for a tibial element which is received within a canal of a tibial inner cortex.

9. The prosthetic of claim 8, further including a hard plastic cap component which provides an interface between a talus element partial-hemispherical surface and a tibial base concavity.

10. A prosthetic for implantation in a joint of a human or animal, the joint including a bone having a cortical canal, comprising: a stem part which has a long axis and a radial aspect, the stem part having a distal end which extends into and within the canal of the canal in use, an intermediate body part which widens in radius toward a proximal end which is a base to the stem part, the stem part being adapted to present a stem exterior that conforms to a shape formed in the canal yielding an open canal interior sidewall which is matched to the radius of the stem, so as to be press fit into the canal and held in place through contact between the canal interior sidewall and the stem exterior.

11. The prosthetic of claim 10, wherein the stem part is affixed without any use of cement or other mechanical fixation.

12. The prosthetic of claim 10, further including a first element which is to be affixed to the surface of a first end of a joint, the first element presenting a partial-hemispherical surface; the intermediate body part which widens in radius toward an end which is the base wherein the base has a concavity formed therein shaped to match the partial-hemispherical surface of the first element.

13. The prosthetic of claim 10, further including a hard plastic cap component which provides an interface between the first element partial-hemispherical surface and the base concavity.

14. The prosthetic of claim 13, wherein the first element is adapted for a talus element, and the stem part is adapted for a tibial element which is received within a canal of a tibial inner cortex.

15. The prosthetic of claim 14, further including a hard plastic cap component which provides an interface between a talus element partial-hemispherical surface and a tibial base concavity.

16. A prosthetic ankle replacement comprising: a talus element which is to be affixed to the surface of the talus, the talus element presenting a partial-hemispherical surface; and a tibial element which is to be affixed within the tibia, the tibial element having an elongated stem part which extends into and within a canal of the tibial inner cortex, an intermediate body part which widens in radius toward an end which is a base to the tibial element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the talus element; the tibial element being adapted to conform to a shape formed within the tibia presenting tibial cortex canal sidewalls so as to be press fit into the tibial cortex canal and affixed in place without further means of fixation.

17. The prosthetic ankle replacement of claim 16, further including a hard plastic cap component which provides an interface between the talus element partial-hemispherical surface and the tibial base concavity.

18. A method for implantation of a prosthetic bone joint replacement, comprising: providing a prosthesis of a first element which is to be affixed to the surface of an end of a first bone of the joint, the first element presenting a partial-hemispherical surface; a second element which is to be affixed within a cortical canal of a second bone of the joint, the second element having an elongated stem part which extends into and within a canal of the cortical canal, an intermediate body part which widens in radius toward an end which is a base to the second element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the first element; cutting an end of the second bone to expose the inner canal, and successively widening the canal through removal of intramedullary bone therein so as to match the external shape of the second element; affixing the first element to the surface of the first bone so as to present the partial-hemispherical surface toward the concavity of the second element; press fitting the second element into the canal into tight engagement with a sidewall forming the interior of the canal; and seating the first element within the concavity of the second element.

19. The method of claim 18, wherein the second element is affixed without any use of cement or other mechanical fixation.

20. The method of claim 19, further including providing a hard plastic cap component which provides an interface between the first element partial-hemispherical surface and the base concavity.

21. The method of claim 20, wherein the first element is adapted for a talus element, and the stem part is adapted for a tibial element which is received within a canal of a tibial inner cortex.

22. The method of claim 21, further including a hard plastic cap component which provides an interface between a talus element partial-hemispherical surface and a tibial base concavity.

23. The prosthetic ankle replacement of claim 16, wherein the tibial element is made as a single piece.

24. The prosthetic of claim 10, wherein the stem part made as a single piece.

25. The prosthetic of claim 6, wherein the second element is made as a single piece.

26. The prosthetic ankle replacement of claim 1, wherein the tibial element is made as a single piece.

27. The method of claim 4, wherein the tibial element is made as a single piece.

28. The method of claim 18, wherein the second element is made as a single piece.

29. The prosthetic ankle replacement of claim 16, wherein the talus element further includes projections extending outwardly from the talus element, the projections adapted to limit inversion and eversion motion of the prosthesis.

30. The prosthetic of claim 12, wherein the first element further includes projections extending outwardly from the talus element.

31. A prosthetic ankle replacement comprising: a talus element which is to be affixed to the surface of the talus, the talus element presenting an articulation upper interface surface; and a tibial element which is to be affixed within the tibia, the tibial element having an elongated stem part which extends into and within a canal of the tibial inner cortex, an intermediate body part which widens in radius toward an end which is a base to the tibial element, the base having a shape formed thereon shaped to interface with the articulation upper surface of the talus element; the tibial element being adapted to conform to a shape formed within the tibia presenting tibial cortex canal sidewalls so as to be press fit into the tibial cortex canal and affixed in place through such press fit.

32. The prosthetic ankle replacement of claim 31, wherein the tibial element is affixed without further means of fixation.

33. The prosthetic ankle replacement of claim 31, wherein the tibial element base has a concavity formed therein shaped to match a partial-hemispherical surface of the talus element.

34. The prosthetic ankle replacement of claim 31, wherein the articulation upper interface surface is a hard plastic component provided on the talus element upon which the tibial element is seated.

35. The prosthetic ankle replacement of claim 31, wherein the talus element further includes projections extending outwardly from the talus element, the projections adapted to limit inversion and eversion motion of the prosthesis.

36. A prosthetic ankle replacement comprising: a talus element configured to be affixed to the surface of the talus, the talus element presenting a partial-hemispherical surface; and a tibial element configured to be affixed within the tibia, wherein the tibial element comprises an elongated stem part sized and shaped to extend into and within a canal of a tibial inner cortex, an intermediate body part which smoothly widens in radius toward an end which is a base to the tibial element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the talus element; wherein the tibial element is adapted to conform to a shape formed in the tibia so as to be press fit into a tibial canal of the tibia with a designed axial load.

37. The prosthetic ankle replacement of claim 36, further comprising: a hard plastic cap component which provides an interface between the partial-hemispherical surface of the talus element and the concavity formed in the base of the tibial element.

38. The prosthetic ankle replacement of claim 37, wherein the hard plastic cap component is formed as a hemispherical dome and further comprises a projection at a periphery of the hard plastic cap component to limit the outward flow of synovial fluid exiting a space between the hard plastic cap component and the talus element in order to maintain a cushioning boundary layer under dynamic impact loads, and wherein the talus is metal.

39. The prosthetic ankle replacement of claim 36, wherein the tibial element is made as a single piece.

40. A method for implanting a prosthetic ankle replacement, the method comprising: providing prosthetic ankle replacement including a talus element, a hemispherical hard plastic cap, and a tibial element, wherein the talus element is configured to be affixed to a prepared surface of the talus, the talus element presenting a partial-hemispherical surface that forms a convex surface, and wherein the tibial element is configured to be affixed within the tibia, the tibial element having an elongated stem part which is configured to extend into and within a tibial canal of the tibial inner cortex, an intermediate body part which smoothly widens in radius toward an end which is a base to the tibial element, the base having a concavity formed therein shaped to match a convex surface of the hemispherical hard plastic cap while the partial-hemispherical surface of the talus element matches a concave surface of the hemispherical hard plastic cap; cutting an end of the tibia to expose the tibial canal, and successively widening the tibial canal through removal of intramedullary bone therein so as to match an external shape of the tibial element; affixing the talus element to the prepared surface of the talus so as to present the partial-hemispherical surface toward the concavity of the tibial element; press fitting the tibial element into the tibial canal with a designed axial load; and seating the talus element within the concave surface of the hard plastic cap while seating the hard plastic cap within the concavity of the tibial element.

41. The method of claim 40, wherein the tibial element is made as a single piece.

42. A prosthetic ankle replacement comprising: a talus element to be affixed to a surface of a talus, the talus element presenting a partial-hemispherical surface; and a tibial element to be affixed within a tibia, the tibial element having an elongated stem part configured to extend into and within a canal of an inner cortex of the tibia, an intermediate body part that widens in radius toward an end which forms a base of the tibial element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the talus element; the tibial element being adapted to conform to a shape formed within the tibia presenting canal sidewalls of the canal of the inner cortex of the tibia so as to be press fit into the canal of the inner cortex and affixed in place without further means of fixation.

43. The prosthetic ankle replacement of claim 42, further including a hard plastic cap component which provides an interface between the partial-hemispherical surface of the talus element and the concavity of the base of the tibial element.

44. The prosthetic ankle replacement of claim 42, wherein the tibial element is made as a single piece.

45. A method for implantation of a prosthetic bone joint replacement, the method comprising: providing a prosthesis comprising: a first element which is to be affixed to the surface of an end of a first bone of the joint, the first element presenting a partial-hemispherical surface; and a second element which is to be affixed within a cortical canal of a second bone of the joint, the second element having an elongated stem part which extends into and within the cortical canal, an intermediate body part which widens in radius toward an end which forms a base to the second element, the base having a concavity formed therein shaped to match the partial-hemispherical surface of the first element; cutting an end of the second bone to expose the cortical canal; successively widening the cortical canal through removal of intramedullary bone therein so as to match an external shape of the second element; press fitting the second element into the cortical canal into tight engagement with a sidewall forming an interior of the cortical canal; affixing the first element to the surface of the first bone so as to present the partial-hemispherical surface toward the concavity of the second element; and seating the first element within the concavity of the second element.

46. The method of claim 45, wherein the second element is affixed without any use of cement or other mechanical fixation.

47. The method of claim 46, further including providing a hard plastic cap component which provides an interface between the partial-hemispherical surface of the first element and the concavity of the base.

48. The method of claim 47, wherein the first element forms a talus element, and the stem part forms a tibial element which is received within the cortical canal of a tibial inner cortex.

49. The method of claim 48, wherein the hard plastic cap component provides an interface between the partial-hemispherical surface of the talus element and the concavity of the base.

50. The method of claim 49, wherein the second element is made as a single piece.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0077] FIGS. 1A and 1B are an anterior and lateral views, respectively, of the bones making up a human ankle. FIG. 1A shows normal ankle joint bones, viewing the right ankle from the front (anterior view). FIG. 1B shows the normal ankle joint bones, viewing the right ankle from the side (lateral view).

[0078] FIG. 2 is a schematic axial cross-sectional view through the tibia.

[0079] FIGS. 3A and 3B are anterior and lateral schematic views of a typical standard prior art TAR design.

[0080] FIG. 4A is a lateral schematic view of a prior art INBONE II TAR system.

[0081] FIG. 4B is a lateral schematic view of a prior art Trabecular Metal TAR design.

[0082] FIG. 5A is a schematic anterior view of cuts made to the tibial end to receive a standard conventional TAR tibial implant component.

[0083] FIG. 5B is a cross sectional schematic view illustrating a distal tibia cut of a standard conventional TAR.

[0084] FIG. 6A is a schematic anterior view of an embodiment of a total replacement ankle according to nonlimiting aspects of the present invention.

[0085] FIG. 6B is a lateral view of the TAR shown in FIG. 6A.

[0086] FIG. 6C is an enlarged cross-sectional view of the TAR of FIG. 6A demonstrating articulation between components of the TAR at the metal talus and plastic dome interface.

[0087] FIGS. 7A-7Q illustrate various steps in a procedure for implanting the prostheses of FIG. 6A in a human ankle joint to form a total ankle replacement.

[0088] FIG. 7A is an anterior view of an ankle with the tibial inner cortex and tibial outer cortex shown prior to being altered for implantation of a TAR.

[0089] FIG. 7B is an anterior view of the ankle that illustrates large drill holes used to create an anterior cortex window.

[0090] FIG. 7C is a lateral view of the ankle that illustrates the drill paths from the lateral view.

[0091] FIG. 7D is a lateral view of the ankle that illustrates a curved awl used to initially penetrate the tibial canal.

[0092] FIG. 7E is a lateral view of the ankle that shows the curved awl as used to create a path for broaches in the tibial canal.

[0093] FIG. 7F is a lateral view of the ankle that illustrates how a small broach is placed in the tibial canal as part of a sequentially larger broaching process.

[0094] FIG. 7G is a lateral view of the ankle that shows a larger broach placed in the tibial canal with press-fit.

[0095] FIG. 7H is a lateral view of the ankle that schematically shows a jig is attached to the final broach to allow for burr or saw resection of the distal tibia medially and the distal fibula laterally.

[0096] FIG. 7I is an anterior view of the ankle that illustrates the way a cutting tool would be proposed to be used to create distal tibia medial resection and distal fibula resection.

[0097] FIG. 7J is an anterior view of the ankle that illustrates the tibia after resection of bone.

[0098] FIG. 7K is a schematic lateral view of the tibia and the talus after resection of bone from both.

[0099] FIG. 7L is a schematic lateral view of the tibia and the talus that illustrates plantarflexion of the talus to provide space for the tibial component.

[0100] FIG. 7M is a schematic lateral view of the tibia and the talus that illustrates an initial insertion of a tibial component in the tibia according to a nonlimiting example of the present invention.

[0101] FIG. 7N is a schematic lateral view of the tibia and the talus that illustrates deeper placement of the tibial component of FIG. 7M into the tibia.

[0102] FIG. 7O is a schematic lateral view of the tibia and the talus that shows the tibial component as press-fit in place in the tibia.

[0103] FIG. 7P is a schematic lateral view of the tibia and the talus that shows the completed TAR after implantation and insertion of the plastic interface component and metal talus element.

[0104] FIG. 7Q is an anterior view of the ankle with the TAR in FIG. 7P with the dotted line representing the anterior cortex window.

[0105] FIGS. 8A and 8B show another form of a talus component which has one or more radial extensions which reduce possible excessive inversion or eversion.

DETAILED DESCRIPTION OF EMBODIMENTS

[0106] Turning now to the drawings, FIGS. 1A and 1B illustrate bones commonly associated with the ankle: tibia 10, fibula 12 and talus 14. In FIG. 2, a schematic cross section of the tibia 10 illustrates the cortical bone 16 surrounding the lower strength interior trabecular bone 18.

[0107] Some prior art TAR system components are illustrated in FIGS. 3A-3B and FIGS. 4A and 4B. The FIGS. 3A and 3B drawings are intended to depict a “standard” TAR design. It is composed of a metal component 20 attached to the talus, a hard plastic component 22 that interfaces between the talus metal component 20 and a metal component 24 attached to the tibia end. This serves to illustrate the limited contact surface area provided compared to the natural bone engagements.

[0108] In the so-called INBONE II system, shown in FIG. 4A, there is a similar arrangement of talus metal component 26, plastic intermediate element 28 and metal tibial component 30. Here, the latter also includes a stem element 32.

[0109] The so-called Trabecular Metal TAR system is illustrated in FIG. 4B. Here again, it is similarly composed of a metal talus element 34, an intermediate plastic component 36 and a tibial metal component 38. Noteworthy is the cylindrically curved nature of all contacting surfaces.

[0110] FIG. 5A shows the kind of box cuts C that are used to emplace the tibial component of a common TAR. Note the high stress riser corners present interior to the cut out. FIG. 5B is a schematic cross section showing how such a cut of the tibia results in edge loading of the tibia at E.

[0111] The intended purpose of the following detailed description of the invention and the phraseology and terminology employed therein is to describe what is shown in the drawings, which include the depiction of and/or relate to one or more nonlimiting embodiments of the invention, and to describe certain but not all aspects of the embodiment(s) to which the drawings relate. The following detailed description also identifies certain but not all alternatives of the embodiment(s). As nonlimiting examples, the invention encompasses additional or alternative embodiments in which one or more features or aspects shown and/or described as part of a particular embodiment could be eliminated, and also encompasses additional or alternative embodiments that combine two or more features or aspects shown and/or described as part of different embodiments. Therefore, the appended Claims, and not the detailed description, are intended to particularly point out subject matter regarded to be aspects of the invention, including certain but not necessarily all of the aspects and alternatives described in the detailed description.

[0112] Although the invention will be described hereinafter in reference to the ankle and total ankle replacement shown in the drawings, it will be appreciated that the teachings of the invention are more generally applicable to a variety of types of bone joints in the body.

[0113] To facilitate the description provided below of the embodiment(s) represented in the drawings, relative terms, including but not limited to, “proximal,” “distal,” “anterior,” “posterior,” “vertical,” “horizontal,” “lateral,” “front,” “rear,” “side,” “forward,” “rearward,” “top,” “bottom,” “upper,” “lower,” “above,” “below,” “right,” “left,” etc., may be used in reference to the orientation of the TAR during its use and/or as represented in the drawings. All such relative terms are useful to describe the illustrated embodiment(s) but should not be otherwise interpreted as limiting the scope of the invention.

[0114] According to certain nonlimiting aspects of the invention, a TAR has a tibia stem geometry that has been optimized to facilitate implant installation while providing improved means to transfer load over a larger surface area (“press-fit,” “scratch-fit” or “cortical fit”), thus lowering the contact stresses at the tibia-metal implant interface. The design of the TAR components and the implantation procedure for the TAR also address minimization of misalignment. Assembly tools have been contemplated and/or adapted and developed to result in proper alignment.

[0115] According to other certain nonlimiting aspects of the invention, a prosthetic ankle replacement includes a member anchored to the tibia (also called a “stem,” “tibial implant” or “tibial element”) and a member anchored to the talus (also called a “talus implant” or “talus element”). The members are operably associated. An intermediate member, such as a hard plastic component, may preferably be included to act as a sliding interface between the tibial and talus elements.

[0116] In one nonlimiting example, the shape of the stem of the tibial component is optimized for increased contact area based on the inner geometry of the tibia's cortical bone. A long stout stem provides radial stiffness and prevents high frequency cyclic loads from reaching the sliding joint and thus preventing micromotion. The stem of the tibial implant may be cylindrical or contoured to match the inner cortical bone. Contouring may be by custom-design, as by an Additive Manufacturing process for one example.

[0117] According to other certain nonlimiting aspects of the invention, the TAR eliminates the sharp corners in the design to prevent stress magnification at corners. Corners have been preferably rounded to minimize stress concentration. In a preferred form, the implant stem (tibial element) is monolithic (one piece), without need of any mechanical fixation within a channel in the tibia end other than a press fit. However, additional fixation, such as by use of cement, may nonetheless be considered.

[0118] According to other certain nonlimiting aspects of the invention, the TAR stem (tibial element) is implanted in the tibia by making a large resection oblique bone cut to give enough space to place the tibial implant. There is precedence for this in the hip joint where a large resection oblique cut is used to help place a press-fit stem. However, the inventor is not aware of any studies in the ankle demonstrating bone preservation as advantageous for TAR life as compared to a larger resection. Oftentimes, the quality of distal tibia bone is poor due to the juxtaposed arthritis. Making such a translation from hip joint to ankle joint is thus not precedented.

[0119] According to other certain nonlimiting aspects of the invention, an advantageous feature in one form of the present TAR design is conversion of the cylindrical joint (of the conventional design) to a spherical (ball and socket) type joint in the present TAR. The ball and socket arrangement will inherently disperse load over a wide area, and hence reduce the stress level which should result in longer bearing life similar to those of hip and knee joint replacements.

[0120] According to yet other certain nonlimiting aspects of the invention, the implant and its methodology preferably are configured to maximize the contact area of the joint by partially cutting into the ends of tibia and fibula without compromising the ligaments. This further reduces the stress levels experienced in tibia and talus, reducing the propensity to subside while improving the bearing life. The syndesmosis articulation (between tibia and fibula) is essentially non-functional in TAR for two reasons. First, the syndesmosis is generally arthritic in conjunction with the arthritic ankle joint. Second, after placement of a TAR the lateral gutter is typically cleared out to prevent impingement of the talus with the fibula. Thus, there is minimal to no anterior to posterior force on the fibula, and it will not move. The present TAR spans the tibia-fibula articulation with the implant and utilizes this non-functional space.

[0121] Turning now to the nonlimiting example in the drawings, FIGS. 6A-7Q depict certain examples and aspects of a TAR and associated prosthetic components and methods of installing the TAR according to various principles of the invention. However, the invention is not necessarily limited to TARs and/or use only with human ankle joints, but rather may also be applied to other bone joints in humans and/or other animals.

[0122] FIGS. 6A and 6B show an embodiment of a TAR 100 (also called a prosthetic ankle replacement, a prosthesis, a prosthetic bone joint replacement, and similar terms throughout). The TAR 100 includes an upper prosthetic component (referred to herein as a tibial element or stem part) 40 that attaches to the distal end of the tibia 10, a lower prosthetic component (referred to herein as a talus element or talus part 50) that attaches to an upper surface of the talus 14, and a plastic interface component (liner) 52 that is disposed between and engages against the stem part 40 and the talus part 50. Preferably, each of the stem part 40 and the talus part 50 is made of a suitable hard bio-compatible metal (e.g., stainless steel, titanium, alloys, etc.) such that the liner 52 forms a soft(er) seating surface between the opposing joint surfaces of stem part 40 and the talus part 50.

[0123] As shown in FIGS. 6A and 6B, in one embodiment, the upper prosthetic component or stem part 40 comprises an elongated tibial stem part 42 which extends from one end 44 that will be located within the tibial intramedullary canal 11, and widens in radius to an opposite end 46 forming a base to the stem part 40. There is a spherical concavity 48 formed in the base, which as will be seen, engages with a complimentary spherical convexity of the liner 52 and metal talus components. The talus components comprise a solid talus hemispherical shaped element 50 and inset within the concavity 48 is in the liner 52, which is preferably a hard plastic. These provide a high contact area spherical articulation between the plastic and metal components. While set forth in this embodiment as being metal, the tibial stem part 40 may be made of any material or materials commonly used in the prosthetic arts, including, but not limited to, metals, ceramics, or any other total joint replacement metal and/or ceramic, bony in-growth surface, including such things as artificial bone, uncemented metal or ceramic surface, or a combination thereof. The tibial stem may further be covered with one or more coatings such as antimicrobial, antithrombotic, and osteoinductive agents, or a combination thereof.

[0124] The tibial stem part 40 may be variable lengths, and variable widths. In the preferred embodiment, the tibial stem has a flared shape extending from a nose inserted up into the tibial intramedullary canal along a smooth widening radius to its interface with the talus part 50 and plastic liner componentry. It should be understood that the disclosed tibial stem could be of virtually any length, depending upon the size of the patient, his or her bone dimensions, and the anticipated future mobility of the patient. A custom-made tibial component is most preferably considered. The tibial stem is inserted into the reamed intramedullary passage superiorly through the tibia.

[0125] For example, as depicted in FIGS. 7D, 7E, 7F and 7G a passage using an awl and then successive reaming devices superiorly through the tibia, to form a space matching the shape of the intended tibial element, such that the latter can be press fit into place. The stem may further be fixed in the lower tibia as with polymethylmethacrylate bone cement, hydroxyapatite, a ground bone composition, or any other fixation materials common to one of skill in the art of prosthetic surgery.

[0126] Note that the base of the stem has a concavity formed therein, which is matched to the talus componentry which has a convexity such that the stem component and concentric plastic liner will smoothly fit on the talus element.

[0127] As shown in FIGS. 6A, 6B, 7P and 7Q, the talus portion of an embodiment of the present invention has a curved or dome shape presenting toward the tibia. This talus part would be preferably formed as a single piece, including pegs 56 that affix in holes drilled into the talus in known fashion. The pegs can be placed in different positions on the talus component than depicted, and alternatively, the talus component could have slots to accept screws, staples, pins, or any other fixation devices. The pegs or slots can be part of the hemispherical talus component or part of a projection extending off the component. Thus, the talus part 50 is fixed to the top of the talus. It may be made of various materials commonly used in the prosthetic arts including, but not limited to metals, alloys, ceramic, or any other joint replacement metal and/or ceramic, including most preferably surface bone engaging the talus component.

[0128] In this embodiment, the liner (interface component) 52 is provided between the talus part and the tibial stem and forms a part of the talus componentry. This interface is preferably ultra-high molecular weight polyethylene (UHMWPE) and is shaped like a dome to the surface of the talus part and matched to the interior concavity of the stem base.

[0129] As further illustrated in FIG. 6B, there is indicated an oblique resection R at the top end of the anterior cortex window, which will be discussed in a procedure related to implantation hereinafter.

[0130] As noted, FIGS. 7A through 7Q illustrate one possible example embodiment of an implantation procedure for the TAR 100 depicted in FIGS. 6A-6C.

[0131] FIG. 7A shows an anterior view of the native configuration of the tibia 10 and fibula 12, including the relative locations of the inner cortex 18 and outer cortex 16.

[0132] In a first step, illustrated in FIGS. 7B and 7C, two drill holes are made in the distal end of the tibia 10. FIG. 7B shows an anterior view of the tibia 10 with two drill holes 108A and 108B that have been made from the front to the back to create an anterior window for eventual tibial component placement. The drill hole 108A is a proximal large drill hole, whereas the drill hole 108B is a distal larger drill hole. Alternatively, this same bone resection can be completed with multiple perforations from a drill bit, burr, saw or other tool. FIG. 7C shows a lateral view of the drill holes 108A and 108B seen in FIG. 7B. The path of the distal larger drill hole 108B is parallel to the end of the tibia 10. The path of the smaller more proximal drill hole 108A is aimed inferiorly and posteriorly. The top surface 106 of the talus 14 is also resected. The lateral aspect of the talus 14 after a flat-cut is also depicted in FIG. 7C.

[0133] Next, FIG. 7D shows a curved awl 110 used to penetrate the tibial canal 11 to create a space for subsequent broaching. FIG. 7E shows deeper penetration of the awl 110 into the tibial canal 11. The awl 110 is curved and designed to avoid penetration of the cortex and only stay within the softer tibial canal 11.

[0134] After creating enough space with the awl 110, FIG. 7F shows a small entry broach 112 being placed into the tibial canal 11 to form a receiving cavity for the stem part 42 of the stem part 40. The broach 112 is shaped similar to the stem part 42 of the stem part 40 but is smaller than the definitive size. Optionally, one or more broaches 112 of increasing size may be used sequentially to shape and enlarge the receiving cavity into the tibial canal 11. FIG. 7G shows the final broach 112 placement after sequentially larger broaches have been used to enlarge the receiving cavity. This final broach 112 has sufficient press-fit in the tibial canal 11. The size of the final broach 112 is then used to determine the appropriate size of the tibial implant 40.

[0135] Next, excess bone can be removed from the tibia 10 and the fibula 12 if needed. FIG. 7H shows a targeting jig 114 attached to the final broach 112. This targeting jig 114 can be used to guide a burr, saw or other bone machining tool to remove excess bone from the tibia 10 and fibula 12. FIG. 7I shows proposed cuts 116a, 116b, and 116c made off the fibula and tibia to complete the bone resection needed to allow for implant placement. FIG. 7J shows an anterior view of the resected tibia 10 and fibula 12 bones after the cuts 116a-c have been made with the final broach 112 (and the targeting jig 114) removed from the tibia 10. Preferably, the edges of these resections are smoothed for optimal low stresses. This is in contradistinction to standard conventional TAR installation procedures which form sharp corners C as shown in FIG. 5A. FIG. 7K shows a lateral view of the tibia 10 and talus 14 after bone resection. The talus is in the “neutral” position at approximately 90 degrees to the axis of the tibia 10 in this view.

[0136] The talus 14 is then flexed in the plantar direction to provide sufficient clearance between the tibia 10 and the talus 14 for insertion of the stem part 40. FIG. 7L shows a lateral view similar to FIG. 7K but with the talus plantarflexed (downward) to create space for tibial component placement.

[0137] Next, the stem part 40 is inserted into the receiving cavity within the tibial canal 11. FIG. 7M shows a lateral view of penetrance of the stem part 40 in the tibial canal 11 entering anteriorly and inferiorly. The end 44 is inserted into the tibial canal 11 such that the base 70 will extend from the distal end of the resected tibia 10. FIG. 7N shows a similar view to FIG. 7M as the stem part 40 is placed (partially inserted) further into the tibial canal 11 and rotates distally to better approximate the axis of the tibia 10.

[0138] FIG. 7O shows a similar view to FIG. 7N with the stem part 40 definitively seated in the tibia 10 and press-fit into the tibial canal 11 in its final intended implant position.

[0139] Typically, although not necessarily thereafter, the talus part 50 is then attached to the flattened top surface of the talus 14, and the hemispherical top surface of the talus part 50 is seated within the concave (lower) surface of the liner 52, and the convex (upper) surface of the liner 52 is seating within the concavity 48 in the lower surface of the base 70 of the stem part 40. FIG. 7P shows a lateral view of the ankle with definitive placement of all components of the prosthetic ankle replacement (TAR) 100 similar to FIG. 6B. FIG. 7Q shows an anterior view of the ankle with definitive placement of all components of the TAR 100, along with a dotted line representing the bone resections made for implantation. This represents superimposing of FIGS. 6A and 7K.

[0140] FIGS. 8A and 8B illustrate one or more projections, or extensions, may also be provided on the talus component itself. Such projections 64 extend generally radially from the circumference of the talus component, most preferably from the lower circumference. The projections perform the function of stops in essence, to prevent the tibial component from sliding in undesirable inversion or eversion.

[0141] Optionally, the stem part 40 and the talus part 50 may be advantageously made with a sintering process and/or with an additive manufacturing 3D printing, to have connected porosity within one or both of these parts 40/50. This may allow for the formation of channels 72 therein (shown schematically in FIG. 7P), which allow diffusion of fluid within the part 40/50, and therefore to more function like a bone under transient dynamic loading conditions. At least some of the channels 72 extend from an exterior of the respective stem part 40 and/or talus part 50 into an interior thereof. These channels 72 allow diffusion of fluid such that the part 40/50 will function like a bone under transient dynamic loading conditions. This will result in distribution of load over the tibial and talus parts 40 and 50 minimizing the dynamic stresses, and hence life.

[0142] The TAR 100 and related implementation methods of the present invention are believed to overcome existing deficiencies in conventional TARs by creating robust contact between a tibia stem and the inside surface of the tibia cortical bone. This allows improved axial load transfer with lower stress levels imposed on the tibia 10 and talus 14.

[0143] Assembly tools and procedures are provided to improve alignment and preload accuracy on the stem to distribute the load over a large area, as depicted variously in FIGS. 7A-7Q. The technique of osteotomy, canal entry, and sequential broaching mimics the standard technique for hip replacement femoral stem placement, but it is considered to be new and unconventional as provided to ankle replacement. In order to place the tibia part 40, a cavity is gradually created through controlled broaching to accept the top surface of the stem. Broaching and tibia device placement may be done manually or using a computer-controlled system with load sensors for another technique.

[0144] It is expected that keeping stresses below the endurance limit will result in enhanced life of the TAR 100 relative to conventional ankle replacements prostheses. Improved alignment also helps with longevity. Nanomaterials may be utilized in the parts design to improve boundary lubrication. Microscopic passages (e.g., channels 72) may be provided through the upper stem and the top side to allow fluid migration to lubricate the sliding surfaces (see, e.g., FIG. 6C).

[0145] In a nonlimiting example, the design process for a tibial stem (tibial part) 40 involves obtaining the geometry of the tibia. From the geometry of the tibia bone's external surface an estimate of the internal cortical part of the bone could be obtained. From the inside geometry of the tibia, a tentative shape of the stem part 40 (stem) may be generated. This shape can be analyzed for its loadbearing capacity. If found to be sufficiently strong, a graphical means (or computerized equivalent means) could be used to determine the ability to assemble the stem into the tibia. During assembly, known processes could be incorporated to measure the applied axial force to calculate the measured radial interference. From the bone properties, the adequacy of the interference may be evaluated.

[0146] The components of the TAR 100 may be manufactured by any effective means. While not exclusive, it is considered most preferred that all metallic components of the inventive TAR (e.g., the stem part 40 and talus part 50) are made by a sintering method wherein powdered material (of graded particle size distribution) is used to make a part in ‘green state’ by compressing the powder in a mold. The green part is then heated in a furnace to the sintering temperature and held for a required length of time. The sintered metal and plastic materials have lower mechanical strength but are stronger than the bones. They also have a lower Young's modulus (compared to the parent material) which tends to make their compressive behavior similar to that of bones for a given size. This helps distribute load more uniformly over the contact area between the tibia and talus. Manufacturing may also be done by 3D printing (additive manufacturing) to achieve similar characteristics. Standard coating and porous surfaces may also be created to allow for bone ingrowth or cement fixation.

[0147] The spherical joint between the liner 52 and metallic talus part 50 may be made with projections 62 at the periphery of the plastic component to slow escape of synovial fluid during axial shock loading. Based on the amount of fluid between the components, the projections 62 may or may not be necessary.

[0148] There are numerous advantages in the new prosthetic bone joint replacement implant (e.g., TAR 100) relative to conventional joint replacement prostheses. For example, the large articulation contact area of the new prosthetic bone joint replacement implant (e.g., TAR 100) will increase the usable life span of the replacement joint due to larger contact area for load transfer from tibia to talus through the spherical joint. The fluid pressure (or equivalently the mechanical stress) in the bearing area is reduced due to the larger contact area. The lower stress level should increase the boundary layer thickness which should reduce the wear rate in the sliding parts. In some arrangements, mechanical subsidence of the tibia metal component may be reduced due to the larger contact area from the press-fit tibia stem component as compared to the traditional end-loading tibia components. In some arrangements, the TAR may have improved performance in that it should allow a patient to perform higher impact activities as compared to traditional TARs. In some arrangements, reduced friction and increased mass in the TAR joint will lead to lower transient temperatures (in the sliding joint) keeping it below 42° C., and thus reduce the degradation of synovial fluid and prevent solids precipitation from the synovial fluid at high transient temperatures (e.g., T>42° C.) in the sliding joint. In some arrangements, the ball-and-socket joint design of the new TAR 100 is based on a spherical (ball and socket) joint allowing angular displacements of the required magnitudes about two orthogonal axes. This makes the design more tolerant to angular misalignment of tibia to talus, preventing wear due to edge loading. It also provides protection against shock loads. Additionally, the spherical design allows for inversion and eversion movement to further offload adjacent joints. In some arrangements, the length and diameter of the stem will be designed to result in a press-fit with the tibial canal, which will ensure improved load transfer capability through the cortical section of healthy proximal tibia. The tibia component will not rely on arthritic distal tibial bone for support. In some arrangements, a cushioning effect may be achieved, for example, because articulation will be designed to maintain a sufficient boundary layer for cushioning between the plastic and metal talus components during axial shock loading. A plastic component may advantageously include peripheral projections to retain sufficient synovial fluid between components.

[0149] According to some nonlimiting aspects of the invention, stem geometry of a tibial element implant has been optimized to facilitate implant installation while providing improved means to transfer load over a larger surface area through a “press-fit,” “scratch-fit” or “cortical fit,” thus lowering the contact stresses at the tibia-metal implant interface. The design and its implantation procedure also address minimization of misalignment.

[0150] As previously noted above, though the foregoing detailed description describes certain aspects of one or more particular embodiments of the invention, alternatives could be adopted by one skilled in the art. For example, the joint replacement prosthesis, such as the TAR 100, and its components could differ in appearance and construction from the embodiments described herein and shown in the drawings, functions of certain components of the joint replacement prosthesis could be performed by components of different construction but capable of a similar (though not necessarily equivalent) function, and various materials could be used in the fabrication of the joint replacement prosthesis and/or its components. As such, and again as was previously noted, it should be understood that the invention is not necessarily limited to any particular embodiment described herein or illustrated in the drawings.

[0151] This methodology as well as the prosthesis itself, as set forth for ankle replacement could be used in other applications such as hip, knee or shoulder replacements. Also, increasing the size of the elements may further adapt the prosthesis to be used for other applications such as when a patient has lost part of their bone in an accident or the talus bone has lost its blood supply.

[0152] Although the devices, components, materials and methods have been described and illustrated in connection with certain embodiments, many variations and modifications will be evident to those skilled in the art and may be made without departing from the spirit and scope of the disclosure. For instance, while the invention has found particular form for ankle replacement, aspects may nevertheless be applicable to other joints in the body. The disclosure is thus not to be limited to the precise details of methodology or construction set forth above as such variations and modification are intended to be included within the scope of the disclosure, and the Claims hereafter.