Offset cup impactor with an expandable dome for double mobility implants

Abstract

An orthopaedic prosthetic inserter used for the implantation of double mobility implants is described. The inserter consists of a drive train, a C-shaped housing, and a prosthetic cup grabbing subassembly. The subassembly comprises a frustro-conical nose and an expandable dome. When activated by the drive train, the dome expands into the cup of the prosthetic to manipulate the prosthetic during implantation.

Description

BACKGROUND OF THE INVENTION

This invention relates to surgical inserters for aiding in installing orthopedic prostheses, and more specifically, to easily sterilizable inserters for installing acetabular implants in the acetabular socket.

A double mobility prosthetic cup is a type of acetabular implant that is designed to increase a patient's range of mobility. Unlike other types of actabular implants, double mobility prosthetic cups do not have an opening through the cup portion which allows for easy manipulation during implantation. For example, a rod is typically threaded through the cup opening. This rod is used like a handle with which to control and guide the implant during implantation. Double mobility implants, on the other hand, do not have such an opening and therefore create a challenge in controlling them during implantation. The present invention solves this problem and provides an effective novel means of manipulating the double mobility implant during implantation.

Complicated mechanical devices have crevices and recesses that are difficult, if not almost impossible to clean with ease. Devices that are not properly cleaned and sterilized run the risk of disease transfer from patient to patient following the emergence of certain “prions” that are not killed by normal hospital sterilization and need to be physically removed by washing and rinsing.

Further, in surgical procedures in which access to the treatment site is limited, it is difficult to use current solutions without subjecting the patient to repeated abrasion and tissue trauma when inserting and extracting surgical instruments.

Still further, once the appropriate position of the implant is selected, it is often difficult to ensure that the position does not change upon insertion of the assembly through the incision.

What is needed therefore is a double mobility implant inserter that is easily adjustable, disassemblable, and cleanable. Further, what is needed is an inserter that enables the surgeon to better maneuver, position and install the double mobility implant in a particular angular orientation.

SUMMARY OF THE INVENTION

The present invention relates to an acetabular inserter that aids a surgeon in controlling the installation of a double mobility acetabular cup prosthesis. The inserter has a housing which encloses a drive train having, at a far end, a double mobility prosthetic engaging subassembly, and at the opposite end, a handle which facilitates activation of the drive train and movement of the subassembly. The inserter enables easy orientation of a double mobility prosthesis attached to its end. This is important because precise control of the prosthetic is critical in implantation of the prosthetic in a patient.

The subassembly comprises a series of components, a frustro-conical nose and an expandable dome which work in concert to grip the inside of the prosthetic cup.

An objective of the invention is to be “easily cleaned” by quick and modular disassembly which enables access to all surfaces that can be cleaned. The reduction in the number of small radius internal corners, crevices and small gaps and the absence of blind holes also aids in the sterilization of the instrument.

BRIEF DESCRIPTION OF THE DRAWINGS

The attached drawings represent, by way of example, different embodiments of the subject of the invention.

FIG. 1A is a cross-sectional side view of the inserter of the invention.

FIG. 1B is a magnified cross-sectional side view of the components that comprise the subassembly.

FIG. 1C is a magnified cross-sectional side view of the components of the subassembly aligned together.

FIG. 2A is a perspective view of the proximal and distal ends on the expandable dome.

FIG. 2B shows a perspective view of the proximal and distal ends of an alternate embodiment of the expandable dome.

FIG. 3A is a magnified cross-sectional side view of the components that comprise an alternate embodiment of the subassembly.

FIG. 3B is a magnified cross-sectional side view of the components that comprise an alternate embodiment of the subassembly aligned together.

FIG. 4 is a cross-sectionai view of the inserter of the present invention in operation.

FIG. 5A is a perspective view of the inserter of the present invention, showing a step of disassembly for cleaning.

FIG. 5B is a perspective view of the inserter of the present invention, showing another step of disassembly for cleaning.

FIG. 5C is a perspective view of the inserter of the present invention, showing a stage of disassembly for cleaning.

FIG. 5D is a perspective view of the inserter of the present invention, showing a stage of disassembly for cleaning.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

Referring now to FIGS. 1A-1C, an acetabular inserter 10 is provided to aid the surgeon in controlling the installation of an acetabular cup prosthesis 12. The inserter 10 has a housing 14 which encloses a drive train 16 having, at a distal end, a prosthesis engaging subassembly 18, and at the proximal end, a handle 20 which facilitates moving of the drive train by the operator. The housing 14 may be C-shaped, as shown, in order to minimize the invasiveness of the surgery by better clearing anatomical structures and tissue.

The subassembly 18 comprises a nose 22 and a dome 24 that are in direct communication with each other. The dome 24 is designed to expand into the double mobility acetabular cup prosthesis 12 to provide a substantially friction tight engagement which enables precise control of the prosthesis 12 during implantation in the body.

The distal end of the nose 22 has a frustro-conical shape that engages the dome 24 in its proximal end. The nose 22 has an annular ramp surface 26 that slopes downwardly and inwardly towards the distal end of the nose 22. The downwardly sloping ramp surface 26 engages the proximal end of the dome 24 by contacting the opposing coping surface 28 inside the dome cavity 30 located at the proximal end of the dome 24. The dome cavity 30 is designed to receive the frustro-conical shape of the distal end of the nose 22. As will be discussed in more detail, the downwardly and inwardly shape of the ramp surface 26 acts as a wedge to expand the dome 24. The outwardly expansion of the dome 24 creates a friction tight engagement between the dome 24 and the interior cup surface 32.

The nose 22 is connected to the distal end of the housing 14. A cylindrical rod 34, which is connected to a cylindrical piston 44, slides in an axial bore 38 that penetrates through the nose 22 and into the dome 24. The cylindrical rod 34 is preferably threaded. In a preferred embodiment, the nose 22 is made of a polymer material. However, alternate materials such as metal or ceramic could also be used to create the nose 22.

A channel 40 penetrates through the center of the dome 24 from the distal end of the dome cavity 30 through the outer distal dome surface 42. The channel 40 provides a space for the cylindrical rod 34 to reside and gives added flexibility to the expansion of the dome 24 as well. It is preferred that channel 40 have grooves to receive the threads of the cylindrical rod 34.

The piston 44 is connected by way of a first O-joint 46 to a lever 48 which slides in a pivoting sleeve 50 fixed to the housing 14 via a pivot 52. The lever 48 is connected via a second U-joint 54 to a second pivoting lever 56 which is fixed to pivot, in a catch 57 (FIG. 5A) on a pivot pin 58. The catch is essentially a divot or a seat cut into the housing 14, against which the pivot pin 58 of the lever 56 is captured when a slide 59 (FIG. 5A) is slid over the pin 58 when engaged against the seat.

A slideable sleeve 60 (FIGS. 1A and 4) slides over the lever 56 and has a trunnion 62 to which a rod 64 is pivotally attached. The rod 64 passes through a one-way catch 66 in the housing 14. The one-way catch 66 can be a captured split wedge sleeve 68 having an inner diameter that just matches the outer diameter of the rod 64 and which is captured in a recess having a matching conical surface that surrounds the sleeve so as to allow the rod 64 to slide into the housing 14, but to prevent the rod 64 from sliding out of the housing 14 unless an unlock lever (not shown) is activated, such lever merely lifting the sleeve 68 out of engagement with the conical surface so as not to lock and to permit the rod 64 to back out of the housing 14. Any number of alternative one-way lock devices may be used however, the selection of which being within the skill of a person of ordinary skill in this field.

FIGS. 2A and 2B depict different preferred embodiments of the dome 24. The dome 24 is made out of a pliable polymer material which is designed to fit and expand into the prosthetic cup 12 to create a substantially friction tight engagement between the dome 24 and the interior cup surface 32 that is incapable of movement with respect to the subassembly 18. The dome 24 is designed to be sized to fit a multitude of different double mobility implants 12 of different diameters and depths. As such, the diameter of the dome 24 may range from about 2 cm to about 15 cm. The depth of the dome 24 may range from about 2 cm to about 10 cm. In all cases, it is preferred that the dome 24 create an interference fit with the interior of the prosthetic cup surface 32.

The dome 24 is designed with at least one slit 70 through the distal surface of the dome 24. The slit or slits 70 have a width from about 1 mm to about 10 mm that penetrates through the distal dome surface 42 through the dome body from the proximal dome end through the distal dome end to a core region that is just above the channel 40 of the dome 24. In other words, each slit 70 penetrates from the distal dome surface 42 to the core region of the dome. The slits 70 divide the dome 24 into sections 72 that are capable of independent or unison movement. It is preferred that the dome 24 have three slits 70. However, one could design the dome 24 with two, four, five, six or more slits 70 as desired. As previously mentioned, the dome channel 40 and opening 74 provide added flexibility to the dome sections 72.

The proximal end of the dome 24 has a rounded cavity 30 in which the distal end of the nose 22 resides. The threaded end of the cylindrical rod 34 resides in the bore 38 of the dome 24. The threads of the cylindrical rod 34 engage the grooves in the dome channel 40.

When activated, the cylindrical rod 34 slides proximally towards the distal end of the housing 14. The rod 34 traverses through the bore 38 of the nose 22, pulling the attached dome 24 proximally towards the ramp surface 26 of the nose 22. The coping surface 28 of the dome 24 inside the cavity 30 meets the ramp surface 26 of the nose 22 creating a force therebetween. This force separates and moves the sections 72 of the dome 24 distally thereby expanding the diameter of the dome 24 against the interior cup surface 32 creating a seal therebetween.

Although the nose 22 and dome 24 components are preferably frusto-conical and dome, in shape respectively, alternate forms and shapes of these components could also be used. What is required of the invention are matching components, one with a ramping surface, the other with a coping surface, that work together to expand outwardly to grasp the interior surface of the prosthetic 32. For example, instead of a dome shaped component, one could design a cone shaped component with a proximal coping surface working in conjunction with a triangular shaped component with a ramp surface that rides along the opposing coping surface, expanding the cone shaped component. The expandable component being of an appropriate size and form to create a frictional interference fit with the interior cup surface 32. Furthermore, the nose 22 and dome 24 could be of a variety of curved, rounded or conical shapes.

In an alternate embodiment as shown in FIG. 23, an O-ring 76 is received in an annular groove 78 on the surface of the distal end of the dome 24. The O-ring 76 is designed to improve the seal by creating a more uniform frictional fit with the interior cup surface 32. The O-ring 76 is made from a polymer material, preferably silicone rubber, that is capable of expanding in unison with the dome 24. As such, the O-ring 76 has a diameter which creates an interference fit with the interior cup surface 32. The thickness of the O-ring 76 is from about 1 mm to about 10 mm.

The O-ring 76 is positioned on the outer distal surface 42 of the dome 24 near the proximal end. This creates an improved frictional seal that does not damage the prosthetic cup 12. As shown in FIG. 3A, it is preferred that the O-ring 76 be placed a distance x from the proximal end of the dome 24. The distance x is defined to be from about 1 to about 25 percent of y, the distance along a longitudinal axis from the proximal end to the apex of the dome 24.

The cross-sectional views of FIGS. 3A-3B illustrate how the alternate dome 24 embodiment is utilized in the subassembly 18. As shown in FIG. 3A, the O-ring 76 is positioned in the annular groove 78 surrounding the outside distal dome surface 42.

Although an O-ring 78 is preferred in the present invention, one skilled in the art might design a different attachment to the dome 24. For example, one might attach a wide band or flap around the dome 24 to form a seal between the dome 24 and interior cup surface 32.

Referring now to FIG. 4, in operation, first the dome 24 is threaded onto the threaded cylindrical rod 34 in such a manner that the dome ramp surface 26 is in contact with the coping surface 28 of the dome 24. The operator may rotate the handle 20 about its axis to turn the drive train 14 in order to orient the prosthesis in what he believes to be a correct or an initial position. Then, the proximal end 56B of the lever 56 is urged downwardly toward the housing 14. Such downward movement acts through the drive train 16 to draw the piston 44 into the housing 14, and thus to cause the coping surface 28 of the dome 24 to be drawn against the ramp surface 26 of the nose 22 so as to create a normal force between the inside of the dome 24 and the nose 22. This normal force causes the sections 72 and outer distal surface of the dome 42 to expand outwardly so as to grip the interior cup surface 32 of the prosthetic cup 12. The operator may use the one way locking mechanism 68 to lock the lever 56 in a position so as to lock the dome 24 against the nose 22, thus enabling the surgeon to pre-set and lock the position of the prosthesis 12 prior to the installation thereof.

Referring now to FIGS. 5A-5D, in the embodiment shown, the device 10 is disassembled for cleaning by simply sliding the slide 59 back so as to release the pivot 52 and then lift the drive train 16 out of the housing but allow it to remain pivotally connected at pivot 52. As the drive train 16 is pivoted, the piston 44 is drawn out of the housing cavity 82. To reassemble after cleaning, the piston 44 is reinserted into the housing cavity 82 and the drive train 16 is rotated back into position, with the one way locking mechanism entering its receiver and the pivot 52 again entering into the catch 57. The slide 59 is then slid over the pivot 52 and the inserter 10 is again ready for use.

The present invention can be packaged in a kit offering a variety of double mobility prosthetic implants 12 of different sizes and diameters. The inserter 10, and assorted double mobility implants 12 and domes 24 can be packaged in a case with recesses which conveniently holds the components in a convenient easy to access manner.

The attached drawings represent, by way of example, different embodiments of the subject of the invention. Multiple variations and modifications are possible in the embodiments of the invention described here. Although certain illustrative embodiments of the invention have been shown and described here, a wide range of modifications, changes, and substitutions is contemplated in the foregoing disclosure. In some instances, some features of the present invention may be employed without a corresponding use of the other features. Accordingly, it is appropriate that the foregoing description be construed broadly and understood as being given by way of illustration and example only, the spirit and scope of the invention being limited only by the appended claims.

Claims

1. An inserter for aiding a surgeon in controlling the installation of a prosthesis cup, the inserter comprising: a) a housing extending from a proximal housing end to a distal housing end;b) a nose supported at the distal housing end with a bore extending longitudinally through the nose, wherein the nose comprises an outer ramping surface extending distally and inwardly toward the bore from a proximal nose end adjacent to the housing to a distal nose end;c) an expandable dome having comprising a dome length extending distally and inwardly from a proximal end adjacent to the housing to an apex of the dome, wherein the inner dome surface comprises a coping surface extending from the proximal end part way along the dome length toward the apex, the dome being supported on the nose with the inner coping surface contacting the outer ramp surface of the nose;d) an O-ring supported in an annular groove provided in the outer dome surface;e) a drive train at least partially housed inside the housing, the drive train comprising: i) a first lever comprising a first lever proximal end spaced apart from a first lever distal end located adjacent to the distal housing end;ii) a second lever comprising a second lever proximal end located adjacent to the proximal housing end and spaced apart from a second lever distal end;iii) a drive rod comprising a drive rod proximal end space apart from a drive rod distal end, wherein the second lever distal end is in a universal joint relationship with the first lever proximal end, and wherein the first lever distal end is in a universal joint relationship with the drive rod proximal end and the drive rod distal end extends through the bore of the nose and connects to the dome in the dome bore;iv) a first sleeve pivotably connected to the housing, wherein the first lever is in a slidable relationship with a first opening in the first sleeve disposed at an intermediate location between the first lever proximal end and the first lever distal end;v) wherein the second lever is pivotably supported by the housing; andf) wherein the second lever proximal end is manipulable from a first position spaced from the housing to a second position spaced closer to the housing than the first spaced position to cause the second lever to pivot with respect to the housing and thereby move the second lever distal end away from the distal housing end and to further cause the first lever to move away from the distal housing end along the first opening in the first sleeve as the first sleeve pivots on the housing to thereby cause the drive rod to move along the longitudinal bore in the nose with the drive rod distal end connected to the dome moving from a first drive rod position spaced from the nose to a second drive rod position closer to the nose than the first drive rod position to thereby cause the inner coping surface of the dome to move proximally against the outer ramp surface of the nose to thereby cause the dome supporting the O-ring to both expand from a first, unexpanded state to a second expanded state.

2. The inserter of claim 1 wherein the ramping surface of the nose has a frusto-conical shape.

3. The inserter of claim 1 wherein the housing is C-shaped.

4. The inserter of claim 1 wherein the dome is made of a polymeric material.

5. The inserter of claim 1 wherein actuation of the drive train draws the drive rod along the bore in the nose to thereby move the dome in a proximal direction with the inner coping surface of the dome riding against the outer ramping surface of the nose to thereby expand the dome from a first state to a second state of a larger size than the first state against a prosthesis cup and into a substantially friction tight engagement therebetween.

6. The inserter of claim 1 wherein the dome has at least one slit that penetrates into the dome from the distal dome surface through to the core region of the dome.

7. The inserter of claim 1 wherein the O-ring is positioned around an outside circumference of the dome a distance x from the proximal end of the dome, the distance x being from about 1 to about 25 percent of y, which is the distance along the longitudinal axis from the proximal end to the apex of the dome.

8. The inserter of claim 1 wherein the O-ring is of a polymer material.

9. The inserter of claim 1 wherein a knob is attached to the second lever proximal end, the knob enabling a user to manipulate the drive train.

10. The inserter of claim 1 wherein the material of the nose is selected from the group consisting of a polymer, a metal and a ceramic.

11. An inserter for aiding a surgeon in controlling the installation of an orthopaedic prosthesis, the inserter comprising: a) a housing extending from a proximal housing end to a distal housing end;b) a frusto-conical nose supported at the distal housing end with a bore extending longitudinally through the nose, wherein the nose comprises an outer ramping surface extending distally and inwardly toward the bore from a proximal nose end adjacent to the housing to a distal nose end;c) an expandable dome comprising a dome length extending distally and inwardly from a proximal end adjacent to the housing to an apex of the dome, wherein the inner dome surface comprises a coping surface extending from the proximal end part way along the dome length to a distal bore leading to the apex, the dome being supported on the nose with the inner coping surface contacting the outer ramp surface of the nose;d) an O-ring, having a curved cross-section, supported in an annular groove provided in the outer dome surface adjacent to the proximal dome end;e) a drive train at least partially housed inside the housing, the drive train comprising: i) a first lever comprising a first lever proximal end spaced apart from a first lever distal end located adjacent to the distal housing end;ii) a second lever comprising a second lever proximal end located adjacent to the proximal housing end and spaced apart from a second lever distal end;iii) a drive rod comprising a drive rod proximal end space apart from a drive rod distal end, wherein the second lever distal end is in a universal joint relationship with the first lever proximal end, and wherein the first lever distal end is in a universal joint relationship with the drive rod proximal end and the drive rod distal end extends through the bore of the frusto-conical nose and connects to the expandable dome in the dome bore;iv) a first sleeve pivotably connected to the housing, wherein the first lever is in a slidable relationship with a first opening in the first sleeve disposed at an intermediate location between the first lever proximal end and the first lever distal end; andv) wherein the second lever is pivotably supported by the housing;f) a prosthesis cup contactable with the outer surface of the expandable dome;g) wherein the second lever proximal end is manipulable from a first position spaced from the housing to a second position spaced closer to the housing than the first spaced position to cause the second lever to pivot with respect to the housing and thereby move the second lever distal end away from the distal housing end and to further cause the first lever to move away from the distal housing end along the first opening in the first sleeve as the first sleeve pivots on the housing to thereby cause the drive rod to move along the longitudinal bore in the frusto-conical nose with the drive rod distal end moving from a first drive rod position spaced from the frusto-conical nose to a second drive rod position closer to the frusto-conical nose than the first drive rod position; andh) wherein this drive rod movement draws and expands the expandable dome supporting the O-ring against an interior surface of the prosthetic cup, thereby establishing a substantially friction tight engagement there between.

12. The inserter of claim 11 wherein the O-ring is positioned a distance x from the proximal end of the expandable dome, the distance x being from about 1 to about 25 percent of y, which is the distance along the longitudinal axis from the proximal end to the apex of the expandable dome.

13. The inserter of claim 11 wherein a knob is attached to the second lever proximal end, the knob enabling a user to manipulate the drive train.

14. The inserter of claim 11 wherein the material of the frusto-conical nose is selected from the group consisting of a polymer, a metal, and a ceramic.

15. The inserter of claim 11 wherein the expandable dome is made of a polymeric material.

16. A surgical kit for minimally invasive surgery, the kit including: a) a case having recesses into which components of the kit may be conveniently stored until use;b) at least one prosthetic cup implant; andc) an inserter for aiding a surgeon in controlling the installation of the orthopedic implant, the inserter comprising: i) a housing extending from a proximal housing end to a distal housing end;ii) a nose supported at the distal housing end with a bore extending longitudinally through the nose, wherein the nose comprises an outer ramping surface extending distally and inwardly toward the bore from a proximal nose adjacent to the housing to a distal nose end;iii) an expandable dome comprising a dome length extending distally and inwardly from a proximal end adjacent to the housing to an apex of the dome, wherein the inner dome surface comprises a coping surface extending from the proximal end part way along the dome length toward the apex, the dome being supported on the nose with the inner coping surface contacting the outer ramp surface of the nose;iv) an O-ring supported in an annular groove provided in the outer dome surface;v) a first lever comprising a first lever proximal end spaced apart from a first lever distal end located adjacent to the distal housing end;vi) a second lever comprising a second lever proximal end located adjacent to the proximal housing end and spaced apart from a second lever distal end;vii) a drive rod comprising a drive rod proximal end space apart from a drive rod distal end, wherein the second lever distal end is in a universal joint relationship with the first lever proximal end, and wherein the first lever distal, end is in a universal joint relationship with the drive rod proximal end and the drive rod distal end extends through the bore of the nose and connects to the dome in the dome bore;viii) a first sleeve pivotably connected to the housing, wherein the first lever is in a slidable relationship with a first opening in the first sleeve disposed at an intermediate location between the first lever proximal end and the first lever distal end;ix) wherein the second lever is pivotably supported by the housing; andd) wherein the second lever proximal end is manipulable from a first position spaced from the housing to a second position spaced closer to the housing than the first spaced position to cause the second lever to pivot with respect to the housing and thereby move the second lever distal end away from the distal housing end and to further cause the first lever to move away from the distal housing end along the first opening in the first sleeve as the first sleeve pivots on the housing to thereby cause the drive rod to move along the longitudinal bore of the nose with the drive rod distal end connected to the dome moving from a first drive rod position spaced from the inserter head to a second drive rod position closer to the nose than the first drive rod position; ande) wherein the prosthesis cup implant is removeably secured to the distal end of the expandable dome such that actuation of the drive train draws the drive rod along the bore in the nose to thereby expand the expandable dome supporting the O-ring against an interior surface of the prosthetic cup into a substantially friction tight engagement therebetween with the prosthesis cup being substantially incapable of movement with respect to the expandable dome and the O-ring.

17. The inserter of claim 16 wherein the O-ring is positioned around the outside circumference of the expandable dome a distance x from the proximal end of the expandable dome, the distance x being from about 1 to about 25 percent of y, which is the distance along a longitudinal axis from the proximal end to the apex of the expandable dome.

18. An inserter for aiding a surgeon in controlling the installation of an orthopedic prosthesis, the inserter comprising: a) a housing extending from a proximal housing end to a distal housing end;b) a frusto-conical nose supported at the distal housing end with a bore extending longitudinally through the nose, wherein the nose comprises an outer ramping surface extending distally and inwardly toward the bore from a proximal nose end adjacent to the housing to a distal nose end;c) an expandable dome comprising a dome length extending distally and inwardly from a proximal end adjacent to the housing to an apex of the dome, wherein the inner dome surface comprises a coping surface extending from the proximal end part way along the dome length toward the apex, the dome being supported on the nose with the inner coping surface contacting the outer ramp surface of the nose;d) an O-ring supported in an annular groove provided in the outer dome surface, the O-ring positioned a distance x from the proximal end of the expandable dome, the distance x being from about 1 to about 25 percent of y, which is the distance along the longitudinal axis from the proximal end to the apex of the expandable dome;e) a drive train at least partially housed inside the housing, the drive train comprising: i) a first lever comprising a first lever proximal end spaced apart from a first lever distal end located adjacent to the distal housing end;ii) a second lever comprising a second lever proximal end located adjacent to the proximal housing end and spaced apart from a second lever distal end;iii) a drive rod comprising a drive rod proximal end space apart from a drive rod distal end, wherein the second lever distal end is in a universal joint relationship with the first lever proximal end, and wherein the first lever distal end is in a universal joint relationship with the drive rod proximal end and the drive rod distal end extends through the bore of the frusto-conical nose and connects to the expandable dome in the dome bore;iv) a first sleeve pivotably connected to the housing, wherein the first lever is in a slidable relationship with a first opening in the first sleeve disposed at an intermediate location between the first lever proximal end and the first lever distal end,v) wherein the second lever is pivotably supported by the housing; andf) wherein the second lever proximal end is manipulable from a first position spaced from the housing to a second position spaced closer to the housing than the first spaced position to cause the second lever to pivot with respect to the housing and thereby move the second lever distal end away from the distal housing end and to further cause the first lever to move away from the distal housing end along the first opening in the first sleeve as the first sleeve pivots on the housing to thereby cause the drive rod to move along the longitudinal bore in the frusto-conical nose with the drive rod distal end connected to the dome moving from a first drive rod position spaced from the frusto-conical nose to a second drive rod position closer to the frusto-conical nose than the first drive rod position; andg) wherein this drive rod movement draws and expands the expandable dome outer surface supporting the O-ring.

19. The inserter of claim 18 wherein a portion of the O-ring extends above the outer dome surface.

20. The inserter of claim 18 wherein the O-ring and the dome are made of a polymeric material.

21. An inserter, comprising: a) a housing extending from a proximal housing end to a distal housing end;b) a nose supported at the distal housing end with a bore extending longitudinally through the nose, wherein the nose comprises an outer ramping surface extending distally and inwardly toward the bore from a proximal nose end adjacent to the housing to a distal nose end;c) an expandable dome comprising a dome length extending distally and inwardly from a proximal end adjacent to the housing to an apex of the dome, wherein the inner dome surface comprises a coping surface extending from the proximal end part way along the dome length toward the apex, the dome being supported on the nose with the inner coping surface contacting the outer ramp surface of the nose;d) an O-ring supported in an annular groove provided in the outer dome surface; ande) a drive train at least partially housed inside the housing, the drive train comprising a drive rod comprising a drive rod proximal end space apart from a drive rod distal end that is connected to the nose, wherein the drive rod distal end extends through the nose of the inserter along the longitudinal axis and into the expandable dome through a central bore which begins at the distal cavity dome end and extends proximally therefrom,f) wherein the drive train is manipulable to cause the drive rod to move along the longitudinal bore in the nose with the drive rod distal end moving from a first drive rod position spaced from the nose to a second drive rod position closer to the nose than the first drive rod position to thereby cause the inner coping surface of the dome to move proximally against, the outer ramp surface of the nose and cause the dome supporting the O-ring to both expand from a first, unexpanded state to a second expanded state.

22. The inserter of claim 21 wherein expansion of the dome supporting the O-ring is sufficient to establish a substantially friction tight engagement against the interior surface of a prosthesis.