1. Field of the Invention
The present invention relates to endoprosthetic articular joint implants, and more specifically to methods and apparatus for replacing a radial head using a modular implant.
2. Description of the Related Art
Prosthetic devices for joint repair and replacement in humans and other skeletal beings are known. Joint function can be lost due to fracture or damaged joint surfaces, for example. Joints compromised in these ways typically have suffered injury or disease. Repair often entails endoprosthetic implants installed in place of resected bone-ends to replace the damaged joint and restore joint function.
A radial head implant system is disclosed in U.S. Pat. No. 6,361,563 to Terrill-Grisoni et al. The modular system includes a head and a stem. A complex system is used to adapt the radius of the head.
Joint-replacements are known that generally include an intramedullary stem anchoring a curved joint surface. U.S. Pat. No. 5,061,288 to Berggren et al. Berggren et al. discloses a joint implant that features a surface-replacing portion attached to the end of an axial support. Bristles extend radially from the axial support sufficient to be urged proximally upon insertion to the canal. The bristles consequently are biased against removal of the implant, thereby acting as barbs to anchor the surface-replacing portion of the implant on the end of resected bone. A joint-surface material features a dove-tail groove that engages a base with a corresponding pin attached to the axial support.
French patent document no. 2,605,878 in the name of Condamine discloses a two part joint prosthesis. Referring to
U.S. Pat. No. 5,314,486 to Zang et al. discloses a phalangeal implant having an insertable bearing-surface. The implant lacks an ability to adjust alignment between respective joint components.
There is a need in the prior art for a simple but effective modular radial head prosthesis with fixation elements supporting articulating surfaces with improved properties and materials.
The invention provides a modular endoprosthetic radial head replacement implant. The implant features an end cap that fits into a cannulated body connected to an anchoring screw. The screw has a spherical head and fits into the cannulated body to engage complementary internal geometry of the cannulated body. The end cap is manufactured from a material that provides an appropriate bearing surface.
The invention is described herein mostly in connection with replacing the proximal end of a radius for articulating with the capitellum of a humerus. Other configurations are possible, however. The radial depression of the bearing surface can be radiused according to the type of joint being replaced, i.e., the depression can feature a single radius, a dual radius, an eccentric radius, etc. Also, the bases of the end cap and the base can be configured with a slant, for example, to sit flush with a variety of bone surfaces.
In an exemplary surgical technique for radial repair, an appropriated combination of modular components is selected to match a patient's anatomy. The fractured radius is resected using instrumentation configured to accommodate the implant. The threaded end of the screw is passed into the body to nest with the internal geometry of the body. The screw, engaged with a driver, is advanced with turning into the intermedullary canal of the radius. A spanner-type wrench may be used to rotate the body to improve fit or alignment. A jam nut is advanced along threads formed within the body and tightened onto the screw head. Once the screw is locked in place to maintain alignment with respect to the body, the end cap is assembled onto the body to complete the construct.
Other features and advantages of the present invention will become apparent from the following description of exemplary embodiments of the invention with reference to the accompanying drawings.
Referring to
End cap 3 may be manufactured from hydrogel, polished titanium, polished CoCr, PEEK, plastics and other polymers, and other biocompatible materials. Metal surfaces may be coated or treated to enhance bearing properties. Hydrogels are colloidal gels in which water is the dispersion medium. An exemplary hydrogel material contains water in similar proportions to human tissue, to which it has similar mechanical and physical properties. The hydrogel is an organic polymer-based biomaterial known to be highly biocompatible. Used in articular applications, the hydrogel material is soft and compliant like human tissue, and is exceptionally wear resistant and strong, making it an exemplary implant resource suitable for many medical applications.
End cap 3 mates with the body 5. Joining of the two components may be accomplished by a “snap” fit in the case of non-metallic components. Metallic or ceramic end cap components 4 may be joined using a Morse type taper 6, as shown in
The interface between the end cap 3 and body 5 may or may not contain index notches to allow for precise incremental radial adjustment. The base 8 of the end cap 3 may be slanted to provide better anatomical matching of the device to the anatomy, as illustrated by broken line 9 in
External edges of the end cap 3 are substantially rounded. The central portion 11 is substantially concave and has a single radius. Referring to
The cannulated body 5 can be manufactured from titanium alloy, or other biocompatible metallic or non-metallic materials. Body 5 assembles with the end cap 3 as described above to cover the proximal end of the body 5 cannulation. Once in place, the end cap 3 will enclose within body 5 a jam nut (not shown) and a screwhead 17, described in further detail below. Body 5 is substantially cylindrical, and may have a slanted distal end 19, shown by a broken line in
Body 5 is formed to provide a hole 23 through the bottom surface 21. Internal geometry of body 5 adjacent the hole 23 is spherical to accommodate the head 17 of the screw 7. The complementary geometry of both components, body 5 and screw 7, provides improved contact surface area for locking the implant construct, as described further below. Additionally, the complementary configuration allows for polyaxial motion of the body 5 to place surface 21 in apposition to the resected radial bone, regardless of the angle of resection. The polyaxial adjustment is infinite within the mechanical constraints of the device.
A plurality of sockets 25 located radially about the central axis of body 5, on the major diameter, provides a method of attachment for a corresponding instrument. The instrument may be used to rotate the body 5 about it's central axis to position the body 5 for maximum implant 1 performance. Alternately, or in addition, other features or forms located radially, such as flats 27, may be employed to facilitate in situ rotation of the body 5.
Screw 7 may be manufactured from titanium alloy, or other metallic materials. The screw 7 preferably is manufactured from materials similar to those of the jam nut and body 5.
The screw 7 may be tapered or straight in design. The spherical head 17 is located proximally. The shape of the head 17 is complementary to the spherical radius found within the body 5. The head 17 of the screw 7 is formed to accept a corresponding tool to drive the implant forward with turning into bone.
Once polyaxial adjustment of the body 5 with respect to screw 7 is completed, as described above, the body 5 and screw 7 are locked into position. More specifically, the jam nut is assembled within the body 5. The externally-threaded jam nut is installed into complementary internally-threaded portion 31 of body 5. The jam nut is tightened onto spherical head 17 using a common tool. The adjusted polyaxial position can be unlocked as necessary by loosening the jam nut. The distal face of the jam nut is spherical to provide improved contact surface area with the spherical head 17 for locking the body 5/screw 7 construct.
The jam nut may be manufactured from titanium alloy or other metallic materials. The jam nut preferably is manufactured from materials similar to those of the screw 7 and body 5.
Preparation for an exemplary surgical technique relies upon radiographic film, surgical templates, and trial implants to determine and select the appropriate combination of modular devices end cap 3, body 5, screw 7 that make up implant 1 to meet the patient's anatomical requirements. The remaining fractured radius is resected using appropriate instrumentation designed specifically for the implant system.
The distal end of the screw 7 is passed through the proximal opening of the body 5 until the screw 7 is nestled within the complementary internal sphericity of the body 5. The screw 7 is located and advanced down the intermedullary canal of the radius until the distal surface 21 of body 5 is in apposition with the resected bone. A spanner type wrench may be used to rotate body 5 radially for improved fit or alignment. The jam nut is advanced and tightened to lock the screw 7 into place. The end cap 3 is assembled onto the body 5 to complete the construct.
Although the present invention has been described in connection with preferred embodiments, many modifications and variations will become apparent to those skilled in the art. It is not intended that the invention be strictly limited to the above-described and illustrated embodiments. Any modifications, including those presently unforeseeable, of the invention that come within the spirit and scope of the following claims should be considered part of the invention.
This application claims the benefit of U.S. Provisional Application Ser. No. 60/607,783, filed Sep. 8, 2004.
Number | Date | Country | |
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60607783 | Sep 2004 | US |