This invention relates to an instrument for positioning a cup component of an orthopaedic joint prosthesis.
Certain orthopaedic joint prostheses include a hollow cup with an inner surface which defines a generally hemispherical hollow region, and another component which has a spherical part which can be received in the hollow region for articulation relative to the cup component. Such joint prostheses can include hip joint prostheses and shoulder joint prostheses. The exterior of the cup will contact the prepared surface of the patient's bone in which the component is to be implanted. The interior of the cup will present a smooth bearing surface to the spherical convex part of the other component of the joint prosthesis. The bearing surface can be provided by a single piece cup component. Alternatively, the cup component can comprise a shell part which contacts the prepared surface of the patient's bone, and a bearing part which provides the bearing surface, and which fits into the shell part. The bearing part can be made from a material which is different from the material of the shell part: for example the bearing part can be made from a polymeric material (such as polyethylene) and the shell part (and the spherical convex part of the other component) can be made from a metal (such as a cobalt-chromium based alloy, or a stainless steel, or a titanium based alloy).
It is important that the components of an orthopaedic joint prosthesis are positioned accurately in a patient's bone. Both location and alignment are important. Accurate positioning of a component requires that the component be engaged by an appropriate instrument, allowing considerable force to be applied to the component if and as necessary (for example through use of an impactor instrument). However, it can be important not to contact the external surface or the internal surface or both of the component with the instrument, especially the internal surface when it has been provided with a smooth polished bearing surface. Scratching or otherwise damaging that surface can impair the bearing properties of the prosthesis.
In some prior art instruments, the insertion tool includes a flange that interacts with a groove cut into an inner surface of the cup. Other prior art instruments utilize a plurality of jaw members which extend radially from a central drive shaft. The jaw members can be made to slide radially inwardly so that they engage the outside wall of a cup component. Each of the jaw members has a pin at one end which is received in a spiral track on a drive plate. The jaw members are made to slide radially by rotating the drive plate. The jaw members engage a corresponding recess in the cup.
In each of these prior art examples, the insertion tool works by interacting with special features on the cup. This limits the instrument to only be able to be used with certain cups. Therefore, there is a need for an insertion instrument that can be used on a cup without the cup having special features added to the cup.
According to one embodiment of the present invention, an instrument for positioning a hollow cup component of an orthopaedic joint prosthesis is provided. The instrument includes a longitudinal member having a first end and a second end opposite the first end. The instrument further includes a resilient cup engaging member coupled to the first end. The resilient cup engaging member has a convex outer surface adapted to engage an interior of the hollow cup component. The entire outer convex surface is manufactured of a resilient material. An actuator in fluid communication with the resilient cup engaging member is also included. When the actuator is actuated, the suction force between the resilient cup engaging member and the hollow cup increases.
According to another embodiment, a method for using an insertion instrument to insert a cup into an acetabulum is provided. The method includes inserting a convex outer surface of the instrument into an inner surface of the cup. The entire convex outer surface is made of a resilient material. A piston is activated, in order to decrease pressure within a sealed cavity of the instrument, This activation causes the convex outer surface of the instrument to engage the inner surface of the cup. The instrument and cup are inserted into place in the acetabulum. The piston is de-activated in order to increase pressure within the sealed cavity, causing the convex outer surface of the instrument to disengage the inner surface of the cup.
According to yet another embodiment of the present invention, a kit for use in hip arthroplasty is provided. The kit includes a monoblock cup, and an instrument for positioning the cup. The instrument includes a longitudinal member having a first end and a second end opposite the first end. Also included is a resilient cup engaging member coupled to the first end. The resilient cup engaging member having a convex outer surface adapted to engage an interior of the cup. The entire outer convex surface is manufactured of a resilient material. The instrument also includes an actuator in fluid communication with the resilient cup engaging member, such that when the actuator is actuated, the suction force between the resilient cup engaging member and the cup increases.
Like reference numerals refer to like parts throughout the following description and the accompanying drawings. Turning now to
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The shaft portion 38 is an elongated shaft and includes the remaining portion of the inner cavity 34. Inside the inner cavity 34 is also part of the actuator 27, a moveable piston 44. The moveable piston is coupled to the lever 26. As the lever 26 is moved, the moveable piston 44 moves along the inner cavity 34.
Moving toward the second end 16 of the longitudinal member 12 and shaft portion 38, is a holder 46. The holder 46 is adapted to engage the moveable piston 44 and lock the moveable piston 44 in position. There is also a spring 48, which interacts with the holder 46 and a releasement mechanism (in the illustrated embodiment, a collar) 50 in order to enable a user to unlock the moveable piston 44 from its locked position.
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The cup 24 described in the above embodiments is a monoblock cup 24 having a metal outer surface and a polyethylene inner surface. The outer surface may be made of any biocompatible metal, such as titanium. The outer surface may also include a porous outer coating to promote bone in-growth. The inner surface may be molded into the outer surface and may be any biocompatible polyethylene, such as an antioxidant polyethylene. Alternatively, an ultra high molecular weight polyethylene may also be used.
The foregoing description of the invention is illustrative only, and is not intended to limit the scope of the invention to the precise terms set forth. Further, although the invention has been described in detail with reference to certain illustrative embodiments, variations and modifications exist within the scope and spirit of the invention as described and defined in the following claims.