U.S. patent application number 12/711137 was filed with the patent office on 2010-08-26 for prosthetic device, method of planning bone removal for implantation of prosthetic device, and robotic system.
This patent application is currently assigned to MAKO SURGICAL CORP.. Invention is credited to Miranda Jamieson, Amit Mistry, Mark Ellsworth Nadzadi, Scott David NORTMAN, Jason K. Otto, Robert Van Vorhis.
Application Number | 20100217400 12/711137 |
Document ID | / |
Family ID | 42244429 |
Filed Date | 2010-08-26 |
United States Patent
Application |
20100217400 |
Kind Code |
A1 |
NORTMAN; Scott David ; et
al. |
August 26, 2010 |
PROSTHETIC DEVICE, METHOD OF PLANNING BONE REMOVAL FOR IMPLANTATION
OF PROSTHETIC DEVICE, AND ROBOTIC SYSTEM
Abstract
A prosthetic device, method for planning bone removal, and a
robotic system for implantation of a prosthetic device in bone are
disclosed. The prosthetic device can include a body portion for
attachment to a bone, wherein the body portion includes an
implantation surface configured to face the bone upon implantation,
and a constraint structure. The prosthetic device, method, and
robotic system can be configured to cause the constraint structure
and bone to interact so as to constrain the prosthetic device in
the bone.
Inventors: |
NORTMAN; Scott David;
(Sunrise, FL) ; Mistry; Amit; (Plantation, FL)
; Otto; Jason K.; (Plantation, FL) ; Vorhis;
Robert Van; (Davis, CA) ; Nadzadi; Mark
Ellsworth; (Memphis, TN) ; Jamieson; Miranda;
(Fort Lauderdale, FL) |
Correspondence
Address: |
FOLEY AND LARDNER LLP;SUITE 500
3000 K STREET NW
WASHINGTON
DC
20007
US
|
Assignee: |
MAKO SURGICAL CORP.
|
Family ID: |
42244429 |
Appl. No.: |
12/711137 |
Filed: |
February 23, 2010 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
61208451 |
Feb 24, 2009 |
|
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|
Current U.S.
Class: |
623/20.14 ;
606/130; 606/86R; 623/16.11; 623/22.11 |
Current CPC
Class: |
A61F 2002/30795
20130101; A61F 2002/30878 20130101; A61F 2002/4631 20130101; A61F
2002/3412 20130101; A61B 34/30 20160201; A61B 17/1764 20130101;
A61F 2002/3895 20130101; A61B 17/1746 20130101; A61F 2/30771
20130101; A61B 34/25 20160201; A61F 2/36 20130101; A61B 17/175
20130101; A61B 90/39 20160201; A61F 2/30724 20130101; A61F
2002/30823 20130101; A61F 2/38 20130101; A61F 2002/30805 20130101;
A61F 2002/30883 20130101 |
Class at
Publication: |
623/20.14 ;
623/16.11; 623/22.11; 606/86.R; 606/130 |
International
Class: |
A61F 2/38 20060101
A61F002/38; A61F 2/28 20060101 A61F002/28; A61F 2/32 20060101
A61F002/32; A61B 17/56 20060101 A61B017/56; A61B 19/00 20060101
A61B019/00 |
Claims
1. A prosthetic device for implantation in bone, comprising: a body
portion for attachment to a bone, wherein the body portion includes
an implantation surface configured to face the bone upon
implantation; and constraint structure comprising at least one of:
(i) at least one compressive projection projecting from the
implantation surface in a lateral direction of the body portion and
configured to provide a compressive force between the at least one
compressive projection and the bone, (ii) at least one interlock
projection projecting from the implantation surface and having an
interlock-projection surface configured to receive bone in a space
between the interlock-projection surface and a proximal portion of
the implantation surface, and (iii) at least one recess in the
implantation surface and configured to receive bone to constrain
the body portion in at least two translational degrees of freedom,
wherein the constraint structure is configured to constrain the
prosthetic device in the bone.
2. The prosthetic device of claim 1, wherein the at least one
compressive projection is configured to include a bone-engaging
surface for engaging the bone and a free surface that does not
engage the bone.
3. The prosthetic device of claim 1, comprising at least three
compressive projections.
4. The prosthetic device of claim 1, wherein the
interlock-projection surface includes a substantially planar
portion that projects over and extends at an acute angle relative
to the proximal portion of the implantation surface.
5. The prosthetic device of claim 1, wherein the
interlock-projection surface includes a substantially arcuate
portion that projects over the proximal portion of the implantation
surface.
6. The prosthetic device of claim 1, wherein the at least one
interlock projection includes an additional interlock-projection
surface configured to receive bone in a space between the
additional interlock-projection surface and a proximal portion of
the implantation surface.
7. The prosthetic device of claim 1, wherein the at least one
recess includes an inner surface and a recess surface, wherein the
recess surface is disposed between the inner surface and a proximal
portion of the implantation surface so as to form a space for
receiving bone between the recess surface and the inner
surface.
8. The prosthetic device of claim 7, wherein the recess surface
includes a substantially planar portion that extends at an obtuse
angle relative to the proximal portion of the implantation
surface.
9. The prosthetic device of claim 7, wherein the recess surface
includes a substantially arcuate portion.
10. The prosthetic device of claim 7, wherein the at least one
recess includes an additional recess surface configured to form a
space for receiving bone between the additional recess surface and
the inner surface.
11. The prosthetic device of claim 1, wherein the at least one
recess includes a sidewall with at least two portions for engaging
bone to constrain the body portion in the at least two
translational degrees of freedom.
12. The prosthetic device of claim 1, wherein the constraint
structure is configured to constrain the prosthetic device in the
bone in the absence of adhesive.
13. The prosthetic device of claim 1, wherein the prosthetic device
is one of a tibial implant and a femoral implant configured to be
implanted in a respective one of a tibia and femur to form a
portion of a knee joint.
14. The prosthetic device of claim 13, wherein the at least one of
the tibial implant and the femoral implant includes a plurality of
the compressive projections projecting from a lateral side portion
of the implantation surface.
15. The prosthetic device of claim 13, wherein the at least one of
the tibial implant and the femoral implant includes the at least
one interlock projection projecting from a bottom side portion of
the implantation surface.
16. The prosthetic device of claim 13, wherein the at least one of
the tibial implant and the femoral implant includes the at least
one recess in a bottom side portion of the implantation
surface.
17. The prosthetic device of claim 1, wherein the prosthetic device
is an acetabular cup configured to be implanted in a pelvis to form
a portion of a hip joint.
18. The prosthetic device of claim 17, wherein the acetabular cup
includes the at least one recess, wherein the at least one recess
includes a sidewall with at least two portions for engaging bone to
constrain the body portion in the at least two translational
degrees of freedom.
19. The prosthetic device of claim 1, wherein the prosthetic device
is a femoral stem configured to be implanted in a femur to form a
portion of a hip joint.
20. The prosthetic device of claim 19, wherein the femoral stem
includes a plurality of the compressive projections projecting from
a lateral side portion of the implantation surface.
21. A method for planning bone removal for implantation of a
prosthetic device into bone, comprising: storing data
representative of a prosthetic device in a computer readable
medium, wherein the prosthetic device includes a body portion
having an implantation surface configured to face the bone upon
implantation and at least one feature that provides a constraint
structure that will constrain the prosthetic device in the bone;
and defining, based on the data, at least one bone-cutting pattern
for (i) removing a first portion of bone in a first area sufficient
to seat the body portion and (ii) at least one of removing and
maintaining a second portion of bone in a second area configured to
interact with the constraint structure.
22. The method of claim 21, wherein the defining of the at least
one bone-cutting pattern includes removing a portion of the second
portion of bone, while maintaining a portion of the second portion
of bone to provide at least one projection configured to engage the
implantation surface to provide a compressive force between the
projection and implantation surface and constrain the prosthetic
device.
23. The method of claim 22, wherein the defining of the at least
one bone-cutting pattern includes maintaining a portion of the
second portion of bone to provide a plurality of projections
configured to engage the implantation surface to provide a
compressive force between the projection and implantation surface
and constrain the prosthetic device.
24. The method of claim 21, wherein the defining of the at least
one bone-cutting pattern includes maintaining a portion of the
second portion of bone to provide a projection that is configured
to project into a recess in the prosthetic device forming at least
a portion of the constraint structure.
25. The method of claim 21, wherein the defining of the at least
one bone-cutting pattern includes removing a portion of the second
portion of bone to provide a recess that is configured to receive a
projection from the prosthetic device forming at least a portion of
the constraint structure.
26. The method of claim 21, further comprising displaying
information representative of the at least one bone-cutting
pattern.
27. A robotic system for preparing a bone to receive a prosthetic
device, the robotic system comprising: a controllable guide
structure configured to guide cutting of the bone into a shape for
receiving the prosthetic device; a computer readable medium for
storing data representative of the prosthetic device, wherein the
prosthetic device includes a body portion having an implantation
surface configured to face the bone upon implantation and at least
one feature that provides a constraint structure that will
constrain the prosthetic device in the bone; and a control system
for controlling the guide structure, wherein the control system is
configured to define at least one bone-cutting pattern for (i)
removing a first portion of bone in a first area sufficient to seat
the body portion and (ii) at least one of removing and maintaining
a second portion of bone in a second area configured to interact
with the constraint structure.
28. The robotic system of claim 27, wherein the control system is
configured to define the at least one bone-cutting pattern by
removing a portion of the second portion of bone, while maintaining
a portion of the second portion of bone to provide at least one
projection configured to engage the implantation surface to provide
a compressive force between the projection and implantation surface
and constrain the prosthetic device.
29. The robotic system of claim 28, wherein the control system is
configured to define the at least one bone-cutting pattern to
maintain a portion of the second portion of bone to provide a
plurality of projections configured to engage the implantation
surface to provide a compressive force between the projection and
implantation surface and constrain the prosthetic device.
30. The robotic system of claim 27, wherein the control system is
configured to define the at least one bone-cutting pattern to
maintain a portion of the second portion of bone to provide a
projection that is configured to project into a recess in the
prosthetic device forming at least a portion of the constraint
structure.
31. The robotic system of claim 27, wherein the control system is
configured to define the at least one bone-cutting pattern to
remove a portion of the second portion of bone to provide a recess
that is configured to receive a projection from the prosthetic
device forming at least a portion of the constraint structure.
32. The robotic system of claim 27, further comprising a display,
wherein the control system displays information representative of
the at least one bone-cutting pattern on the display.
Description
CROSS-REFERENCE TO RELATED PATENT APPLICATIONS
[0001] This application claims priority to U.S. Provisional Patent
Application Ser. No. 61/208,451, filed on Feb. 24, 2009, which is
hereby incorporated by reference in its entirety.
BACKGROUND OF THE INVENTION
[0002] 1. Field of Invention
[0003] The present invention relates to a prosthetic device for
implantation in bone, methods of planning bone removal for
implantation of a prosthetic device in bone, and robotic systems
for preparing a bone to receive a prosthetic device.
[0004] 2. Description of Related Art
[0005] Conventional prosthetic implantation techniques involve
resecting a pocket of material from a bone to provide a void or
pocket within the bone that receives a prosthetic device. After
resection of bone material is complete, the prosthetic device is
implanted within the pocket. The prosthetic device is typically
secured in place with bone cement.
[0006] Using the conventional techniques, undesired movement of the
prosthetic device relative to the bone may occur. In particular,
the pocket in the bone often includes an expansion gap that
provides empty space between the prosthetic device and the
remaining bone. This expansion gap may be filled or partially
filled with bone cement during implantation of the prosthetic
device to permit uniform or near uniform dispersion of the bone
cement. FIG. 34 shows a top view of an example of a conventional
prosthetic device 10 implanted in a medial condyle 12 of a tibia
(the lateral condyle 14 is shown for reference). An expansion gap
16 is provided between the prosthetic device 10 and an edge of the
remaining bone in the medial condyle. The expansion gap, which is
typically 0.5-0.8 mm in a tibia, is exaggerated in this drawing for
purposes of illustration. This expansion gap may cause the
prosthetic device to be less than fully constrained, which can
permit unwanted movement of the prosthetic device. Consequently,
the prosthetic device may move (e.g., rotate or translate) relative
to the bone when a force is applied to the prosthetic device. For
example, during trial articulation of a leg, contact forces from a
femoral condyle can cause unwanted movement of a tibial inlay. In
addition, undesired movement can occur during final fixation as a
surgeon presses against the prosthetic device to disperse the bone
cement and squeeze out excess bone cement.
[0007] Using conventional techniques, it also may be undesirably
difficult to properly position a prosthetic device in the pocket in
the bone. For example, there can be difficulty in positioning the
cup of a hip acetabulum in a desired tilt/abduction and anteversion
due to difficulty in knowing exactly where a pelvis is located
during total hip arthroplasty.
SUMMARY
[0008] An embodiment relates to prosthetic device for implantation
in bone. The prosthetic device includes a body portion for
attachment to a bone, wherein the body portion includes an
implantation surface configured to face the bone upon implantation.
The prosthetic device further includes constraint structure
comprising at least one of: (i) at least one compressive projection
projecting from the implantation surface in a lateral direction of
the body portion and configured to provide a compressive force
between the at least one compressive projection and the bone, (ii)
at least one interlock projection projecting from the implantation
surface and having an interlock-projection surface configured to
receive bone in a space between the interlock-projection surface
and a proximal portion of the implantation surface, and (iii) at
least one recess in the implantation surface and configured to
receive bone to constrain the body portion in at least two
translational degrees of freedom. The constraint structure is
configured to constrain the prosthetic device in the bone.
[0009] Another embodiment relates to a method for planning bone
removal for implantation of a prosthetic device into bone. The
method includes storing data representative of a prosthetic device
in a computer readable medium, wherein the prosthetic device
includes a body portion having an implantation surface configured
to face the bone upon implantation and at least one feature that
provides a constraint structure that will constrain the prosthetic
device in the bone. The method further includes defining, based on
the data, at least one bone-cutting pattern for (i) removing a
first portion of bone in a first area sufficient to seat the body
portion and (ii) at least one of removing and maintaining a second
portion of bone in a second area configured to interact with the
constraint structure.
[0010] Yet another embodiment relates to a robotic system for
preparing a bone to receive a prosthetic device. The robotic system
includes a controllable guide structure configured to guide cutting
of the bone into a shape for receiving the prosthetic device. The
robotic system further includes a computer readable medium for
storing data representative of the prosthetic device, wherein the
prosthetic device includes a body portion having an implantation
surface configured to face the bone upon implantation and at least
one feature that provides a constraint structure that will
constrain the prosthetic device in the bone. The robotic system
further includes a control system for controlling the guide
structure, wherein the control system is configured to define at
least one bone-cutting pattern for (i) removing a first portion of
bone in a first area sufficient to seat the body portion and (ii)
at least one of removing and maintaining a second portion of bone
in a second area configured to interact with the constraint
structure.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011] The accompanying drawings, which are incorporated and
constitute a part of this specification, illustrate embodiments of
the invention and together with the description serve to explain
aspects of the invention.
[0012] FIG. 1 is a perspective view of a prosthetic device
implanted in a pocket in a tibia, according to an embodiment.
[0013] FIG. 2a is a top view of a representation of the pocket and
zones where projections are to be provided in bone, according to an
embodiment.
[0014] FIG. 2b is a top view of a representation of areas of bone
for resection.
[0015] FIG. 2c is a top view of a bone cutting pattern, according
to an embodiment.
[0016] FIG. 2d is a top view of a portion of the tibia of FIG. 1
showing the pocket resected according to the bone cutting pattern
of FIG. 2c.
[0017] FIG. 2e is a top view of the tibia of FIG. 1 with the
prosthetic device in the pocket.
[0018] FIG. 3a is a top view of a portion of a tibia showing an
intended pocket with three projections, according to an
embodiment.
[0019] FIG. 3b is a top view of the tibia of FIG. 3a, showing the
pocket without the prosthetic device.
[0020] FIG. 3c is a top view of the tibia of FIG. 3a with the
prosthetic device in the pocket.
[0021] FIG. 4 is a perspective view of a tibia having a pocket with
vertically oriented projections, according to an embodiment.
[0022] FIG. 5a is a perspective view of a circumferential perimeter
of a pocket, according to an embodiment.
[0023] FIG. 5b is a perspective view of a tibia having the pocket
of FIG. 5a.
[0024] FIG. 5c is a perspective view of a pocket, according to an
embodiment.
[0025] FIG. 5d is a perspective view of the circumferential
perimeter of the pocket of FIG. 5c.
[0026] FIG. 6a shows a perspective view of an exemplary projection,
according to an embodiment.
[0027] FIG. 6b is a top view of the projection of FIG. 6a.
[0028] FIG. 6c is a side view of the projection of FIG. 6a.
[0029] FIG. 6d is a front view of the projection of FIG. 6a.
[0030] FIG. 7a is a side cross-sectional view of a projection
extending only partially along a vertical depth of a pocket,
according to an embodiment.
[0031] FIG. 7b is a side cross-sectional view of a projection
extending 100% of a vertical depth of a pocket, according to an
embodiment.
[0032] FIG. 8a is a side cross-sectional view showing an
interference fit between a prosthetic device and a projection of a
bone, according to an embodiment.
[0033] FIG. 8b is a side cross-sectional view showing an
interference distance for an interference fit between a prosthetic
device and a projection of a bone, according to an embodiment.
[0034] FIG. 9 is a perspective view of a tibia with a horizontally
oriented projection, according to an embodiment.
[0035] FIG. 10 is a side cross sectional view of a femur with a
prosthetic device in a pocket, according to an embodiment.
[0036] FIG. 11a is a top cross sectional view along line A-A of
FIG. 10.
[0037] FIG. 11b is a top cross sectional view along line B-B of
FIG. 10.
[0038] FIG. 12a is a side cross-sectional view of a prosthetic
device in a first stage of implantation, according to an
embodiment.
[0039] FIG. 12b is a side cross-sectional view of the prosthetic
device of FIG. 12a in an advanced stage of implantation.
[0040] FIG. 12c is a side cross-sectional view of the prosthetic
device of FIG. 12a when implanted.
[0041] FIG. 13 is a perspective view of a prosthetic device,
according to an embodiment.
[0042] FIG. 14 is a side view of the prosthetic device of FIG.
13.
[0043] FIG. 15 is a bottom view of the prosthetic device of FIG.
13.
[0044] FIG. 16a is a side cross-sectional view of a prosthetic
device in a first stage of implantation, according to an
embodiment.
[0045] FIG. 16b is a side cross-sectional view of the prosthetic
device of FIG. 16a in an advanced stage of implantation.
[0046] FIG. 16c is a side cross-sectional view of the prosthetic
device of FIG. 16a when implanted.
[0047] FIG. 17a is a top view of a bone with projections for
projecting into recesses of a prosthetic device, according to an
embodiment.
[0048] FIG. 17b is a cross sectional view taken along line A-A in
FIG. 17a with a prosthetic device implanted in the pocket.
[0049] FIG. 18a is a top view of a alternative prosthetic device
that implanted in pocket of the prepared bone of FIG. 17a,
according to an embodiment.
[0050] FIG. 18b is a cross sectional view taken along line B-B in
FIG. 18a.
[0051] FIG. 19a is a top exploded view of a prosthetic device with
recesses and bone projections, according to an embodiment.
[0052] FIG. 19b is a cross sectional view taken along line B-B in
FIG. 19a, with the prosthetic device implanted.
[0053] FIG. 20 is a cross-sectional view of the prosthetic device
of FIG. 19a.
[0054] FIG. 21a is an isometric view of a femur with a pocket
having a projection, according to an embodiment.
[0055] FIG. 21b is a side cross sectional view of the femur of FIG.
21a.
[0056] FIG. 22 is a perspective view of a prosthetic device for
implanting in the pocket of FIG. 21a.
[0057] FIG. 23a is a cross sectional view of a hip bone with a
pocket prepared to receive a prosthetic device, according to an
embodiment.
[0058] FIG. 23b is a cross sectional view of the hip bone of FIG.
23a as a prosthetic device is being inserted into the hip bone.
[0059] FIG. 23c is a cross sectional view of the hip bone of FIG.
23a after the prosthetic device has been implanted into the hip
bone.
[0060] FIG. 24a is a top exploded view of a prosthetic device with
projections and a bone with recesses, according to an
embodiment.
[0061] FIG. 24b is a cross sectional view taken along line C-C in
FIG. 24a, with the prosthetic device implanted.
[0062] FIG. 25a is a top exploded view of a prosthetic device with
projections and a bone with recesses, according to an
embodiment.
[0063] FIG. 25b is a cross sectional view taken along line A-A in
FIG. 25a, with the prosthetic device implanted.
[0064] FIG. 26a is a side view of a prosthetic device, according to
an embodiment.
[0065] FIG. 26b is a top view of the prosthetic device of FIG.
26a.
[0066] FIG. 27 is a top view of bone with a pocket and an implanted
prosthetic device that includes projections, according to an
embodiment.
[0067] FIG. 28a is an isometric view of bone having a projection on
a bottom surface of a pocket, according to an embodiment.
[0068] FIG. 28b is an isometric view of bone having a projection on
a bottom surface of a pocket, according to an embodiment.
[0069] FIG. 28c is an isometric view of bone having a plurality of
projections on a bottom surface of a pocket, according to an
embodiment.
[0070] FIG. 29a is a side view of a prosthetic device with
projections, according to an embodiment.
[0071] FIG. 29b is a side view of a prosthetic device with
projections, according to an embodiment.
[0072] FIG. 30 is an isometric view of a robotic system, according
to an embodiment.
[0073] FIG. 31a is a progression of a bone that has experienced
trauma and been repaired, according to an embodiment.
[0074] FIG. 31b is a close up of a bone fracture that has been
repaired, according to an embodiment.
[0075] FIG. 31c is a view of various constraint structure
geometries, according to an embodiment.
[0076] FIG. 32a is an isometric view of a bone piece prepared to
engage with a hardware component, according to an embodiment.
[0077] FIG. 32b includes a top view and a cross sectional view of a
hardware component, according to an embodiment.
[0078] FIG. 33 is a progression of a bone that has experienced
trauma and been repaired with a component that serves as an
additional bone piece, according to an embodiment.
[0079] FIG. 34 is a top view of a conventional prosthetic device
implanted in a tibia.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
[0080] Presently preferred embodiments of the invention are
illustrated in the drawings. An effort has been made to use the
same or like reference numbers throughout the drawings to refer to
the same or like parts.
Overview
[0081] The preferred embodiments relate, in general, to methods for
planning bone removal to allow implantation of a prosthetic device
to create a constraining relationship between the bone and the
prosthetic device. The preferred embodiments also relate to
prosthetic devices that are configured to achieve such a
constraining relationship and a robotic system that can be used to
facilitate the creation of such a constraining relationship.
[0082] In general, the methods for planning include storing data
representative of the prosthetic device in a computer readable
medium. The methods further include defining, based on the data, at
least one bone-cutting pattern for (i) removing a first portion of
bone in a first area sufficient to seat a body portion of the
prosthetic device and (ii) at least one of removing and maintaining
a second portion of bone in a second area configured to interact
with a constraint structure of the prosthetic device. The method
also may include displaying information representative of the at
least one bone-cutting pattern, for example on a conventional
monitor. Particular implementations of the planning methods are
described below, though the invention is not limited to those
particular implementations.
[0083] Particular implementations of prosthetic devices and a
robotic system that are useful with the planning methods also are
described below. However, the invention is not limited to those
particular implementations and the prosthetic devices and robotic
system could be used without the planning methods.
Creating Bone Projections that Provide Compressive Force to
Prosthetic Device
[0084] One such implementation of the planning method includes
defining the bone cutting pattern for removing a first portion of
bone in the first area sufficient to seat a body portion of the
prosthetic device and for maintaining a second portion of bone in
the second area to provide at least one projection of bone
configured to engage an implantation surface of the prosthetic
device to provide a compressive force between the projection and
implantation surface and constrain the prosthetic device. This
compressive force need not be sufficient to deform the projection
or the implantation surface, though it may deform one or both.
[0085] FIGS. 1 and 2e show views of a prosthetic device 90, e.g., a
tibial inlay, implanted in a pocket (or bone cavity) 106 formed by
resecting bone from a tibia 100 pursuant to such a planning method.
The prosthetic device 90 preferably includes a body portion 91 and
an implantation surface 94 configured to face the bone of the tibia
100 upon implantation. In this embodiment, the implantation surface
94 can form a constraint structure 107 of the prosthetic device 90.
The planning method provides bone projections 104 in the pocket 106
that engage the constraint structure 107 to constrain the
prosthetic device 90.
[0086] To achieve such a pocket 106 with projections 104, initially
zones 109 can be identified in which it is desired to locate the
projections 104, as shown in FIG. 2a. In this figure, the anterior
A, posterior P, medial M, and lateral L directions are identified.
Then, based on data representative of the prosthetic device 90, a
bone-cutting pattern is defined for removing a first portion of
bone in a first area 101 within line 162 (see FIG. 2b) sufficient
to seat the body portion 91 of the prosthetic device 90. The
bone-cutting pattern (or another bone cutting pattern) is also
defined to remove portions of bone in a second area 103 (between
lines 161 and 162) while maintaining second portions of bone to
provide the projections 104 that are configured to interact with
the constraint structure 107 of the prosthetic device 90.
[0087] The resulting bone cutting pattern (or patterns) is shown in
FIG. 2c. This bone cutting pattern is designed to provide the
pocket 106 with the projections 104 extending toward the center of
the pocket 106. Bone resection can then be carried out based on
this bone cutting pattern to achieve the pocket 106 with
projections 104, as shown in FIG. 2d.
[0088] As shown in FIG. 2e, the prosthetic device 90 can then be
disposed in the pocket 106. The projections 104 preferably engage
the prosthetic device 90 such that a compressive force is provided
between the prosthetic device 90 and the projections 104 such that
the location and position of the prosthetic device 90 can be
established in the tibia 100 with a relatively high degree of
accuracy and precision. The projections can be provided to minimize
or prevent unwanted movement of a prosthetic device, such as
unwanted translation or rotation of a prosthetic device.
Furthermore, the projections can provide real-time cues to a
practitioner when a trial or final prosthetic device is in place,
such as audial, visual, or tactile cues.
[0089] Due to the engagement of a prosthetic device with the
projections when the prosthetic device is inserted into a location
into bone, an audible sound can be produced, similar to a part
"snapping" into place, the engagement between the prosthetic device
and the bone can be visually checked, and a practitioner can feel
how snugly the engagement between the prosthetic device and the
projections is. Thus, configuration of the prosthetic device and
the engagement of the prosthetic device with the projections
provides a practitioner with enhanced confidence that the
prosthetic device has been located and positioned closely to a
surgical plan.
[0090] Such a pocket 106 can be formed to accommodate bone cement
or other joining substance (referred to generally as adhesive). In
particular, an expansion gap 105 can be maintained between the
prosthetic device 90 and the surface of the tibia 100 so that the
adhesive can flow into the expansion gap 105 to partially or fully
fill the expansion gap 105 to assist in the fixation of the
prosthetic device 90 to the tibia 100.
[0091] The size and location of the projections 104 can be
controlled to provide optimal location and positioning of a
prosthetic device. As shown in the examples of FIGS. 1-2e, a tibia
100 preferably is prepared to provide four projections 104.
[0092] However, fewer projections can be provided. FIGS. 3a-3c show
an embodiment of a portion of a tibia 110 that has been prepared by
resecting bone to provide a pocket 116 that receives a prosthetic
device in a similar manner as the previous embodiment. The
embodiment of FIGS. 3a-3c has only three bone projections 114 that
can engage with a prosthetic device 118 instead of four bone
projections.
[0093] The bone projections 104, 114 can be provided at various
locations to aid in locating and positioning a prosthetic device
90, 118 in the tibia 100, 110. The location of such projections can
be selected based upon, for example, the number of the bone
projections. For example, a greater number of bone projections can
permit a smaller distance between bone projections in relation to
an implantation surface of a prosthetic device, such as a
circumferential surface of a prosthetic device. Other numbers of
bone projections can be provided, such as, for example, five, six,
or more bone projections, which can be selected to affect the
distribution of compressive forces between a prosthetic device and
a bone and to affect the amount of expansion gap provided between
the prosthetic device and the bone. For example, the number of
projections can be selected to provide an advantageous distribution
of forces between a prosthetic device and a bone, such as by
selecting a greater number of projections and a prosthetic device
configured to engage such projections, but a larger-sized expansion
gap, which provides enhanced joining of the prosthetic device to a
bone via bone cement or other fixation substances, indicates a
smaller number of projections. Thus, various considerations must be
accounted for when determining which prosthetic device to use and
the number and size/shape of projections selected.
[0094] Preferably the projections are configured to extend along at
least 1% of the circumferential perimeter 161 of the pocket and not
more than 75% of the circumferential perimeter 161 (see FIG. 2b).
Or more particularly, the horizontal length of a prepared
anatomical structure can extend between 10% and 50% of the
circumferential perimeter 161, or more particularly 20% and 35% of
the circumferential perimeter 161.
[0095] In addition, the size and location of bone projections can
be controlled to affect the compressive force provided between the
bone projections and a prosthetic device and to maximize the amount
of bone tissue that is preserved. The durability of the bone
projections and the prosthetic device can be optimized by
controlling the size and location of bone projections. For example,
the forces between a prosthetic device and a bone can be
distributed and optimized by selecting the configuration of the
prosthetic device and the number and/or size of the projections
that engage the prosthetic device, thus minimizing or preventing
unwanted damage or failure of the prosthetic device or areas of
bone, such as the projections.
[0096] Bone projections can have various geometries, such as, for
example, spheres, cylinders, cones, elliptical tracks, or other
geometrical shapes. In another example, the bone projection can
essentially form a negative mold of a mating surface of a
prosthetic device or a cavity or indentation in bone that
substantially matches the shape of a mating surface of a prosthetic
device. Such bone projections can be three dimensional or two
dimensional in form.
[0097] The orientation of bone projections can also be altered to
affect the engagement between a prosthetic device and a bone. As
shown in the example of FIG. 4, bone projections 122 can be provide
in a bone 120 such that the bone projections 122 extend in a
vertical direction relative to the bone 120. In another example,
bone projections 126 can be prepared in a bone 124 such that the
bone projections 126 extend in a substantially horizontal direction
relative to the bone 124, as shown in the example of FIG. 9.
[0098] In addition, the shape and size of the bone projections can
be altered and selected to affect the engagement between a
prosthetic device and a bone. The proper size of the bone
projections is important not only for the final location and
positioning of a prosthetic device but also for the easy insertion
and removal of a trial prosthetic device during an implantation
procedure so that the constraint of the prosthetic device in a bone
may be assessed before final implantation. Further, the selection
of the size and shape of the bone projections can affect the
location of the bone projections. Thus, the prosthetic devices and
methods described herein advantageously assist in the location and
positioning of trial prosthetic devices and prosthetic devices that
are finally implanted and fixed to bone so that the outcome of a
surgical procedure may be even closer to a surgical plan.
[0099] FIG. 5a shows a perspective view of an exemplary
circumferential perimeter of a pocket 134 prepared in a bone 136,
as shown the example of FIG. 5b. As shown in the example of FIGS.
5a and 5b, the projections formed from the bone 136 can have a
shape that projects into the pocket 134 such that the projections
form a constraining face 130 that engages with the features of a
prosthetic device. The projections can be shaped to have curved
regions 132, such as on lateral sides or edges of the constraining
faces 130 of the projections. Such curved regions 132 can be
utilized to increase the size of the projections to increase the
amount of force the projections may withstand when engaging with a
prosthetic device. The shape of the curved region may be selected
to avoid sharp corners, which can act as stress risers or
multipliers that can lead to damage of projection or joint between
a prosthetic device and a bone. In addition, the corners 138 of the
pocket can be advantageously shaped to avoid sharp corners and to
affect the expansion gap provided between a prosthetic device and
the bone, as shown in FIG. 5c, which shows a corner within an
exemplary pocket 139, and as shown in FIG. 5d, which shows the
circumferential perimeter of the pocket 139, including a corner
138.
[0100] FIG. 6a shows a perspective view of an exemplary projection
140 formed on a surface 142 of a bone such that the projection 140
extends into a pocket 144 formed within the bone. FIG. 6b shows a
top view of the projection of FIG. 6a, FIG. 6c shows a side view of
the projection of FIG. 6a, and FIG. 6d shows a front view of the
projection of FIG. 6a. As shown in the examples of FIGS. 6a-6d, the
projection 140 can have a constraint surface 146 that is configured
to engage with a prosthetic device. The constraint surface 146 can
have a size selected to maximize engagement between a prosthetic
device and the projection 140, and thus minimize or prevent
unwanted movement of the prosthetic device, but also to provide a
properly sized expansion gap between the prosthetic device and the
bone to also constrain the prosthetic device. For example, such a
constraint surface 146 preferably can have a width X of 1 to 15 mm,
1 to 10 mm, 2 to 8 mm, 2 to 5 mm, 2 to 3 mm, or 2 mm or 3 mm, in
order of preference. In another example, the constraint surface can
project from the surrounding surface of bone by a distance of 0.01
to 10 mm, 0.1 to 5 mm, 0.25 to 2 mm, 0.5 to 1 mm, in order of
preference.
[0101] The vertical length of a projection may also be varied to
control the engagement between a prosthetic device and bone, the
amount of expansion gap, and the amount of bone tissue retained
during preparation. As shown in the example of FIG. 7a, a
projection 140 can have a vertical height L1 relative to the total
depth L2 of a pocket provided within a bone. Such a vertical height
L1 of a projection 140 can be expressed as a ratio of the vertical
height L1 of the projection 140 to the total depth L2. Projections
can be prepared such that the projections have a vertical height
ratio of 5 to 100%. FIG. 7b shows an example of a projection 140
with a vertical height L1 that extends 100% of the total depth L2
of a pocket. In another example, projections can have a vertical
height ratio of 10 to 90%, 20 to 80%, 25 to 45%, or 40%, in order
of preference. Alternatively, the vertical height of a projection
can be expressed in terms of a ratio of the vertical height of the
projection to a height of a prosthetic device. For example,
projections can have a vertical height ratio of 10 to 90%, 20 to
80%, 25 to 45%, or 40%, in order of preference. In another example,
each projection can be sized to have a ratio of projection area to
total area of 1 to 99%, 5 to 90%, 5 to 80%, 10 to 50%, 15 to 30%,
in order of preference.
[0102] The prosthetic device and projections are preferably sized
to provide an interference fit or press fit between the constraint
features of the prosthetic device and the projections. FIG. 8a
shows a side view of an exemplary interference fit between a
prosthetic device 150 and a bone 152. Such a prosthetic device 150
can be configured to provide a compliance between the prosthetic
device 150 and the bone 152 so that the compressive forces produced
between the prosthetic device 150 and the bone 152 may be
accommodated by the prosthetic device 150 and the bone 152. Such an
interference fit can be created when an implantation surface 158 of
a prosthetic device 150 and the surface 156 of a bone, such as at a
projection, are oversized such that the surfaces 158, 156 overlap
in a spatial region, such as the region 159 indicated in the
example of FIG. 8a.
[0103] As shown in the example of FIG. 8b, the prosthetic device
150 and the bone 152 can overlap in an interference region 159 over
a distance X1, which can be a distance of, for example, 0.25 to
0.75 mm, 0.33 to 0.66 mm, 0.40 to 0.6 mm, or 0.5 mm, in order of
preference. Alternatively, a prosthetic device and the prepared
anatomical structures of a bone can be configured such that there
is an interference fit of 0 mm between the prosthetic device and
the bone so that the prosthetic device and bone fit together line
to line and substantially without spatial overlap. The surface 156
of a bone 152 can be shaped to accommodate and distribute
compressive forces provided between the bone 152 and a prosthetic
device 150. For example, the surface 156 of the bone 152 that
engages with a prosthetic device 150 can have a rounded or a flat
shape.
[0104] A prosthetic device and the bone projections can be designed
so that compressive forces provided between the prosthetic device
and the bone normally remain with a desired range. The following
formulas can be utilized when designing a prosthetic device and any
prepared anatomical structures:
.sigma..sub.A=F/A,
.sigma..sub.A=E.epsilon.,
[0105] where .sigma..sub.A represents a stress applied to a given
area, F represents a force applied to that area, A represents the
amount of the area, E represents the modulus of the material, and
represents an amount of strain induced in the material. The amount
of stress induced in a prosthetic device or bone can also be a
function of whether a prepared anatomical feature in a bone is a
temporary feature, such as a feature used during trials of a
prosthetic device, or a permanent prepared anatomical feature. For
example, if a prepared anatomical feature is provided as a
permanent feature, a prosthetic device and the prepared anatomical
feature can be designed such that .sigma..sub.A is less than
.sigma..sub.b, which represents the yield strength of the bone. In
another example, the prosthetic device and the prepared anatomical
feature can be designed such that .sigma..sub.A is greater than 0.1
.sigma..sub.b and less than 0.8 .sigma..sub.b, or greater than 0.3
.sigma..sub.b and less than 0.7 .sigma..sub.b. Conversely, if a
prepared anatomical feature of a bone is a temporary feature a
prosthetic device and the prepared anatomical feature can be
designed such that .sigma..sub.A greater than or equal to
.sigma..sub.b. More particularly, the prosthetic device and the
prepared anatomical feature can be designed such that .sigma..sub.A
is less than or equal to 0.5 .sigma..sub.b.
[0106] The circumferential length prepared anatomical features can
be selected to maximize engagement between a prosthetic device and
the prepared anatomical features, and thus minimize or prevent
unwanted movement of the prosthetic device, but also to provide a
properly sized expansion gap between the prosthetic device and a
bone to also constrain the prosthetic device with bone cement or
another joining substance provided in the expansion gap.
[0107] Although the above examples relate to prosthetic devices for
a tibia, the present invention also can be applied to other bones
and joints, such as a hip joint. FIG. 10 is a cross sectional view
of a femur 300 that has been prepared to provide a pocket for a
prosthetic device 302, i.e., a femoral stem, which has been
inserted into an opening formed in the cortical bone 305 of the
femur 300. The prosthetic device 302 can include a body portion
301. According to another example, the prosthetic device can be a
hybrid system that includes a plastic centralizer, although one is
not required for the present invention. For example, the prepared
anatomical structures of the femur 300 can be sufficient to provide
a desired angle for the prosthetic device 302 without additional
components or features to provide a varus/valgus angle that is
accurate and close to a surgical plan.
[0108] The pocket of the femur 300 can be prepared to provide an
expansion gap between the prosthetic device 302 and the femur 300
for bone cement 304 or another joining substance. In addition, the
femur 300 has been prepared to provide one or more prepared
anatomical structures to engage with the prosthetic device 302.
[0109] As shown in FIG. 11a, which is a cross sectional view along
line A-A in FIG. 10, and in FIG. 11b, which is a cross sectional
view along line B-B in FIG. 10, the prepared anatomical structures
can be provided as projections 306 that extend from a surface of
the femur 300 and engage the prosthetic device 302, such as a
constraint structure 307 on an implantation surface 301 of the
prosthetic device 302. The projections 306 can be configured to
engage with the prosthetic device 302 to provide a compressive
force between the projections 306 and the prosthetic device 302.
For example, the prosthetic device can include plurality of
projections that project from a lateral side portion of an
implantation surface of the prosthetic device. According to another
example, the projections can extend vertically, as shown in the
example of FIGS. 10-11b and/or can extend along a circumferential
perimeter of the pocket provided with the femur 300, as discussed
in regard to the examples herein. As shown in the examples of FIGS.
11a and 11b, the projections 306 can be provided as three
projections or four projections that engage a surface of the
prosthetic device 302. In another example, five or more projections
can be provided. The projections 306 can be used to center the
prosthetic device 302 within the pocket of the femur 300 while
providing an expansion gap for the bone cement 304 or other joining
substance.
[0110] The bone projections described above preferably are
permanent, i.e., they remain substantially intact after the
prosthetic device has been fully implanted in the pocket. However,
it is not required that the bone projections be permanent. They
instead could be temporary. For example, the bone projections could
be utilized during a particular phase of surgery to position the
prosthetic device and thereafter eliminated, e.g., crushed. As a
specific example, the bone projections could be used to achieve
initial positioning of the prosthetic device and when a surgeon
drives the prosthetic device into a final implanted position, such
as through an impact force, the bone projections could be
configured to be crushed to allow the prosthetic device to move
into that final implanted position. As a further alternative, the
bone projections could be used to position a trial prosthetic
device and then be crushed when the permanent prosthetic device is
implanted.
Creating Bone Projections that Project into Recesses in Prosthetic
Device
[0111] Another implementation of the planning method includes
defining the bone cutting pattern for removing a first portion of
bone in the first area sufficient to seat a body portion of the
prosthetic device and for maintaining a portion of the second
portion of bone in the second area to provide a projection that is
configured to project into a recess in the prosthetic device
forming at least a portion of the constraint structure.
[0112] In this embodiment, the pocket in the bone can be formed by
a process similar to that described above. However, the bone
surface can be prepared to provide projections that interact with a
constraint structure, i.e., a recess, of a prosthetic device.
[0113] FIG. 12a shows a cross-sectional view of an exemplary
prosthetic device 50 as the prosthetic device 50 is being implanted
into a bone 60. FIG. 12b shows the prosthetic device 50 in an
advanced stage of implantation into the bone 60, and FIG. 12c shows
the prosthetic device 50 after implantation into the bone 60.
[0114] As shown in the example of FIG. 12a, the prosthetic device
50 can include an implantation surface 58 and a constraint
structure that includes a first projection 54 and a second
projection 56 that project from the implantation surface 58 of the
prosthetic device 50 in a lateral direction, as indicated by arrow
L in the example of FIG. 12c, to form a recess 52. The first
projection 54 and the second projection 56 can each be a single,
continuous projection extending around at least a portion of the
circumference of the prosthetic device 50 or include plural,
discrete projections dispersed around the circumference of the
prosthetic device 50. Similarly, the recess 52 can be a single,
continuous channel extending around the circumference of the
prosthetic device 50 or be a plurality of discrete channels
dispersed around the circumference of the prosthetic device 50.
[0115] As shown in the examples of FIGS. 12a-12c, the recess 52 can
receive and engage a projection 62 of the bone 60 to constrain the
prosthetic device 50. Providing such an engagement between the
prosthetic device 50 and the bone 60 permits a practitioner to
"snap" the prosthetic device 50 in place, providing confidence that
the prosthetic device 50 has been implanted substantially according
to a surgical plan while minimizing or preventing unwanted movement
of the prosthetic device 50.
[0116] The bone 60 can have one or more bone projections 62 that
engage with the prosthetic device 50. The bone projection 62 can be
a single, annular bone projection 62 that extends along a portion
or entirety of the circumference of the prosthetic device 50 or be
plural, discrete bone projections 62 dispersed along the
circumference of the prosthetic device 50.
[0117] The recess 52 also can serve as a side cement channel that
is partially or fully filled with bone cement or other fixation
substances during implantation of the prosthetic device 50.
[0118] FIG. 13 shows an example of a prosthetic device 20, i.e., a
tibial inlay, for implantation into a tibia, such as in the
examples discussed immediately above. As shown in the example of
FIG. 13, the prosthetic device 20 can include a body portion 22 for
attachment to a bone and an implantation surface 24 that is
configured to face the bone upon implantation of the prosthetic
device 20. The prosthetic device 20 can include a constraint
structure that enhances the location and positioning of the
prosthetic device 20 during implantation. In the example shown in
FIG. 13, the prosthetic device 20 can include a first projection 26
as a constraint structure. The first projection 26 can project in a
lateral direction of the body portion 22 from the implantation
surface 24 of the prosthetic device 20 so that the first projection
26 is configured to engage with a bone portion, such as a recess or
projection of bone. The prosthetic device 20 may further include a
second projection 28, as shown in the example of FIG. 13 and FIG.
14, which is a side view of the prosthetic device 20 shown in FIG.
13. The second projection 28 may serve as a constraint structure,
alternatively or in addition to the first projection 26 because the
second projection 28 may also project in a lateral direction of the
body portion 22 from the implantation surface 24 of the prosthetic
device 20 so that the second projection 28 is configured to engage
with the prepared features of a bone, such as a recess or channel
shaped to receive the second projection 28.
[0119] The second projection 28 can have a shape that is matched to
the instruments used to prepare a bone surface. For example, the
second projection 28 can have an edge radius that is matched to a
size of an instrument used to prepare a bone surface, such as a
radius of a burr, such as, for example a 6 mm burr. According to
another example, the prosthetic device 20 can be configured such
that all features of the prosthetic device 20 correspond to a
minimal number of instruments to facilitate bone preparation. For
example, the prosthetic device 20 can be configured such that a
single burr, such as, for example, a 6 mm burr, can be used to
prepare a bone for the prosthetic device 20.
[0120] The prosthetic device 20 can include a recess 30, as shown
in the examples of FIGS. 13 and 14. The side recess 30 can be
formed as a recess in the implantation surface 24 that provides a
space for bone cement or another joining substance so that a
relatively large fixation force can be provided between the
prosthetic device 20 and the bone that the prosthetic device 20 is
implanted into. Therefore, the prosthetic device 20 can have a
pullout strength that is comparable to that of onlay designs. Such
a side recess 30 can have a size of, for example, 0.25 to 10 mm,
0.25 to 5 mm, 0.5 to 3 mm, 1 to 2 mm, in order of preference. In
the opposing direction, the same size can be applied. The shape of
the form can be rectangular, circular, dovetail, cylindrical,
arcuate, corrugated, or other appropriate forms, such as those that
could by made by a tool such as a router.
[0121] The prosthetic device 20 can include one or more x-ray
marker pins 34 to assist in the location and positioning of the
prosthetic device 20 during implantation. In addition, a bottom
surface of the prosthetic device 20 can include a recess 38, as
shown in the example of FIG. 15, which shows a cement pocket in the
form of the letter D.
[0122] FIG. 16a shows a cross-sectional view of another exemplary
prosthetic device 70 as the prosthetic device 70 is being implanted
into a bone 80. FIG. 16b shows the prosthetic device 70 in an
advanced stage of implantation into the bone 80 and FIG. 16c shows
the prosthetic device 70 after implantation into the bone 80.
[0123] In the example shown in FIGS. 16a-16c, the prosthetic device
70 includes an implantation surface 72 and a constraint structure.
The constraint structure can be formed by a projection 74
projecting from the implantation surface 72 of the prosthetic
device 70 to form a recess in a side of the prosthetic device 70.
Such a projection 74 can be a single, continuous projection
extending around at least a portion of the circumference of the
prosthetic device 70 or include plural, discrete projections
dispersed around the circumference of the prosthetic device 70.
Such a projection 74 can engage with the bone 80 to constrain the
prosthetic device 70, thus aiding in fixing the prosthetic device
70 to the bone 80 and minimizing or preventing unwanted movement of
the prosthetic device 70.
[0124] The bone 80 can include a bone projection 82, which can be a
single, continuous projection extending around at least a portion
of a circumference of a cavity formed in the bone 80 for the
prosthetic device 70 or can include a plurality of discrete
projections dispersed about the circumference of the cavity in the
bone 80. As shown in the examples of FIGS. 16a-16c, the projection
82 can form a recess 84, which can accommodate the projection 74 of
the prosthetic device 70. Thus, the projection 74 can be configured
to engage with the bone 80 at the recess 84 such that the
prosthetic device 70 is constrained. Similarly, the bone forms a
projection that extends into the recess formed by the projection
74.
[0125] FIG. 17a shows an example of a bone 170 with a prepared
pocket 172. The bone 170 includes projections 174 formed from the
bone and provided within the pocket 172. As shown in FIG. 17b,
which is a cross sectional view along line A-A in FIG. 17a, the
projections 174 can extend vertically into the pocket 172 from a
bottom surface of the prepared pocket 172. Such projections 174 can
be inserted into corresponding recesses or holes in a prosthetic
device to center, locate, and position the prosthetic device within
the pocket 172 and to minimize or prevent unwanted movement of the
prosthetic device.
[0126] FIG. 18a is a top view of an exemplary prosthetic device 180
that can be used with the prepared bone of FIGS. 17a and 17b. As
shown in FIG. 18b, which is a cross sectional view along line B-B
of FIG. 18a, the prosthetic device 180 can include recesses or
holes that receive the bone projections 174 of bone 170. The
prosthetic device 180 can also include a channel or undercut 184
within the bone projections to provide an expansion gap or space
for bone cement or other fixation substance.
[0127] The recesses prepared in a bone and the constraint
structures can also be configured to interlock with one another to
constrain the prosthetic device. For example, FIG. 19a is a top
view of a prosthetic device 200 and a bone 202 that has been
prepared to include one or more interlock projections 204. As shown
in FIG. 19b, which is a cross-sectional view along line B-B of FIG.
19a, the interlock projections 204 can extend vertically upwards
from the bone 202, and the prosthetic device 200 can include one or
more recesses or channels 206 configured to receive the interlock
projections 204, such as by sliding the prosthetic device 200 onto
the bone in the direction indicated by arrow S in FIG. 19a. The
channels 206 can have a shape that is matched to the shape of the
interlock projections 204, as shown in the example of FIGS. 19a and
19b. In another example, the bone projections 204 can have a
dovetail shape or other shape to promote interlocking between a
prosthetic device and bone.
[0128] The recesses or channels 206 in the implantation surface of
the prosthetic device 200 can be configured to receive bone to
constrain the body portion of the prosthetic device 200 in at least
two translational degrees of freedom. For example, the recesses or
channels 206 can be configured constrain the prosthetic device 200
in directions normal to the sliding direction indicated by arrow S
in the example of FIG. 19a.
[0129] The recesses or channels 206 can include at least one
sidewall 221 with portions for engaging bone to constrain the body
portion of a prosthetic device 200 in at least two translational
degrees of freedom. For example, the recesses 206 can include an
inner surface 205 and a recess surface 207, with the recess surface
207 disposed between the inner surface 205 and a proximal portion
203 of an implantation surface of the prosthetic device 200 so as
to form a space 209 for receiving an interlock-projection surface
of the interlock projection 204 of the bone between the recess
surface 207 and the inner surface 205. The recess surface 207
preferably includes a substantially planar portion 211 that extends
at an obtuse angle relative to the proximal portion 203 of the
implantation surface. In another example, the interlock projection
204 includes an additional interlock-projection surface that
contacts an additional recess surface 225 configured to receive
bone in a space between the additional recess surface 225 and the
inner surface 205. In another example, the recess surface 207 can
include a substantially arcuate portion. In another example, a
recess or channel can include an additional recess surface
configured to form a space for receiving bone between the
additional recess surface and the inner surface of the recess or
channel.
[0130] FIG. 20 shows a cross-sectional view of an exemplary
prosthetic device 36 that can be used with the method shown in
FIGS. 19a and 19b. As shown in FIG. 20, the prosthetic device can
include one or more recesses 38 on a bottom surface of the
prosthetic device 36. The recess 38 can be configured to
accommodate bone cement or another joining substance during
implantation of the prosthetic device 36 to enhance location and
positioning of the prosthetic device 36. Thus, the recess 38 may
serve as a constraint structure of the prosthetic device 36, with
the bottom surface of the prosthetic device 36 serving as an
implantation surface. Such a recess 38 can be partially or fully
filled with bone cement or another joining substance during
implantation of the prosthetic device 36.
[0131] The prosthetic device 36 can have one or more x-ray marker
pins 42. Further, the prosthetic device 36 can include a recess or
side cement channel 44, such as the recess discussed above, in
addition to the recess 38. Such a recess 44 can be formed by one or
more projections, as discussed herein.
[0132] In another example, this method can also be applied to a
femur. FIG. 21a shows a femur 290 that has been prepared to provide
a pocket 291 to receive a prosthetic device. The pocket 291 has
been selectively prepared to provide a prepared anatomical
structure 292 that is configured to engage with the prosthetic
device to locate and position the prosthetic device so that
unwanted movement of the prosthetic device is minimized or
prevented. Such a prepared anatomical structure 292 can be a
projection extending from a surface of the femur 290, as shown in
the example of FIG. 21a.
[0133] FIG. 21b shows a side cross sectional view of the femur 290
of FIG. 21a. As shown in FIG. 21b, the femur can be prepared to
provide a plurality of prepared anatomical structures 292 to engage
with a prosthetic device, such as the device 294 of FIG. 22, which
includes one or more constraint structures, such as projections
296, to engage with the anatomical structures 292. The prosthetic
device 294 can include one or more constraint structures 296, as
shown in the example of FIG. 22. The constraint structure 296 can
be a projection extending from a surface of the prosthetic device,
as discussed in regard to the examples herein. Such projections can
engage with a femur to provide a compressive force between the
femur and the prosthetic device. The prosthetic device can be a
total knee prosthetic device, as shown in the example of FIG. 22,
or can be a unicompartmental prosthetic device or a segment of a
total knee or unicompartmental prosthetic device.
[0134] The prepared anatomical structures 292 can be a plurality of
recesses or channels configured to receive and engage with the
features of the prosthetic device. The prepared anatomical
structures 292 can be discrete structures, as shown in the example
of FIG. 21b, or be a single, continuous structure. The prepared
anatomical structures can extend in an anterior-posterior
direction, as shown in the example of FIG. 21b.
[0135] This method can also be applied to acetabular hip prosthetic
devices. In total hip arthroplasty the acetabulum receives a cup
that is typically spherical in form. In an impaction technique the
cup is pressed into a slightly undersized mating form. However, due
to the shape of the cup inclination and/or abduction can occur,
causing implantation to possibly deviate from a surgical plan.
[0136] FIG. 23a shows an example of a portion of hip bone 310 that
includes a prepared pocket 312 for a prosthetic device. The hip
bone 310 can be prepared to include prepared anatomical structures
to engage with the prosthetic device and provide compression forces
between the hip bone and the prosthetic device. For example, the
prepared anatomical structures can be projections 314, as shown in
the example of FIG. 23a.
[0137] A prosthetic device 316 can be configured to include a
constraint structure, such as a projection and/or recess 318, that
engages with the prepared anatomical structures of the hip bone
310, as shown in the example of FIG. 23b, which shows the
prosthetic device as it is being inserted into the pocket 312 of
the hip bone 310. FIG. 23c shows the prosthetic device 316 after
implantation is complete. According to an example, an end 317 of
the prosthetic device 316 can engage with one or more of the
projections 314 of the hip bone 310, as shown in FIGS. 23b and 23c.
According to another example, the prosthetic device includes at
least one recess 319 that includes a sidewall 313 with at least two
portions for engaging the hip bone 310 to constrain a body portion
of the acetabular cup in at least two translational degrees of
freedom.
[0138] By providing the constraint structures in the prosthetic
device 316 and the prepared anatomical features in the hip bone
310, the prosthetic device 316 can be located and positioned in the
hip bone with minimal or no deviation from a surgical plan due to
unwanted movement of the prosthetic device 316. In addition, the
constraint structures in the prosthetic device 316 and the prepared
anatomical features in the hip bone 310 can provide a controlled
placement of the prosthetic device 316 within the hip bone 310,
thus increasing confidence that implantation of the prosthetic
device 316 has occurred according to a surgical plan.
Creating Bone Recess to Receive Projections from Prosthetic
Device
[0139] Another implementation of the planning method includes
defining the bone cutting pattern for removing a first portion of
bone in the first area sufficient to seat a body portion of the
prosthetic device and for removing a portion of the second portion
of bone in the second area to provide a recess that is configured
to receive a projection from the prosthetic device forming at least
a portion of the constraint structure. For example, a constraint
structure of a prosthetic device can include at least one interlock
projection projecting from an implantation surface and having an
interlock-projection surface configured to receive bone in a space
between the interlock-projection surface and a proximal portion of
the implantation surface.
[0140] FIG. 24a is a top view of a prosthetic device 210 and a bone
212 that has been prepared to include one or more recesses or
channels 214, according to another example. The prosthetic device
210 includes one or more interlock projections 216 that project
from an implantation surface 215 of the prosthetic device 210. As
shown in FIG. 24b, which is a cross sectional view along line C-C
of FIG. 24a, the interlock projections 216 of the prosthetic device
210 can be inserted into the channels 214 of the bone 212, such as
by sliding the prosthetic device 210 towards the bone 212 from a
lateral side of the bone 212, as indicated by arrow S in FIG. 24a.
As shown in the example of FIGS. 24a and 24b, the prosthetic device
210 can be configured to include an interlock-projection surface
217 that is configured to receive bone in a space 219 between the
interlock-projection surface 219 and a proximal portion 213 of the
implantation surface. The interlock-projection surface 217 can
include a substantially planar portion 229 that extends over the
proximal portion at an acute angle relative to the proximal portion
213 of the implantation surface. The interlock-projection surface
219 can alternatively include a substantially arcuate portion
227.
[0141] FIG. 25a is a top view of a prosthetic device 194 and a bone
190 that has been prepared to include one or more recesses or
channels 192, according to another example. The prosthetic device
194 includes one or more interlock projections 196 that project
from an implantation surface 198 of the prosthetic device 194. For
example, the interlock projections 196 can project from a bottom
side portion 223 of the implantation surface 198. As shown in FIG.
25b, which is a cross sectional view along line A-A of FIG. 25a,
the interlock projections 196 of the prosthetic device 194 can be
inserted into the channels 192 of the bone 190, such as by sliding
the prosthetic device 194 towards the bone 190 from a lateral side
of the bone 190, as indicated by arrow S in FIG. 25a. Thus, the
interlock projections 196 and the channels 192 can locate and
position the prosthetic device 194 relative to the bone 190 such
that unwanted movement of the prosthetic device 194 is minimized or
prevented. The interlock projections 196 and the channels 192 can
have dovetail shapes, as shown in the examples of FIGS. 25a and
25b, or other shapes to promote interlocking between a prosthetic
device and bone.
[0142] As shown in the example of FIGS. 25a and 25b, the prosthetic
device 194 can be configured to include an interlock-projection
surface 197 that is configured to receive bone in a space 195
between the interlock-projection surface 197 and a lower portion
199 of the implantation surface. The interlock-projection surface
197 can include a substantially planar portion that projects over
and extends at an acute angle relative to the lower portion 199 of
the implantation surface, as shown in the example of FIGS. 25a and
25b.
[0143] The recesses or channels in the implantation surface of the
prosthetic device can be configured to receive bone to constrain
the body portion of the prosthetic device in at least two
translational degrees of freedom. For example, the recesses or
channels can be configured constrain the prosthetic device in
directions normal to the sliding direction indicated by arrow S in
the examples of FIGS. 24a and 25a.
[0144] The recesses or channels and projections described above in
regard to FIGS. 24a, 24b, 25a, and 25b can be used with a bone
cement or other joining substance to fix a prosthetic device to a
bone. Alternatively these recesses or channels and projections can
be used to constrain a prosthetic device in the bone in the absence
of bone cement or other adhesive substance.
[0145] FIG. 26a shows another example of a prosthetic device 328,
i.e., an acetabular cup, with a plurality of constraint structures,
which can be a plurality of vertically extending projections 330,
as shown in FIG. 26a and FIG. 26b. The projections shown in FIGS.
26a and 26b can be configured to engage with the prepared
anatomical features of hip bone to provide desired positioning
between the projections and the prepared anatomical features.
[0146] In another example, the recesses or channels can include a
sidewall with at least two portions for engaging bone to constrain
the body portion of a prosthetic device in at least two
translational degrees of freedom. The recesses or channels can
include an inner surface and a recess surface, with the recess
surface disposed between the inner surface and a proximal portion
of an implantation surface of the prosthetic device so as to form a
space for receiving bone between the recess surface and the inner
surface. In another example, the recess surface can include a
substantially planar portion that extends at an obtuse angle
relative to the proximal portion of the implantation surface. For
example, the recess surface can be provided in the shape of a
dovetail. In another example, the recess surface can include a
substantially arcuate portion. In another example, a recess or
channel can include an additional recess surface configured to form
a space for receiving bone between the additional recess surface
and the inner surface of the recess or channel.
Receiving Prosthetic Device Having Compressive Projections
[0147] To provide enhanced location and positioning of a prosthetic
device in a bone, a prosthetic device can include a body portion
for attachment to a bone that includes an implantation surface
configured to face the bone upon implantation and a constraint
structure configured to constrain the prosthetic device in the
bone. The constraint structure can include at least one projection
that projects from the implantation surface. Such a projection can
project in a lateral direction of the body portion from the
implantation surface and be configured to provide a compressive
force between the prosthetic device and the bone. Such projections
can create a compressive force by causing the projection to be
compressed, the bone to be compressed, or both the projection and
the bone to be compressed.
[0148] FIG. 27 shows an example of a prosthetic device 510
implanted in a bone 500, such as a tibia. The prosthetic device 510
includes at least one constraint structure, such as a projection
512, that projects from an implantation surface 514 of the
prosthetic device 510 to engage a surface of the bone 500 within a
pocket prepared within the bone 500, providing a compressive force
between the prosthetic device 510 and the bone 500. Such
projections 512 can have different sizes and shapes, as discussed
for the exemplary projections discussed herein, and can be
configured to provide an interference fit with the bone 500. By
providing a compressive force between the prosthetic device 510 and
the bone 500, the location and positioning of the prosthetic device
510 can be aided and unwanted movement of the prosthetic device 510
can be minimized or prevented.
[0149] The projections described in the various embodiments above
preferably are permanent, i.e., they remain substantially intact
after the prosthetic device has been fully implanted in the pocket.
However, it is not required that the projections be permanent. They
instead could be temporary. For example, the projections could be
utilized during a particular phase of surgery to position the
prosthetic device and thereafter eliminated, e.g., crushed. As a
specific example, the projections could be used to achieve initial
positioning of the prosthetic device and when a surgeon drives the
prosthetic device into a final implanted position, such as through
an impact force, the projections could be configured to be crushed
to allow the prosthetic device to move into that final implanted
position.
Providing Projections for Positioning of Prosthetic Device
[0150] According to another example, a bottom surface of a pocket
prepared within a bone can include a prepared anatomical structure
that a prosthetic device is configured to engage such that the
prosthetic device is constrained to minimize unwanted movement. As
shown in the example of FIG. 28a, a pocket 252 can be prepared in a
bone 250 and at least one projection 254 can be formed on a bone
surface 256 of the pocket 252. The projection 254 can be prepared
by selectively removing and maintaining bone tissue to provide a
projection 254 that extends vertically into the pocket 252. The
projection 254 can be a single projection in the shape of a cross,
as shown in the example of FIG. 28a, or be one or more discrete
projections with various shapes.
[0151] A projection 254 can be used to control the depth to which a
prosthetic device is inserted into the pocket 252. For example, the
height of the projection 254 can be designed to control the depth
of the prosthetic device within the pocket 252 and/or to control an
expansion gap for bone cement or other joining substance between
the prosthetic device and the bone 250. Thus, the prosthetic device
can sit or be placed on top of one or more projections 254 within
the pocket 252. In a further example, the projections 254 can
permit a practitioner to prepare the pocket 252 in less time
because the top engaging surfaces of the projections 254 could be
prepared with relatively high precision while the remaining
portions of the bottom surface 256 could be prepared with less
precision, permitting the preparation of the pocket 252 to be
accomplished in less time. In addition, by providing one or more
projections 254 to engage with and support a prosthetic device, any
asperities that would otherwise be present in the bottom surface
256 and their effects on the location and positioning of a
prosthetic device are avoided by supporting the prosthetic device
above the bottom surface 256 on the projection 254.
[0152] FIG. 28b shows another example of a pocket 262 prepared in a
bone 260. The bone 260 has been selectively prepared to provide a
single, continuous, annular projection 264 that extends around a
circumferential perimeter of the bottom surface 266 of the pocket
262. Such a projection 264 can be used to engage with and support a
prosthetic device, as discussed above in regard to the example of
FIG. 28a.
[0153] FIG. 28c shows another example of a pocket 272 prepared in a
bone 270. The bone 270 has been selectively prepared to provide a
plurality of projections 274 that extend vertically upwards from a
bottom surface 276 of the pocket 272. Such projections 274 can
engage with and support a prosthetic device, as discussed above in
regard to the example of FIG. 28a. The projections 274 can have a
top surface 278 that is substantially flat, slightly rounded, or
other shapes to facilitate engagement between the prosthetic device
and the projections.
[0154] FIG. 29a shows an example of a prosthetic device 320, i.e.,
an acetabular cup, that includes a plurality of constraint
structures. As shown in the example of FIG. 29a, the constraint
structures can be a plurality of projections 322 that extend
radially along the outer surface of the prosthetic device 320. Such
projections can be configured to provide a desired position between
the prosthetic device and the bone that the prosthetic device
engages. FIG. 29b shows an example of a prosthetic device 324 that
includes a plurality of horizontally oriented constraint
structures, such as projections 326.
[0155] According to another example, prepared anatomical structures
can be used to aid in the location and/or positioning of prosthetic
devices during implantation in bone. Such prepared anatomical
structures can be used to help locate and/or position one or more
surfaces of a prosthetic device, such as a primary datum surface,
secondary datum surface, and/or tertiary datum surface. For
example, the bone preparation techniques described herein can be
used to provide geometric landmarks in the pelvic region. Such
geometric landmarks can assist in the implantation of a prosthetic
device. For example, prepared anatomical structures can provide
geometric landmarks in the pelvic region that serve as references
that provide positioning information of the pelvis during
implantation of a prosthetic device. In another example, selective
removal or non-removal of bone can be implemented to provide
prepared anatomical structures and a prosthetic device can have
corresponding features, such as surfaces, projections, or recesses,
that engage with or mate with the prepared anatomical structures.
Both types of prepared anatomical features can provide better
positioning of a prosthetic implant and visual verification of the
location of a prosthetic device by surgeon, thus increasing
confidence that implantation of a prosthetic device has been fully
successful.
[0156] The prepared anatomical structures, such as bone
projections, discussed herein can be also be used to locate or
position an instrument instead of, or in addition to, a prosthetic
device. For example, prepared anatomical structures, such as bone
projections, can be used as visual cues when orienting and
positioning a tibial baseplate that includes a keel that must be
accurately inserted into a tibia. The prepared anatomical
structures can also engage with or mate with instruments that guide
and/or place a prosthetic device, such the tibial baseplate with a
keel.
Robotic System
[0157] The planning methods and prosthetic devices described herein
do not require the use of a robotic system. For example, jigs or
similar guiding instruments can be used to assist in the
preparation of bone. However, a robotic system for preparing a bone
to receive a prosthetic device can be particularly beneficial for
practicing the planning methods and implanting the prosthetic
devices. For example, it can increase the accuracy and precision of
bone preparation and the features produced during bone preparation.
FIG. 30 shows an example of a preferred haptic robotic system 600.
Such a robotic system 600 is described in Published U.S. Patent
Application Pub. No. 2009/0000626, which is hereby incorporated
herein by reference in its entirety.
[0158] The robotic system 600 preferably includes a controllable
guide structure configured to guide cutting of the bone into a
shape for receiving the prosthetic device. The controllable guide
structure can include, for example, a robotic arm 610. The robotic
arm 610 is configured to guide a surgeon to control the resection
of bone. As shown in the example of FIG. 30, the robotic arm 610 of
the robotic system can be used to operate on a leg L, which
includes a femur F, and a tibia T, although the robotic system 600
can be used on other bones and joints.
[0159] The robotic system 600 can include a computer 620. The
computer 620 can have a computer readable medium for storing data
representative of the prosthetic device. The computer 620 also can
form at least part of a control system for controlling the guide
structure, e.g., robotic arm 610.
[0160] The control system preferably is configured to define at
least one bone-cutting pattern for (i) removing a first portion of
bone in a first area sufficient to seat the body portion of the
prosthetic device and (ii) at least one of removing and maintaining
a second portion of bone in a second area configured to interact
with the constraint structure. The control system can be configured
to define the various bone-cutting patterns described above in
connection with the planning methods. For example, the control
system may include planning software and information about the
geometry of a prosthetic device, surgical instruments used, and/or
anatomy being prepared, thus providing greater surgical confidence
due to the accuracy and precision of the robotic system. The
software can permit manipulation of a feature plan, which can
include information about the location, orientation, size, and/or
shape of at least one of the prosthetic device and the anatomy
being prepared so that the feature plan can be personalized for the
patient but in conformance with instruments used and the prosthetic
device and its features, including any mating and constraining
features of the prosthetic device.
[0161] The robotic system 600 also may include a display 630 that
is controlled by the control system to display information
representative of the at least one bone-cutting pattern on the
display.
Trauma
[0162] According to another example, the features of the examples
described herein can be provided to bones that have experienced
trauma, such a fracture. FIG. 31a shows a bone 340 undergoing
trauma, such as one or more fractures, causing the bone 340 to be
broken into multiple pieces 342. Such fractures may require
surgery, including reduction and stabilization, such as when a
fracture occurs mid-shaft in a femur. Such surgery requires proper
alignment and orientation of the bone pieces 342.
[0163] As shown in the example of FIG. 31a, the bone pieces 342 can
be prepared to include prepared anatomical structures 344, such as
a recess or channel or a projection, on each bone piece 342 to
provide mating, corresponding structures. For example, a first bone
piece can be provided with a recess or channel while a second bone
piece that mates with the first can be provided with a projection
that engages with or mates with the recess or channel of the first
bone piece. Such corresponding bone pieces can be provided with a
single pair of corresponding structures or a plurality of
corresponding structures, as shown in the example of FIG. 31b,
which shows an enlarged portion of corresponding bone pieces joined
along a fracture line 346. Such structures guide joining of the
bone pieces and assist in the location and positioning of the bone
pieces relative to one another. In addition, the prepared
anatomical structures 344 can serve only as cues to assist in the
alignment and positioning of the bone pieces without acting as
engagement structures. FIG. 31c shows various exemplary geometries
that can be used for the prepared anatomical structures 344, or for
other anatomical structures discussed herein.
[0164] FIG. 32a shows another example of a bone piece 350 that has
been fractured from a bone due to trauma. In this example, the bone
piece 350 has been prepared to include prepared anatomical
structures 352 to engage with a hardware component that assists in
joining bone pieces and healing fractures between the bone pieces.
Such prepared anatomical structures can be, for example, recesses
or channels, as shown in the example of FIG. 32a, or projections
extending from a surface of the bone piece 350 prepared by the
selective preparation of a surface of the bone piece 350. The
prepared anatomical structures 352 can be configured to engage with
constraint structures of a hardware component, such as a fracture
plate 354, as shown in the example of FIG. 32b. For example, the
fracture plate 354 can include projections 356 that can be inserted
into recesses 352 provided in the bone 350, thus guiding insertion
and alignment of the fracture plate 354 relative to the bone piece
350.
[0165] FIG. 33 shows another example of a bone 360 that has been
fractured into multiple bone pieces B. However, due to surgical
preparation of the bone pieces, one piece B may not be suitable for
rejoining or a void may otherwise be created in the assembly of
bone pieces B. An additional piece HB, such as a harvested bone
piece or piece of biocompatible material may be used to replace the
missing piece or void and promote healing of the trauma. The bone
pieces B and additional piece HB can include prepared anatomical
structures and constraint structures discussed in regard to the
examples of FIGS. 31a-32b to assist in the location and positioning
of the bone pieces B and the additional piece HB.
CONCLUSION
[0166] The prosthetic devices, systems, and methods described
herein can be used in various bones, joints, and surgical
techniques. For example, the prosthetic devices, systems, and
methods described herein can be used in full or partial knee
procedures, hip procedures, or shoulder procedures. In addition,
the prosthetic devices, systems, and methods described herein can
be used in spinal procedures, ankle procedures, elbow procedures,
wrist procedures, hand procedures, foot procedures, dental
procedures, such as maxilla and mandible operations, and trauma
procedures.
[0167] The prosthetic devices discussed herein can be fixed to bone
with a cement or other substance, such as, hydroxyapatite (HA)
(collectively referred to as adhesive herein). In another example,
the prosthetic devices discussed herein can be fixed to bone via a
mechanical connection or interlock that does not require a cement
or adhesive substance. For example, a prosthetic device can include
a porous surface that has a microscopic texture that mechanically
joins to a surface of a bone. The features and examples discussed
above for hip prosthetic devices can also be applied to shoulder
prosthetic devices because these prosthetic devices and bones have
similarities.
[0168] The prosthetic devices discussed herein can be made of any
suitable material, such as, for example, polymer material. The
polymer could be, for example, ultra high molecular weight
polyethylene (UHMWPE).
[0169] Other embodiments of the present invention will be apparent
to those skilled in the art from consideration of the specification
and practice of the invention disclosed herein. It is intended that
the specification and examples be considered as exemplary only.
* * * * *