The present invention relates to implant components, and more particularly to sleeve components for use with implant stems.
Joint replacement surgery can be performed on hips, knees, elbows, shoulders, and other joints to replace a diseased or damaged natural joint. A common joint replacement surgery is hip arthroplasty, which may replace one or both of the ball part of the femur that articulates in the hip socket and/or the hip socket itself. If the ball part of the femur needs to be replaced, a hip implant stem (also referred to as a femoral stem) is typically used, and various hip stem designs and methods are well known in the art. Regardless of what type of stem is used it is important to secure the hip stem securely within the femoral canal for the initial fixation, as well as to promote the long-term stability of the implant.
One feature that may be provided in conjunction with various hip stems to help stabilize the stem in plane in a canal is a sleeve. Sleeves are typically provided with a bore that extends through the sleeve, and a hip stem or other implant stem is received through the bore. The proximal part of the sleeve typically has a spout or other surface that engages the proximal part of the femur for stabilization. While this mechanism for fixation is usually adequate for primary surgeries, more complex surgeries such as revision and congenital dysplasia of the hip surgeries may require alternate and better types of stem/sleeve fixation, particularly at the middle to more distal part of the bone.
Some current femoral fixation devices and techniques include a cylindrical stem that is biologically and/or bead coated. Other systems use a tapered grit-blasted stem. These cylindrical and tapered stems have had relatively good clinical success, but not without complications. Some surgeons who use traditional, conical, tapered hip stems find it difficult to recreate the femoral neck height because the stem locks into place in the femoral canal too high or too low. Difficulties in achieving reproducible reamer depth placement and variations in bone quality are other factors that result in the stem placement uncertainty. Some revision tapered hip systems offer modular necks of various heights to compensate for the height deficiency, but in some instances, offering modular necks as the only feature to compensate for such problems may increase the complexity of the surgical procedure. Cylindrical biologically and/or bead coated revision hip stems have the advantage of a more reproducible fit during the surgery, however, the biological enhancement coating in conjunction with the cylindrical shape of the implant may cause stress-shielding to the proximal bone. Unlike a tapered stem, a cylindrical stem loads the bone entirely against shear forces within the femoral canal. The inefficient loading distribution is likely to cause bone loss proximally, making future revision surgeons even more difficult.
Accordingly, when seeking support for the prosthesis more distally, the surgeon often uses a longer revision stem. With such long stems, the most distal section of the stem must be modified to accommodate the anterior bow of the femur. Examples of modifications include bowing or angling the distal section of the stem and/or adding a chamfer onto distal tip of the stem. Without modification, the stem may perforate the cortex of the femur. Both approaches and other variations, however, introduce a severe limitation in stem neck orientation. The surgeon is often unable to adequately reproduce the desired stem prosthesis version angle. Accordingly, additional hip stems for more complex surgeries are needed.
Various embodiments of the invention relate to sleeves having lengths that allow the sleeve to engage a patient's femoral intramedullary canal in a mid to distal region rather than only proximally. In preferred embodiments, the sleeve length is between about 60 millimeters to about 150 millimeters. In certain embodiments, the sleeve is adapted to extend beyond the lesser trochanter, to or near or beyond a patient's isthmus.
This deep fixation of the sleeve in the intramedullary canal allows a stem that extends through the sleeve to achieve a greater fixation more proximally than stems that have only a distal taper or bowed distal end or other feature at the distal end of the stem. This more proximal fixation provided by the long sleeve's ability to fixate in the mid to distal part of the femur may help enhance the integrity of the stem by moving loading stresses to more proximal regions of the stem, rather than distally. Such long sleeves can provide better fixation when there is less proximal bone on which a standard stem can “grab” and/or “rest.” Other embodiments of the long sleeves according to this invention may help bridge bone defects or bypass sclerotic bone. In certain embodiments, the sleeve is adapted to extend beyond the lesser trochanter, to or near or beyond a patient's isthmus and provide diaphyseal fixation.
For example,
The sleeve 30 preferably has a spout 36 that protrudes from a proximal portion 38 of sleeve. Spout 36 is typically a protruding section extending from the upper portion 38 of sleeve body 32 that can be seated in the proximal portion of the femur 100, as shown in
Outer surface 40 of sleeve 30 may optionally be provided with a bone-engaging feature that may provide the sleeve and stem combination with more stability. The bone engaging feature may include a surface that is treated with one or more of grit blasting, bead coating; fluting (such as that shown and described in co-pending U.S. Provisional Application Ser. No. ______, filed Jan. 20, 2006, titled “Fluted Hip Sleeve for Modular Stem,” the contents of which are incorporated herein by reference), porous coating, absorbable materials, surface enhancing materials or any other appropriate surface treatment. It may also be possible to provide terraced or stepped portions on spout 36.
Importantly, the sleeve 30 has a length that allows it to engage a patient's femur 100 in a mid to distal, region 102 of the femoral intramedullary canal rather than only proximally 104, as shown in
A particularly preferred sleeve according to various embodiments is adapted to engage the portion of bone between the lesser trochanter and the isthmus of the femur bone. (
Long sleeves according to various embodiments of this invention may be manufactured and used in a manner similar to those used to manufacture and use current standard sleeves. For example, during use, the portion of the bone to receive the long sleeve is prepared using instruments such as reamers or broaches. During the preparation of the femur, a ledge is normally created by the reamer, which helps support the stem in an axial direction. The surgeon should next assess what type of long sleeve would fit best. Various long sleeves described herein may be provided as a part of kit that has a plurality of sleeves, wherein the plurality of sleeves are provided in differing, lengths or widths or both. The sleeves may also be provided with varying spout shapes and types (or sleeves without spouts) varying stem/sleeve connection mechanisms, or any other feature that will provide more options to a surgeon during a procedure. For example, a kit according to one embodiment of the invention could include one or more long sleeves provided in (a) differing lengths or widths or both; (b) varying spout shapes, angles, extension lengths, and types, or combinations thereof (as well as sleeves without spouts); (c) varying stem connection mechanisms; or (d) any combination thereof. The kit may also include a plurality of stems having varying lengths or fixation features. Further kits may include (a) one or more of the above described sleeves having varying features, (b) one or more stems having varying lengths or fixation features; and (c) one or more acetabular cup assemblies. Head components adapted to cooperate with the stem and the acetabular cup assembly may also be provided.
Once chosen, the sleeve may be press fit into the surgically prepared femur. The stem may then be inserted through the sleeve and locked into place by intimate contact between the distal bone and engagement of the sleeve (via any of the stem/sleeve connection mechanisms described above). Another implantation method may include pre-assembling the stem and sleeve combination together prior to implantation. One advantage of using a long sleeve is that it provides the ability to achieve fixation as proximal as possible, as opposed to relying on stems having angles or bows to secure the stein distally. Maintaining proximal fixation enhances the integrity of the stem by moving loading stresses to more proximal regions of the stem. As discussed, some currently available stems only feature a distal taper at the end of stem (which engages the bone at the bottom of the stem) to provide the fixation. This creates a flagpole effect, creating high stress at the mid-stem region, which ultimately causes the stem to fracture.
By contrast, significant decreases in stem stresses have been shown when proximal support is enhanced by adding support structures such as long sleeves. Long sleeves work by engaging bone more proximally, that is, more proximally than distal stem tapers or other distal stem fixation options, but deeper in the bone than typical bone sleeves that only rest on and extend into the proximal-most part of the bone. Long sleeves have been found to decrease stem stress and possibly increase the life of the implant.
Changes and modifications, additions and deletions may be made to the structures and methods recited above and shown in the drawings without departing from the scope or spirit of the invention and the following claims.
This application claims priority to U.S. Provisional Patent Application Ser. No. 60/655,101 filed Feb. 22, 2005 and titled “Long sleeves for diaphyseal fixation,” the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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60655101 | Feb 2005 | US |
Number | Date | Country | |
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Parent | 11884587 | Apr 2008 | US |
Child | 15131897 | US |