1. Field Of The Invention
This invention relates generally to an apparatus and method for shoulder arthroplasty and, more particularly, to a humeral component and other associated surgical components and instruments for use in shoulder arthroplasty.
2. Discussion of the Related Art
A natural shoulder joint may undergo degenerative changes due to a variety of etiologies. When these degenerative changes become so far advanced and irreversible, it may ultimately become necessary to replace a natural shoulder joint with a prosthetic shoulder joint. When implantation of such a shoulder joint prosthesis becomes necessary, the natural head portion of the humerus is resected and a cavity is created in the intramedullary canal of the host humerus for accepting a humeral component. The humeral component includes a head portion used to replace the natural head of the humerus. Once the humeral component has been implanted, the humeral cavity positioned at the scapula socket may also be resurfaced and shaped to accept a glenoid component. The humeral component generally includes an articulating surface which engages and articulates with the socket portion of the glenoid component.
It is generally known in the art to provide a shoulder joint prosthesis having a humeral component, as discussed above. However, current prior art humeral components along with the associated surgical components and instruments utilized during shoulder arthroplasty suffer from many disadvantages.
For example, since the humeral component is subject to various types of loading by the glenoid component, the humeral component must offer a stable and secure articulating surface. To achieve this, some humeral components provide a post or stem attached to a lateral surface of the prosthetic humeral head. These humeral components are generally a single piece system with a single stem, which is inserted and cemented into a hole bored deeply into the intramedullary cavity. However, such existing humeral components also exhibit several disadvantages. For example, these types of stemmed humeral components utilize a large stem to stabilize and secure the humeral component to the humerus. Such humeral components increase the amount of bone tissue removed, while also increasing the labor and complexity of the shoulder arthroplasty. Other stemmed humeral components may offer a larger diameter stem. However, the larger diameter stem also requires excess bone tissue to be removed which may not be practical in some patients.
Other prior art humeral components, such as that disclosed in WO 01/67988 A2 sets out a stemless humeral component or head that provides an integral cruciform shape that includes two planar intersecting fins. While this type of humeral component addresses the amount of bone tissue removed, this type of system provides little versatility or adjustments to a surgeon performing the shoulder arthroplasty. Moreover, this type of system does not provide additional enhanced fixation other than the planar intersecting fins.
Additionally, most prior art humeral components only rely on the stem to secure the humeral component into the intramedullary canal, via a cement mantle or bone attachment. The stem may also include grooves or holes, which act as an anchor, once the stem is cemented within the intramedullary canal. The medial surface of most humeral components are thus generally overlooked to enhance cement fixation and are therefore generally smooth. Although some humeral components may include a few longitudinal grooves and others may include both grooves and depressions on the medial surface, such surface enhancements only utilize or texture a portion of the medial surface, thereby not advantageously using the entire medial surface.
What is needed then is a modular humeral component and associated surgical components for use in shoulder arthroplasty which do not suffer from the above-mentioned disadvantages. This in turn, will provide a humeral component which is stable and secure, reduces the overall amount of bone tissue required to be removed, increases a surgeon's available components utilizing a single sized post, reduces the overall surgical time and complexity, increases overall medial surface area, enhances and increases post strength without increasing overall post diameter, provides a fully enhanced or textured medial surface for enhanced cement fixation or bone fixation and increased overall stability, provides for a uniform cement mantle, and provides increased tensile and shear strength. It is, therefore, an object of the present invention to provide such a humeral component and associated surgical components for use in shoulder arthroplasty.
In accordance with the teachings of the present invention, an apparatus and method for shoulder arthroplasty is disclosed. The apparatus and method employs a modular humeral component and other associated surgical components for use in the shoulder arthroplasty. In this regard, the modular humeral component is adapted to be implanted into a humerus and engaged by a glenoid portion of a scapular component.
In one preferred embodiment, a modular humeral component is used for shoulder arthroplasty such that the humeral component is adapted to be implanted into a humerus and engage a glenoid component. The humeral component includes a head member having a first articulating surface and a second fixation surface, which is opposite to the first articulating surface. The first articulating surface is adapted to engage the articulating surface of the glenoid component and the second fixation surface is adapted to engage a fixation component. The fixation component has a first surface adapted to be secured to the head member and a second surface that is generally opposite the first surface. The second surface includes a fixation member adapted to be secured to the humerus.
Use of the present invention provides an apparatus and method for shoulder arthroplasty, and specifically, a modular humeral component and associated surgical components for use in shoulder arthroplasty. As a result, the aforementioned disadvantages associated with the currently available humeral components and associated surgical components for shoulder arthroplasty have been substantially reduced or eliminated.
Still other advantages of the present invention will become apparent to those skilled in the art after reading the following specification and by reference to the drawings in which:
a-2c are views of the fixation member of humeral component of
a-9 are alternate embodiments for the fixation member of the humeral component of the present invention;
a-23e depict another alternate embodiment of the present invention having flanges disposed on a shelfless base member;
b illustrate a method for preparing the humerus implantation of the humeral component using associated surgical components according to the teachings of the preferred embodiment of the present invention;
a-c represent side and perspective views of an alternate fixation member having a through stem fixation bore;
a-c represent side and perspective views of an alternate fixation member having a male Morse taper with through stem fixation bore;
a-c represent side and perspective views of an alternate fixation member having a female Morse taper with through stem fixation bore;
a-c represent side and perspective views of an alternate fixation member
a and 36b represent an alternate fixation component having a fixation member;
a-39b represents the intention of a fixation member;
The following description of the preferred embodiments concerning an apparatus and method for shoulder arthroplasty is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
a-2c depict the base member 32 of one embodiment of the current invention. The base member 32 is defined by a shelf member 44, which may have a plurality of through holes 46. The shelf member 44 can have at least one mating member 48 for engaging the head member 33 of the humeral component 31. It is preferred that the mating member 48 be a defined Morse taper or other suitable attaching mechanism. In addition to the mating member 48, each base member 32 has a fixation peg 34 disposed on the lower lateral surface 50 of shelf member 44. The fixation peg 34 is generally perpendicular to the shelf member for its entire length of the fixation peg 34. As depicted in
b shows the head member 33 which mates with the base member 32 of
The head member 33 and base member 32 must be made of bio-compatible materials such as, without limitation, titanium, titanium alloys, surgical alloys, stainless steels, bio-compatible ceramics, and cobalt alloys. Optionally, the base member 32 can additionally be made of materials such as biocompatible ceramics and resorbable and non-resorbable polymers and other anticipated bio-compatible metallic or polymeric materials. Should the base member 32 be made of non-metallic components, a fastener would be needed to couple the head 33 to the base 32.
As shown in
The fixation peg 34 includes a first end 79, which is inserted into or engages a cavity or hole formed within a cavity in the humerus and a second end 81, which extends from or is integral with the shelf member 44. The first end 79 is semi-spherical and the second end has a 0.25 inch radius about the circumference of the second end 81 of the peg, which blends into a flat or smooth portion of the coupling region 75 to decrease the overall sheer stress of the fixation peg 34. Optionally, should the fixation peg be non-metallic, embedded within the first end of each fixation peg 34 is a tantalum ball 83. The tantalum ball 83 enables the humeral component 31 to be easily identified in an x-ray.
As with the base member depicted in
a shows the alternate humeral component 109 in its assembled configuration.
b depict an alternate embodiment of the humeral component 122. Shown is the base member 124 which has a modified female cavity defining a Morse taper 116. The head portion 126 has a coupling male Morse taper 132 disposed on the medial surface of the head component 126. Disposed between the head portion 126 and the base portion 124 is the coupling member 128. The coupling member 128 defines an outer surface 118 which functions as the male portion of the Morse taper and couples to the female portion 116 of the base member 124. The coupling member 128 further defines an interior cavity 130 which functions as a female Morse taper for the male Morse taper 132 of the head 126. The interior cavity 130 of the coupling member has an offset angle 134, which functions to rotate the center of curvature of the head portion 126 with respect to the base member 124. Similarly, shown in
a-23e depict another alternate embodiment of the present invention. Shown is a shelfless base member 232 which is formed by a fixation peg 234. Each fixation peg 234 has three evenly spaced triangular fins 236 disposed thereon. The triangular fins 236 have an edge 239 which is co-planar to a top surface 238 of fixation peg 234. Incorporated into a top surface 238 of the fixation peg 234 is a fixing mechanism 240.
a and 23b disclose fixing mechanism 240 in the form of a female Morse taper as the fixation which functions to couple the head 30 onto the base member 232 (see
When the base member 240 is coupled to head member 30, there is a defined gap between the lower surface 244 of the head 30 and the upper surface 238 of the base member 232. After implantation, the lower surface 244 of head member 30 rests upon the resected bone, not the top surface 238 of the base member 232.
The method for implanting the humeral component 31, along with associate surgical components utilized will now be described with reference to
Once the guide hole 90 is drilled, the resected head 36 of humerus 38 is optionally reamed using a concave spherical reamer shaft 102 with the driver 98. The concave reamer 102 includes a guide pin 104 and a roughened spherical surface 106 substantially corresponding to the spherical shape of the lower medial surface of the shelf member 44 of base member 32. An optional convex reamer surface 108 permits rasping or drilling of tight humeral cavities (see
With reference to
Once the base member 32 has been inserted into the guide hole 90, the optional screws 85 are disposed through the holes 46 to couple the base member 32 to the humerus 38. At this point, a surgeon may use any number of test head portions and/or adapter portions to determine the proper size needed to mate with the glenoid component. Once a proper head member 33 size has been determined, the final head member 33 can be fixed to the shelf member 44 of the base member 32.
a-c represent side and perspective views of an alternate fixation member 266 having a mating member 268 in the form of a male Morse taper with a through stem fixation bore 270 for engaging the head member of the humeral component. In addition to the mating member 268, the fixation member 266 has a fixation peg 272 disposed on the lower lateral surface 274 of shelf member 276. The shelf member 276 can define convex spherical lower lateral surface 258 and concave spherical upper lateral surface 260.
a-c and 32a-c represent side and perspective views of an alternate fixation members 282a and 282b. The members 282a and 282b have a shelf member 280 with mating features 284a and 284b for engaging the head member of the humeral component. The shelf member 280 of the fixation members 282a and 282b define a flat lower lateral surface 286 and convex spherical upper lateral surface 288.
The fixation members depicted in
The modular nature of the humeral component 31 of the present invention allow a set of various types of both replacement base members 32 and head members 33 to be formed. In using such a set, a surgeon can interoperably choose the appropriate base member depending on the patient's particular degenerative condition. Additionally, the surgeon can then choose from a set of head members 33, which both have the proper articulating surface radius and a proper coupling to the base member 32.
The bone engaging member 304 has a head engagement portion 306 and a threaded bone engagement portion 308. The bone engagement member 304 additionally has a shelf member engagement region 310 and drive feature 312. The shelf engagement region 310 functions to. distribute and translate forces from the articulating head into the resected bone. It is envisioned that the shelf engagement region 310 can be an annular engagement flange 318 or textured cylindrical interface surface. The drive feature 312 can be an aperture having at least one defined flat drive surface, such as a hex aperture. The head engagement portion 306 can be a defined male 314 or female 316 Morse taper.
The shelf member 302 can be generally flat or curved. As described in previous embodiments, the shelf member 302 has upper and lower surfaces 320 and 322 which can be flat, concave or convex. The shelf members can additionally define a plurality of through apertures 324 that are configured to accept bone engaging screws to prevent rotation of the shelf member 302 during the insertion of the bone engaging member.
a and 36b represent an alternate fixation component having a bone fixation member 304. The upper surface 320 of the shelf member 302 is show being concave as previously described. The shelf member has a annular coupling groove 326 which mates with the annular flange 318 of the bone engaging member 304.
a-39b represents the implantation of a fixation member. Once the surface of the resected head 36 of the humerus 38 has been resected, the shelf member 302 positioned adjacent to the resected head 36. The bone engagement member 304 is inserted into the guide hole 90. It is envisioned that the bone engagement member 302 can be forced into the guide hole 90 to displace the bone material around the intramedullary canal.
Once the bone engagement member 302 has been inserted into the guide hole 90, the bone engagement member 302 is rotated until the annular engagement flange 318 engages the upper surface 320 of the annular shelf member 302. Optional screws 85 are disposed through the holes 324 to couple the base member 302 to the humerus 38. At this point, a surgeon may use any number of test head portions and/or adapter portions to determine the proper size needed to mate with the glenoid component. Once a proper head member size has been determined, the final head member 330 can be fixed to the head engagement portion 306 of the bone engaging member 302.
The head portion 403 is shown with an axially centered fixation stem 418. It is envisioned the stem 418 can take the form of an offset male Morse taper as is shown in
A pair of fasteners 434 are positioned through the coupling apertures 414 in the coupling flanges 410 and 412. As seen in
After the coupling member 402 is inserted into the humerus, a trialing head 60′ is optionally used to determine the proper size and orientation of the humeral head 403. The humeral head 403 is then coupled to the coupling member as previously described.
The description of the invention is merely exemplary embodiments in the present invention. One skilled in the art would readily recognize from such discussion and from accompanying drawings and claims that various changes, modifications, variations may be made therein without departing from the spirit and scope of the invention.
This application is a continuation-in-part application of U.S. patent application Ser. No. 10/930,044 filed on Aug. 30, 2004, which is a continuation-in-part application of U.S. patent application Ser. No. 10/205,386 filed Jul. 25, 2002 and issued Aug. 31, 2004 as U.S. Pat. No. 6,783,549, which claims the benefit of U.S. Provisional Application No. 60/308,340, filed on Jul. 27, 2001. The disclosure of the above applications is incorporated herein by reference.
Number | Date | Country | |
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60308340 | Jul 2001 | US |
Number | Date | Country | |
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Parent | 10930044 | Aug 2004 | US |
Child | 11225645 | Sep 2005 | US |
Parent | 10205386 | Jul 2002 | US |
Child | 10930044 | Aug 2004 | US |