U.S. patent application number 17/149871 was filed with the patent office on 2021-06-03 for continuous compression fixation device for the fusion of an intercalary structural augment.
The applicant listed for this patent is Pressio, Inc.. Invention is credited to John Kent ELLINGTON, Daniel LEAS.
Application Number | 20210161671 17/149871 |
Document ID | / |
Family ID | 1000005387074 |
Filed Date | 2021-06-03 |
United States Patent
Application |
20210161671 |
Kind Code |
A1 |
ELLINGTON; John Kent ; et
al. |
June 3, 2021 |
CONTINUOUS COMPRESSION FIXATION DEVICE FOR THE FUSION OF AN
INTERCALARY STRUCTURAL AUGMENT
Abstract
A continuous compression fixation device for coupling a first
bony structure to a second bony structure, including: a body
structure; and a plurality of arm structures extending from the
body structure, wherein at least one of the plurality of arm
structures is configured to be coupled to the first bony structure
and at least one opposed one of the plurality of arm structures is
configured to be coupled to the second bony structure; wherein the
body structure and the plurality of arm structures are manufactured
from a shape memory material; and wherein tips of the at least one
of the plurality of arm structures and the at least one opposed one
of the plurality of arm structures are biased towards one another
such that a desired compressive force is applied to an intercalary
structural augment disposed between the first bony structure and
the second bony structure.
Inventors: |
ELLINGTON; John Kent;
(Charlotte, NC) ; LEAS; Daniel; (Huntersville,
NC) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Pressio, Inc. |
Atlanta |
GA |
US |
|
|
Family ID: |
1000005387074 |
Appl. No.: |
17/149871 |
Filed: |
January 15, 2021 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
15919829 |
Mar 13, 2018 |
10918484 |
|
|
17149871 |
|
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
A61B 17/0642 20130101;
A61B 2017/0645 20130101; A61F 2002/285 20130101; A61B 2017/00867
20130101; A61B 2017/681 20130101; A61B 2017/0641 20130101; A61F
2002/30092 20130101; A61F 2/2846 20130101; A61F 2/447 20130101;
A61B 2017/0647 20130101 |
International
Class: |
A61F 2/28 20060101
A61F002/28; A61F 2/44 20060101 A61F002/44; A61B 17/064 20060101
A61B017/064 |
Claims
1. A continuous compression fixation system adapted to couple a
first bony structure to a second bony structure, comprising: an
intercalary structural augment for insertion between the first bony
structure and the second bony structure; a body structure
manufactured from a shape memory alloy and comprising four outer
edges and four corners; and four arm structures adapted to couple
the body structure to the first bony structure and the second bony
structure, wherein: each arm structure is coupled to and extends
from the body structure from one of the four corners; and the shape
memory material is adapted to provide a compressive force and
resist a torsional force between the first bony structure and the
second bony structure when the body structure and the four arm
structures are deflected from a first configuration to a second
configuration and subsequently released.
2. The continuous compression fixation system of claim 1, wherein
the compressive force is applied to the intercalary structural
augment disposed between the first bony structure and the second
bony structure.
3. The continuous compression fixation system of claim 2, wherein
the body structure is coupled to the intercalary structural augment
disposed between the first bony structure and the second bony
structure.
4. The continuous compression fixation system of claim 1, wherein
the body structure comprises eight arcs.
5. The continuous compression fixation system of claim 3, wherein
each of the eight arcs is formed by one of the four outer edges and
one arm structure of the four arm structures.
6. The continuous compression fixation system of claim 1, wherein
the body structure and the four arm structures are manufactured
from a nitinol shape memory alloy.
7. The continuous compression fixation system of claim 1, wherein
each of the four arm structures comprise one or more friction
structures for securely retaining a respective arm structure in a
hole drilled into a bony structure.
8. The continuous compression fixation system of claim 1, wherein
the body structure comprises at least one exterior side surface
forming a concave transition between an arm structure of the four
arm structures and at least one opposed arm structure.
9. The continuous compression fixation system of claim 8, wherein
each of the four arm structures comprises a tip.
10. The continuous compression fixation system of claim 9, wherein:
a first arm structure of the four arm structures comprises a first
tip; a second arm structure of the four arm structures comprises a
second tip; and the first tip and the second tip are biased towards
one another relative to a perpendicular orientation with respect to
the body structure by a compressive force generated in a proximity
of where each of the first arm structure and second arm structure
are coupled.
11. The continuous compression fixation system of claim 10, wherein
the first tip is tapered for insertion into a hole drilled into a
bony structure.
12. The continuous compression fixation system of claim 11, wherein
each of the four arm structures comprises one or more friction
structures for securely retaining each arm structure in the hole
drilled in the associated bony structure.
13. A continuous compression fixation system adapted to couple a
first bony structure to a second bony structure, comprising: an
intercalary structural augment for insertion between the first bony
structure and the second bony structure; a body structure
manufactured from a shape memory alloy; and two or more arm
structures adapted to couple the body structure to the first bony
structure and the second bony structure, wherein: each arm
structure is coupled to and extends from the body structure; and
the shape memory material is adapted to provide a compressive force
and resist a torsional force between the first bony structure and
the second bony structure when the body structure and the two or
more arm structures are deflected from a first configuration to a
second configuration and subsequently released.
14. The continuous compression fixation system of claim 13, wherein
the compressive force is applied to the intercalary structural
augment disposed between the first bony structure and the second
bony structure.
15. The continuous compression fixation system of claim 14, wherein
the body structure is coupled to the intercalary structural augment
disposed between the first bony structure and the second bony
structure.
16. The continuous compression fixation system of claim 15, wherein
the body structure comprises an arc is formed by one outer edge and
one arm structure of the two or more arm structures.
17. The continuous compression fixation system of claim 13, wherein
the body structure and the two or more arm structures are
manufactured from a nitinol shape memory alloy.
18. The continuous compression fixation system of claim 13, wherein
each of the two or more arm structures comprise one or more
friction structures for securely retaining a respective arm
structure in a hole drilled into a bony structure.
19. The continuous compression fixation system of claim 13, wherein
the body structure comprises at least one exterior side surface
forming a concave transition between an arm structure of the two or
more arm structures and at least one opposed arm structure.
20. The continuous compression fixation system of claim 13, wherein
each of the two or more arm structures comprises a tip.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of, and claims priority
to, U.S. patent application Ser. No. 15/919,829, filed Mar. 13,
2018, entitled "CONTINUOUS COMPRESSION FIXATION DEVICE FOR THE
FUSION OF AN INTERCALARY STRUCTURAL AUGMENT", which is incorporated
herein by reference in its entirety.
FIELD
[0002] The present invention relates generally to a continuous
compression fixation device for the fusion of an intercalary
structural augment. More specifically, the present invention
relates to a continuous compression fixation device, such as a
surgical staple or the like, manufactured from a metallic or
non-metallic shape memory material, such as nitinol (i.e.
nickel-titanium) or the like, for the fusion of an intercalary
structural augment, such as an intervertebral cage and/or bone
graft in an intervertebral fusion, for example. The continuous
compression fixation device of the present invention finds
applicability in any bony structure fixation application in which
restraint of rotational displacement and continuous compressive
force are both desired, especially when an intercalary structural
augment is present between the adjoined bony structures (e.g. foot,
ankle, lower extremity, upper extremity, hand, craniomaxofacial,
etc. applications) In the intervertebral fusion, for example, the
continuous compression fixation device advantageously provides
continuous compressive force over the middle column of the
vertebral axis. Multiple levels of instrumentation are also
contemplated herein.
BACKGROUND
[0003] In intervertebral fusion, for example, intervertebral
structural augmentation after discectomy for spinal column
decompression and subsequent fusion has long been a preferred
procedure. Such intervertebral structural augments have varied from
autologous free-fibular strut grafts to allografts to metallic
cages to synthetic cages with spaces for bone grafts that increase
the rate of fusion. Additional stabilizing instrumentation has also
been found to increase the rate of fusion. The mainstays of such
stabilizing instrumentation include anterior cervical plates
coupled to the anterior or front column of the vertebral axis,
lateral lumbar plates, and rod-screw constructs coupled to the
posterior or back column of the vertebral axis, for example. Each
of these modalities provides rigid fixation and minimizes motion
and settling, however none of the modalities provides continuous
compression, especially across the associated intervertebral
structural augment over the middle column of the vertebral axis.
Some of the modalities allow for a predetermined amount of
compressive force to be applied initially via mechanical
constructs, but this compressive force is diminished with time as
settling and/or remodeling of the vertebral endplates occur. A
similar situation exists in other anatomical applications.
[0004] Direct bony compression has long been identified as critical
to achieving primary bone healing and arthrodesis for fusions. This
direct bony compression allows for cutting cone bone formation in
the absence of the micro-motion that occurs with non-rigid
fixation. In foot and ankle surgery, for example, shape memory
alloy staples have been utilized with marked success by providing
direct bone-to-bone osteosynthesis. However, such shape memory
alloy staples do not properly allow for intercalary structural
augments and do not correspondingly apply continuous compressive
force in the right place(s). The continuous compression fixation
device of the present invention remedies these shortcomings.
[0005] In general, osseous fusion depends on three distinct
physical conditions: bony apposition, strain/stability, and
pressure. For primary bone-to-bone healing, these physical
conditions allow for new osteon formation through cutting cones and
Haversian remodeling. The spine presents a unique environment for
iatrogenic fusion. Patients whose pathology dictates an
intervertebral fusion mass in their treatment algorithm undergo
preparation of the vertebral endplates to accept an intercalary
structural augment, again typically consisting of an autologous
free-fibular strut graft to a synthetic cage with a space for a
bone graft that increases the rate of fusion. Once a graft is
placed, for example, a surgeon has the option of instrumenting the
fusion or leaving it as is in an in-situ fashion. Again, such
instrumentation typically includes anterior cervical plates coupled
to the anterior or front column of the vertebral axis, lateral
lumbar plates, and rod-screw constructs coupled to the posterior or
back column of the vertebral axis, for example. Each of these
modalities provides rigid fixation and minimizes motion and
settling, however none the modalities provides continuous
compression, especially across the associated intervertebral
structural augment over the middle column of the vertebral axis.
Existing shape memory alloy staples designed for foot and ankle
applications do not properly allow for intercalary structural
augments and do not correspondingly apply continuous compressive
force in the right place(s). Again, the continuous compression
fixation device of the present invention remedies these
shortcomings.
BRIEF SUMMARY
[0006] In various exemplary embodiments, the present invention
provides a continuous compression fixation device, such as a
surgical staple or the like, manufactured from a metallic or
non-metallic shape memory material, such as nitinol (i.e.
nickel-titanium) or the like for the fusion of an intercalary
structural augment, such as an intervertebral cage and/or bone
graft in an intervertebral fusion, for example. The continuous
compression fixation device of the present invention finds
applicability in any bony structure fixation application in which
restraint of rotational displacement and continuous compressive
force are both desired, especially when an intercalary structural
augment is present between the bony structures. This includes, but
is not limited to, opening wedge osteotomies with tricortical
auto/allograft and/or deformity correction with intercalary
structural augmentation. In intervertebral fusion, for example, the
continuous compression fixation device advantageously provides
continuous compressive force over the middle column of the
vertebral axis. Multiple levels of instrumentation are also
contemplated herein.
[0007] In one exemplary embodiment, the present invention provides
a continuous compression fixation device for coupling a first bony
structure to a second bony structure, including: a body structure;
and a plurality of arm structures coupled to and extending from the
body structure, wherein at least one of the plurality of arm
structures is configured to be coupled to the first bony structure
and at least one opposed one of the plurality of arm structures is
configured to be coupled to the second bony structure; wherein the
body structure and the plurality of arm structures are manufactured
from a shape memory material; and wherein tips (and other portions)
of the at least one of the plurality of arm structures and the at
least one opposed one of the plurality of arm structures are biased
towards one another relative to a perpendicular orientation with
respect to the body structure thereby providing a compressive force
between the first bony structure and the second bony structure.
Preferably, the tips (and other portions) of the at least one of
the plurality of arm structures and the at least one opposed one of
the plurality of arm structures are biased towards one another
relative to the perpendicular orientation with respect to the body
structure such that a desired compressive force is applied to an
intercalary structural augment disposed between the first bony
structure and the second bony structure. The tips of the at least
one of the plurality of arm structures and the at least one opposed
one of the plurality of arm structures are configured to be
deflected away from one another prior to being coupled to the first
bony structure and the second bony structure, respectively.
Optionally, the continuous compression fixation device further
includes an additional arm structure and an additional opposed arm
structure coupled to and extending from the body structure, wherein
tips of the additional arm structure and the additional opposed arm
structure are biased towards one another relative to the
perpendicular orientation with respect to the body structure
thereby also providing the compressive force between the first bony
structure and the second bony structure. The tips of the at least
one of the plurality of arm structures and the at least one opposed
one of the plurality of arm structures are biased towards one
another relative to the perpendicular orientation with respect to
the body structure by a compressive force generated in a proximity
of where each of the arm structures and the body structure are
coupled. Optionally, the shape memory material includes a shape
memory alloy. Optionally, the shape memory alloy includes nitinol.
Each of the plurality of arm structures includes a tapered tip such
that it may be disposed in a hole drilled into the associated bony
structure. Each of the plurality of arm structures further includes
one or more friction structures such that it is securely retained
in the hole drilled into the associated bony structure. Optionally,
the body structure is coupled to the intercalary structural augment
disposed between the first bony structure and the second bony
structure.
[0008] In another exemplary embodiment, the present invention
provides a method for providing a continuous compression fixation
device for coupling a first bony structure to a second bony
structure, including: providing a body structure; providing a
plurality of arm structures coupled to and extending from the body
structure, wherein at least one of the plurality of arm structures
is configured to be coupled to the first bony structure and at
least one opposed one of the plurality of arm structures is
configured to be coupled to the second bony structure; wherein the
body structure and the plurality of arm structures are manufactured
from a shape memory material; and wherein tips (and other portions)
of the at least one of the plurality of arm structures and the at
least one opposed one of the plurality of arm structures are biased
towards one another relative to a perpendicular orientation with
respect to the body structure thereby providing a compressive force
between the first bony structure and the second bony structure
deflecting the tips of the at least one of the plurality of arm
structures and the at least one opposed one of the plurality of arm
structures away from one another; coupling the at least one of the
plurality of arm structures to the first bony structure and the at
least one opposed one of the plurality of arm structures to the
second bony structure; and releasing the tips of the at least one
of the plurality of arm structures and the at least one opposed one
of the plurality of arm structures to provide the compressive force
between the first bony structure and the second bony structure.
Preferably, the tips (and other portions) of the at least one of
the plurality of arm structures and the at least one opposed one of
the plurality of arm structures are biased towards one another
relative to the perpendicular orientation with respect to the body
structure such that a desired compressive force is applied to an
intercalary structural augment disposed between the first bony
structure and the second bony structure. Optionally, the method
further includes providing an additional arm structure and an
additional opposed arm structure coupled to and extending from the
body structure, wherein tips of the additional arm structure and
the additional opposed arm structure are biased towards one another
relative to the perpendicular orientation with respect to the body
structure thereby also providing the compressive force between the
first bony structure and the second bony structure. The tips of the
at least one of the plurality of arm structures and the at least
one opposed one of the plurality of arm structures are biased
towards one another relative to the perpendicular orientation with
respect to the body structure by a compressive force generated in a
proximity of where each of the arm structures and the body
structure are coupled. Optionally, the shape memory material
includes a shape memory alloy. Optionally, the shape memory alloy
includes nitinol. Each of the plurality of arm structures includes
a tapered tip such that it may be disposed in a hole drilled into
the associated bony structure. Each of the plurality of arm
structures further includes one or more friction structures such
that it is securely retained in the hole drilled into the
associated bony structure. Optionally, the body structure is
coupled to the intercalary structural augment disposed between the
first bony structure and the second bony structure.
[0009] In a further exemplary embodiment, a continuous compression
fixation device is provided in which some or all of the plurality
of arm structures are replaced with conventional locking or
non-locking fixed or variable angle bone screws. The remaining arm
structures, if any, operate as before. In the case where all of the
arm structures 18 are replaced by bone screws, compressive force is
provided solely by the shape memory material body structure itself,
which acts on the coupled bony structures through the bone
screws.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] The present invention is illustrated and described herein
with reference to the various drawings, in which like reference
numbers are used to denote like device components/method steps, as
appropriate, and in which:
[0011] FIG. 1 is a perspective view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in a deployed configuration,
[0012] FIG. 2 is a perspective view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in an expanded configuration,
[0013] FIG. 3 is a front planar view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in an implanted and deployed configuration,
[0014] FIG. 4 is a side planar view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in an implanted and deployed configuration;
[0015] FIG. 5 is a perspective view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in an expanded configuration;
[0016] FIG. 6 is a perspective view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in an expanded configuration being implanted with an intervertebral
cage;
[0017] FIG. 7 is a perspective view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in a deployed configuration implanted with an intervertebral
cage;
[0018] FIG. 8 is a front planar view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in a deployed configuration implanted with an intervertebral
cage;
[0019] FIG. 9 is a side planar view of one exemplary embodiment of
the continuous compression fixation device of the present invention
in a deployed configuration implanted with an intervertebral cage;
and
[0020] FIG. 10 is a side planar view of another exemplary
embodiment of the continuous compression fixation device of the
present invention.
DETAILED DESCRIPTION
[0021] Referring now specifically to FIGS. 1-4, in one exemplary
embodiment, the present invention provides a continuous compression
fixation device 10 for coupling a first bony structure 12 to a
second bony structure 14. The continuous compression fixation
device 10 includes a body structure 16 and a plurality of arm
structures 18 coupled to and extending from the body structure 16
towards the first bony structure 12 and the second bony structure
14. Accordingly, one or more of the plurality of arm structures 18
are configured to be coupled to the first bony structure 12 and one
or more of the plurality of arm structures 18 are configured to be
coupled to the second bony structure 14. In the exemplary
embodiment illustrated, two of the arm structures 18 are associated
with each of the bony structures 12 and 14, although other desired
numbers of the arms structures 18 could be associated with each of
the bony structures 12 and 14 equally.
[0022] The body structure 16 and the plurality of arm structures 18
are manufactured from a shape memory material, such as a shape
memory polymer or a shape memory alloy like nitinol. It will be
readily apparent to those of ordinary skill in the art that any
suitable shape memory material may be utilized provided that it
continuously biases the structure(s) at issue to an original
intended shape after deflection, thereby resisting such deflection
with a reactionary force. By design, the tips 20 of the plurality
of arm structures 18 are biased towards one another relative to a
perpendicular orientation with respect to the body structure 16,
thereby providing a compressive force between the first bony
structure 12 and the second bony structure 14 when the plurality of
arm structures 18 are deflected and coupled to their respective
bony structures 12 and 14. In other words, each of the plurality of
arm structures 18 is intentionally angled inwards in at least one
plane as illustrated and persistently seeks to return to such
configuration despite its state of deflection and what it is
coupled to. Preferably, by design, the tips 20 of the plurality of
arm structures 18 are biased towards one another relative to the
perpendicular orientation with respect to the body structure 16
such that a desired compressive force is applied to an intercalary
structural augment 22 (FIGS. 6, 7, and 9) disposed between the
first bony structure 12 and the second bony structure 14. Again,
the tips 20 of the plurality of arm structures 18 are configured to
be deflected away from one another prior to being coupled to the
first bony structure 12 and the second bony structure 14,
respectively. Thus, the plurality of arm structures 18 are opened
up prior to implantation into appropriate holes drilled into the
first bony structure 12 and the second bony structure 14, for
example, and then released subsequent to implantation. This
provides a desired compressive force between the first bony
structure 12 and the second bony structure 14. This compressive
force is applied (and in fact tailored) to the intercalary augment
structure 22 disposed between the first bony structure 12 and the
second bony structure 14, promoting both fixation and fusion, when
appropriate.
[0023] The tips 20 (and other portions) of the plurality of arm
structures 18 are preferably biased towards one another relative to
the perpendicular orientation with respect to the body structure 16
by a compressive force generated primarily in the proximity of
where each of the arm structures 18 and the body structure 16 are
coupled, at the shoulders 24 of the continuous compression fixation
device 10. In general, it is desirable that the body structure 16
and the plurality of arm structures 18 are integrally formed to
minimize areas in which failure and corrosion can be initiated and
propagate.
[0024] Each of the plurality of arm structures 18 includes a
tapered and/or sharpened tip 20 such that it may be more easily
disposed in the hole drilled into the associated bony structure 12
or 14. Each of the plurality of arm structures 18 further includes
one or more friction structures 26 (e.g. protrusions, barbs, or
threads) such that it is securely retained in the hole drilled into
the associated bony structure 12 or 14.
[0025] Referring now specifically to FIG. 5, one exemplary
embodiment of the continuous compression fixation device 10 of the
present invention is illustrated. In this exemplary embodiment, the
body structure 16 is a substantially planar structure 28 with a
generally rectangular shape that terminates in a raised central
ridge 30 to minimize its anatomical protrusion when the continuous
compression fixation device 10 is implanted in a spinal column or
the like. The body structure 16 may define any number of recesses,
holes, or other openings as desired in a given application. In
general, the plurality of arms structures extend away from the body
structure 16 at an angle of between greater than about 0 degrees
and less than about 45 degrees from perpendicular in a natural or
resting state, with a few degrees past zero degrees preferred. This
natural or resting angular displacement of the plurality of arm
structures 18 is illustrated in one plane along each side of the
continuous compression fixation device 10 and not in the
perpendicular planes along the ends of the continuous compression
fixation device, although such multidimensional angular
displacement of the plurality of arm structures 18 is possible. In
this exemplary embodiment, each of the plurality of arm structures
18 includes a generally tapered tip 20 for insertion purposes and a
plurality of raised barbs 26 for retention purposes. The plurality
of arm structures 18 meet the body structure 16 to form a plurality
of arcs 32 that are designed to enhance conformal anatomical fit in
a given application. As described above, the body structure 16 and
the plurality of arm structures 18 are manufactured from a shape
memory material, such as a shape memory polymer or a shape memory
alloy like nitinol. It will be readily apparent to those of
ordinary skill in the art that any suitable shape memory material
may be utilized provided that it continuously biases the
structure(s) at issue to an original intended shape after
deflection, thereby resisting such deflection with a reactionary
force. Again, in general, it is desirable that the body structure
16 and the plurality of arm structures 18 are integrally formed to
minimize areas in which failure and corrosion can be initiated and
propagate.
[0026] FIGS. 6-9 illustrate the continuous compression fixation
device 10 of the present invention being implanted in a spine 34 of
a patient after an intercalary structural augment 22, such as an
intervertebral cage and/or bone graft, has been implanted into the
prepared intervertebral space 36. FIG. 9 illustrates the
low-profile nature of this installation. Although not specifically
illustrated, the continuous compression fixation device 10 can be
coupled directly to the intercalary structural augment 22, if
desired.
[0027] Thus, the present invention provides continuous compression
across a single-level, or multi-level, osseous segment, with or
without the use of an intercalary cage/graft, with fixation using
staple arms incorporating, in whole or in part, a shape memory
material. The staple is manufactured in a deployed configuration
with acute angles between the staple arms. These are
heated/expanded and placed into a carrying mechanism, and
subsequently deployed into bony structures across the intercalary
structural augment. Once deployed, the staple will reconfigure to
its original shape, providing continuous compression across the
anterior and middle columns of the spine, for example, with most of
the compressive force being directed through the middle column
through the tips of the staple arms. Compression across the middle
column, rather than through an anterior plate, minimizes the
concern for iatrogenic kyphosis in the cervical and lumbar spine,
for example, and focuses the compression more linearly across the
intercalary structural augment.
[0028] It is additionally important to consider rotational strain
across a fusion mass, just as one would consider resistance to
flexion and extension. In that regard, the present invention
incorporates a variety of angular connections to resist torsional
stresses and provide a lower-strain, higher-stability construct
than would typically be seen in existing routine spinal
instrumentation after cyclic loading, for example.
[0029] Because of the conceptual similarity among all iatrogenic
bony fusions, the continuous compression provided by the osseous
staple design of the present invention would work for all bony
fusions with intercalary structural augments. Other exemplary
applications include opening wedge osteotomies with tri-cortical
auto/allograft or other material/device osteotomy filling and
deformity correction with structural augmentation.
[0030] Referring now specifically to FIG. 10, in another exemplary
embodiment, the present invention provides a continuous compression
fixation device 110 in which some or all of the plurality of arm
structures 18 are replaced with conventional locking or nonlocking
fixed or variable angle bone screws 112. The remaining arm
structures 18, if any, operate as before. In the case where all of
the arm structures 18 are replaced by bone screws 1 12, compressive
force is provided solely by the shape memory material body
structure 16 itself, which acts on the coupled bony structures
through the bone screws 112.
[0031] Although the present invention is illustrated and described
herein with reference to preferred embodiments and specific
examples thereof, it will be readily apparent to those of ordinary
skill in the art that other embodiments and examples may perform
similar functions and/or achieve like results. All such equivalent
embodiments and examples are within the spirit and scope of the
present invention, are contemplated thereby for all purposes, and
are intended to be covered by the following non-limiting
claims.
* * * * *