U.S. patent number RE33,348 [Application Number 07/205,128] was granted by the patent office on 1990-09-25 for bone screw.
This patent grant is currently assigned to Zimmer, Inc.. Invention is credited to Jerry L. Lower.
United States Patent |
RE33,348 |
Lower |
September 25, 1990 |
Bone screw
Abstract
A bone screw comprising a shaft having a first set of leading
threads and a second set of trailing threads spaced apart from the
first set of threads by an unthreaded central portion. The second
set of threads are carried externally on a sleeve having a smooth
inner cylindrical surface such that the sleeve is slidable about
the unthreaded shaft portion. A raised lip is provided about the
trailing end of the shaft to retain the sleeve on the shaft. The
first and second set of screw threads are like-handed, but
preferably of different pitch, with the pitch of the first set of
screw threads exceeding that of the second set of screw threads to
effectively hold portions of a fractured bone in compressive
engagement. Provision of the second set of threads on a slidable
sleeve enables the main shaft to slide through the sleeve and back
out of the bone, when absorption occurs such as when the invention
is used to repair a femoral neck fracture. The ability of the main
shaft to back out in a direction opposite the femoral head is an
advantage because if the second set of threads were fixed on the
main shaft, the bone screw would tend to penetrate the femoral head
and enter the joint capsule when absorption occurs, which would
cause interference of the joint articulation and pain to the
patient.
Inventors: |
Lower; Jerry L. (Bourbon,
IN) |
Assignee: |
Zimmer, Inc. (Warsaw,
IN)
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Family
ID: |
26900134 |
Appl.
No.: |
07/205,128 |
Filed: |
June 10, 1988 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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Reissue of: |
795963 |
Nov 7, 1985 |
04640271 |
Feb 3, 1987 |
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Current U.S.
Class: |
606/65; 606/304;
606/308; 606/316; 606/317; 606/328; 606/86R |
Current CPC
Class: |
A61B
17/8685 (20130101); A61B 17/72 (20130101); A61B
17/725 (20130101); A61B 17/742 (20130101) |
Current International
Class: |
A61B
17/86 (20060101); A61B 17/68 (20060101); A61B
17/72 (20060101); A61B 17/74 (20060101); A61B
017/58 () |
Field of
Search: |
;128/92YV,92YT,92Y,92YS,92YP,92YF,92YE |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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WO89/06940 |
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Aug 1989 |
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WO |
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2108229 |
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May 1983 |
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GB |
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Other References
Mecron.RTM. Cannulated Cancellous Screws-advertisement JBJS, Dec.
1983-65-A-Mecron Med. Products, Inc. .
Howmedica.RTM. The Asnis Guided Screw System Brochure &
Surgical Technique, .COPYRGT.Howmedica, Inc., 1981-Howmedica, Inc.
.
Richards.RTM. Cannulated Hip Pin Brochure, .COPYRGT.Richards
Medical Company, 1984. .
"Hip Nails for All Occasions" Raymond G. Tronzo, M.D.-Orthopedic
Clinics of North America-vol. 5, No. 3, Jul. 1974-pp.
479-491..
|
Primary Examiner: Hafer; Robert A.
Assistant Examiner: Rooney; Kevin G.
Attorney, Agent or Firm: Geringer; Margaret L.
Claims
I claim:
1. A bone screw for connecting portions of bone across a fracture
therebetween, comprising:
(a) a shaft comprising a leading end portion including a first set
of uniformly pitched screw threads and an elongated, smooth
unthreaded portion including a central portion and a trailing end
portion;
(b) a sleeve member having a smooth inner cylindrical surface
surrounding the elongated unthreaded portion and being freely
slidable thereabout.Iadd., the bone screw not having any resilient
means between the sleeve member and the unthreaded
portion.Iaddend., the sleeve member including a second set of
uniformly pitched screw threads thereon, the sleeve member adapted
to be positioned substantially about the trailing end portion
spaced apart from the first set of threads by the central
portion;
(c) a retaining means to prevent the sleeve member from sliding off
the shaft; and
(d) a driving means on the trailing end portion to accommodate a
tool for driving the screw.
2. The bone screw of claim 1 wherein the first and second sets of
screw threads are like-handed but of different pitch.
3. The bone screw of claim 2 wherein the pitch of said first set of
screw threads is greater than that of the second set of screw
threads.
4. The bone screw of claim 1 wherein the retaining means includes a
protruding lip about the trailing end of the shaft.
5. The bone screw of claim 1 wherein the shaft has a cannulation
throughout its axial length.
6. The bone screw of claim 1 wherein the driving means includes a
slot in the trailing end of the shaft for accepting a tool.
7. The bone screw of claim 6 wherein the driving means further
includes a slot in the sleeve member. .Iadd.8. A bone screw for
connecting portions of bone across a fracture therebetween,
comprising:
(a) a shaft comprising a leading end portion including a first set
of uniformly pitched screw threads and an elongated, smooth
unthreaded portion including a central portion and a trailing end
portion;
(b) a sleeve member having a smooth inner cylindrical surface
surrounding the elongated unthreaded portion and being freely
slidable thereabout, the sleeve member including a second set of
uniformly pitched screw threads thereon, the sleeve member adapted
to be positioned substantially about the trailing end portion
spaced apart from the first set of threads by the central
portion;
(c) a retaining means to prevent the sleeve member from sliding off
the shaft; and
(d) a driving means on the trailing end portion to accommodate a
tool for driving the screw, and wherein the driving means includes
a slot in the trailing end of the shaft for accepting a tool, and
.Iaddend..[.The bone screw of claim 6.]. wherein the sleeve member
includes a leading edge and a trailing edge and wherein the driving
means further includes a slot in the sleeve member on both the
leading and trailing edges and wherein the threads on the sleeve
member are adapted to cut in both the forward and reverse
directions, enabling the sleeve member to be assembled onto the
shaft with either end being the leading or trailing end. 9. The
bone screw of claim 1 wherein the outside diameter of the second
set of threads is
greater than the outside diameter of the first set of threads. 10.
The bone screw of claim 1 wherein the inner cylindrical surface of
the sleeve member has a uniform diameter throughout providing an
uninterrupted surface to directly slide against the smooth
unthreaded portion of the
shaft. .Iadd.11. A bone screw for connecting portions of bone
across a fracture therebetween, comprising:
(a) a shaft comprising a leading end portion including a first set
of threads and an elongated unthreaded portion extending
therefrom;
(b) a sleeve member having an inner surface surrounding the
elongated unthreaded portion and being freely slidable relative to
the unthreaded portion of the shaft, the bone screw not having any
resilient means between the sleeve member and the unthreaded
portion, the sleeve member including a second set of threads
thereon; and
(c) a means for driving the bone screw. .Iaddend. .Iadd.12. A bone
screw for connecting portions of bone across a fracture
therebetween, comprising:
(a) a shaft comprising a leading end portion including a first set
of threads and an elongated unthreaded portion extending
therefrom;
(b) a sleeve member having an inner surface surrounding the
elongated unthreaded portion and being freely slidable relative to
the unthreaded portion of the shaft, the bone screw not having any
resilient means between the sleeve member and the unthreaded
portion, the sleeve member including a second set of threads
thereon;
(c) a retaining means to prevent the sleeve member from sliding off
the shaft; and
(d) a means for driving the bone screw. .Iaddend. .Iadd.13. A bone
screw for connecting portions of bone across a fracture
therebetween, comprising:
(a) a shaft comprising a leading end portion including a first set
of threads and an elongated unthreaded portion extending
therefrom;
(b) a sleeve member having an inner surface surrounding the
elongated unthreaded portion and being freely slidable in the
longitudinal direction relative to the unthreaded portion of the
shaft, the bone screw not having any resilient means between the
sleeve member and the unthreaded portion, the sleeve member
including a second set of threads thereon; and
(c) a means for driving the bone screw. .Iaddend. .Iadd.14. A bone
screw for connecting portions of bone across a fracture
therebetween, comprising:
(a) a shaft comprising a leading end portion including a first set
of threads and an elongated unthreaded portion extending
therefrom;
(b) a sleeve member having an inner surface surrounding the
elongated unthreaded portion and being freely slidable relative to
the unthreaded portion of the shaft, the sleeve member including a
second set to threads thereon; and
(c) a means for driving the bone screw, and wherein the inner
surface of the sleeve member has a uniform diameter throughout
substantially the entire length of the sleeve member providing an
uninterrupted surface to directly slide against the smooth
unthreaded portion of the shaft.
.Iaddend. .Iadd.15. The bone screw of claim 11 wherein the inner
surface of the sleeve member surrounding the elongated unthreaded
portion of the shaft extends at least one-third of the length of
the sleeve member
providing a bearing surface to slide along the shaft. .Iaddend.
.Iadd.16. A bone screw for connecting portions of bone across a
fracture therebetween, comprising:
(a) a shaft comprising a leading end portion including a first set
of threads and an elongated unthreaded portion extending
therefrom;
(b) a sleeve member having an inner surface surrounding the
elongated unthreaded portion and being freely slidable relative to
the unthreaded portion of the shaft, the sleeve member including a
second set of threads thereon; and
(c) a means for driving the bone screw, and wherein the inner
surface of the sleeve member surrounding the elongated unthreaded
portion of the shaft extends substantially the entire length of the
sleeve member providing a bearing surface to slide along the shaft.
.Iaddend.
Description
BACKGROUND OF THE INVENTION
This invention generally relates to a bone screw for surgically
fastening fractured or severed bone fragments. This invention is
particularly suitable for use as a hip fixation pin for fractures
of the neck of the femur, although is not limited thereto.
The present invention utilizes many of the features of U.S. Pat.
No. 4,175,555 to Herbert which discloses a bone screw having screw
threads which are like-handed but of different pitch on its
respective leading and trailing ends and spaced apart by a smooth,
cylindrical shaft. The pitch of the leading threads may exceed that
of the trailing threads in order to hold the bone fragments in
compressive engagement.
U.S. Pat. No. 3,051,169 to Grath provides a bone screw disclosed as
suitable for use with femoral neck fractures which also includes a
first leading set of threads and a second trailing set of threads
which are indicated to be preferably of the same pitch. The second
set of threads is carried on a sleeve member which fits snugly
around the unthreaded shaft at its inner end, but then for the
remainder of the sleeve's length has a somewhat larger internal
diameter to accommodate a helical spring between the sleeve and the
shaft of the screw. The sleeve carries a spacing ring to center the
sleeve on the shaft. Outside of the ring is another helical spring
which is supported against a nut threadably adjustable on the outer
threaded end of the screw shaft. The disclosure states that by use
of the spring means, the broken bones are forced together to
facilitate and expedite healing.
It is also known to use hip screws which include only one set of
threads on an elongated shaft. Such a screw is often utilized in a
multiple pinning technique, i.e., two or three such screws all
being aligned through the head and neck of the femur for fixation
of a neck fracture. Examples of such pins are illustrated and
disclosed in U.S. Pat. Nos. 3,842,824 and 3,892,232 to Neufeld and
U.S. Pat. Nos. 4,383,527 and 4,450,835 to Asnis.
Another type of fixation device commonly utilized for fractures of
the femoral neck, is a compression hip screw which typically
includes a first angled barrel and plate member and a lag screw
member receivable within the barrel. An example of such a
compression hip screw is shown in U.S. Pat. No. 4,530,355 to
Griggs. Griggs also includes a compression screw which may be
inserted through the barrel and threaded into the back portion of
the lag screw to obtain a tight compression between the lag screw
and the plate/barrel member. Once the desired amount of compression
has been achieved, the compression screw may be removed or left in
place at the option of the surgeon. In the course of time,
absorption takes place near the fractured bone surfaces. Internal
forces act on the lag screw/compression screw assembly, causing it
to back out of the barrel, and thus protrude beyond the
barrel/plate assembly. If the compression screw has been removed,
absorption will still cause the lag screw to back out, but it is
less likely to protrude as far out of the barrel/plate assembly.
Such a compression hip assembly as described above, permits
longitudinal sliding movement between the lag screw and the barrel
due to the forces produced while such absorption occurs. Griggs
also provides a clip which may be optionally insertable into the
barrel to prevent axial rotation of the lag screw with respect to
the barrel member.
It is noted that while a bone screw such as that described in the
previously discussed U.S. Pat. No 4,175,555 to Herbert is very
suitable for fractures such as of the scaphoid and other similar
small bones, if such a screw were used to achieve compression of a
fracture across a femoral neck, absorption could cause the screw to
protrude through the femoral head and into the joint capsule which
would cause pain to the patient. The device would protrude into the
joint capsule as a result of the absorption because as the bone
shortens, it is unable to longitudinally slide out the other end as
with the compression hip screw of Griggs.
OBJECTS OF THE INVENTION
A principle object of this invention is to provide a bone screw
with a first set of fixed threads and second set of threads
provided on a slidable sleeve to be spaced apart from the first set
of threads.
Another object of this invention is to provide a simple bone screw
especially suitable for use in femoral neck fractures which is to
be used without a barrel/plate assembly, and yet which is still
able to provide compression at the fracture site without the
additional complications of springs or other complicated additional
loading mechanisms, and yet which still provides for longitudinal
sliding to enable adjustment when absorption occurs.
SUMMARY OF THE INVENTION
The present invention provides a bone screw including a first set
of fixed threads at its leading end and a second set of threads at
its trailing end spaced from the first set by a smooth cylindrical
shaft. The first and second set of threads are like-handed, but of
different pitch. The pitch of the first set of threads is
preferably greater than that of the second set of threads in order
to effect compression of the bone fragments about the fracture
site. The second set of threads is provided on a sleeve which is
freely slideable on the unthreaded shaft which is particularly
advantageous for use as a hip screw so that the shaft is able to
longitudinally slide within the sleeve to enable adjustment of the
bone screw when absorption occurs due to the internal forces on the
femoral bone joint. The ability of the shaft to longitudinally
slide or back out through the externally threaded sleeve helps to
prevent the bone screw from penetrating into the joint capsule when
absorption occurs. The inner cylindrical surface of the sleeve has
a uniform diameter throughout to provide an uninterrupted, smooth
surface to directly slide against the smooth, unthreaded portion of
the shaft. This interface enables the longitudinal sliding to
occur. Axial rotation also may occur between the sleeve and the
unthreaded shaft.
BRIEF DESCRIPTION OF THE DRAWINGS
These features and objects of the invention as well as others, will
become apparent to those skilled in the art by referring to the
accompanying drawings.
FIG. 1 is an exploded perspective view of a bone screw according to
the present invention;
FIG. 2 is an assembled perspective view of the bone screw of FIG.
1;
FIG. 3 is an end view of the bone screw of FIG. 2;
FIG. 4 is a partial perspective view of the trailing end of the
bone screw of FIG. 2;
FIG. 5 is a cross-sectional view of the trailing end taken along
lines 5--5 of FIG. 3;
FIG. 6 illustrates the upper part of the femur in partial section
with a partially inserted bone screw according to the present
invention.
FIG. 7 illustrates the upper part of the femur with three fully
inserted bone screws according to the present invention.
DETAILED DESCRIPTION OF THE INVENTION
FIGS. 1-7 illustrate a particularly advantageous embodiment of the
bone screw 1 of the present invention. The bone screw 1 is
particularly suitable for and will be described in reference to a
hip screw for fixation of fracture of the femoral neck area,
although it is not limited to such usage.
The bone screw 1 includes a main shaft 2 and a separate sleeve
member 5. The shaft 2 comprising a leading end portion 6 and an
elongated, smooth unthreaded shaft portion 3. The leading end
portion 6 includes a first set of uniformly pitched threads 9. The
unthreaded shaft portion 3 is substantially cylindrical and
includes a central portion 8 and a trailing end portion 7. The
sleeve member 5 surrounds the unthreaded shaft portion 3 and is
freely slidable thereabout. The sleeve member 5 has a smooth inner
cylindrical surface 51. The sleeve member 5 includes a second set
of uniformly pitched threads 10 externally thereon. The sleeve
member 5 is typically positioned on or about the trailing end
portion 7, spaced apart from the first set of threads 9 by the
central portion 8. The outside diameter of the second set of
threads 10 is preferably larger than the outside diameter of the
first set of threads 9.
A protruding lip 20 is provided to prevent the sleeve member 5 from
sliding off the unthreaded shaft portion 3. It is understood that
alternate retaining means other than the protruding lip 20 could be
provided.
A suitable driving means is provided on the trailing end portion 7
to accommodate a suitable tool 30 for driving the bone screw 1. The
driving means may include a first transverse slot 11 in the
trailing end 7 for accepting the corresponding narrow screw driving
protrusion 31 on tool 30. The sleeve 5 may additionally have a
second transverse slot 50 for accepting the corresponding wider
screw driving protrusion 32 on tool 30. The screw may be inserted
or driven with protrusion 31 engaged with slot 11 when slot 11 is
not aligned with slot 50 as in FIG. 4, or both protrusions 31 and
32 may be engaged with slots 11 and 50 respectively when slots 11
and 50 are aligned as in FIG. 2. However, any suitable driving
means and corresponding driving tool may be used with the present
invention. It is noted that the bone screw 1 does not provide a
conventional head on the trailing end, so that the trailing end can
be wholly sunken into the bone into which it is inserted.
The first and second sets of threads 9 and 10 are like-handed but
of different pitch. The pitch of the first threads 9 is preferably
greater than that of the second threads 10 in order to provide a
bone screw 1 which will simply achieve compression of the bone
fragments upon insertion of the bone screw 1. The bone screw 1 may
also be provided with a cannulation 16 throughout main shaft 2 to
enable the bone screw 1 to be inserted over a guide wire 45 by the
surgeon. Such guide wires 45 are well known in the art.
As shown in FIG. 5, the inner cylindrical surface 51 of the sleeve
5 has a uniform diameter throughout and provides an uninterrupted
smooth surface to directly interface with or slide against the
smooth unthreaded portion 3 of the main shaft 2.
The bone screw 1 is utilized as a fixation device to connect
portions of bone across a fracture therebetween. As shown in FIGS.
6 and 7, the bone screw 1 is utilized as a hip screw in the upper
part of a femur 40 to connect the ball head portion 42 to the main
portion of the femur which has been fractured across the neck 43 at
fracture 41.
The bone screw 1 may be manufactured from such materials as
titanium, titanium alloys or 316 LVM stainless steel, although
other suitable biocompatible materials could be utilized. The first
set of threads 9 are formed on an elongated piece of round
cannulated stock and the smooth unthreaded portion 3 turned to
size, leaving the raised lip 20 on the trailing end 7. The slot 11
is then formed in the trailing end 7.
The main shaft 2 may be provided in numerous lengths conveniently
ranging from about 140 mm (5.5 in) to 60 mm (2.4 in). The preferred
outer diameter of the unthreaded shaft portion 3 may be
approximately 5 mm (0.197 in), with the raised lip 20 having about
a 6 mm (0.24 in) diameter and a width of about 1 mm (0.04 in). The
cannulation 16 may be approximately 3 mm (0.12 in) to readily fit
over a 2 to 3 mm (0.08 to 0.12 in) guide wire 35. The inner
diameter of the sleeve 5 is approximately 5.1 mm (0.2 in) to enable
the unthreaded portion to readily slide on the unthreaded shaft
portion 3, but without being too loose. The sleeve 5 may be
approximately 25 mm (1 in) in length. The second set of threads 10
are formed on the tubular stock of the sleeve 5, and a slot 50 is
cut thereon. The second set of threads 10 are formed to cut in both
the forward and reverse directions. A slot 50a may also be formed
on the leading edge of the sleeve 5. With slots 50 and 50a on the
sleeve 5, this enables the sleeve 5 to be installed on the
unthreaded shaft portion 3 without worrying about which end was the
trailing end or the leading end of the sleeve 5 because the sleeve
5 could be put on either way. The sleeve 5 is installed by
mechanically pressing the slot 11 on the trailing end 7 partially
closed and forcing the sleeve 5 over the lip 20. When the pressure
is released the sleeve 5 will be retained on the unthreaded shaft
portion 3.
The thread form of the first set of threads 9 may be defined as a
cancellous thread, preferably with a self-tapping design feature,
while the thread form of the second set of threads 10 may be
defined as a cortical thread form, preferably with a self-tapping
design feature. Slots 50 and 50a eliminate the need for separate
self-tapping cutting flutes on the sleeve 5.
In using the bone screw 1 of the present invention, it is first
necessary to select the appropriate screw length desired. It is
noted that the bone screw 1 is suitable for use in a multiple hip
pinning technique as is known in the art. Thus, the insertion
technique will be described herein for insertion of three bone
screws 1 with reference to FIGS. 6 and 7. However, it is noted that
single or multiple screw fixation may be utilized with the bone
screw 1 of the present invention. However, if a single screw 1 is
used, it may require larger dimensioning for added strength than
that described previously, in particular for the diameter of the
shaft and threads.
For multiple hip pinning, drill the main hole 45 according to
conventional techniques. Insert the first set of threads 9 on the
leading end 6 over a guide pin 35 via the cannulation 16 in the
main shaft 2. A suitable screw-driving tool 30 is utilized to drive
the bone screw 1 into the femur 40. Screw in the bone screw 1 until
the threaded sleeve 5 tightens against the cortex of the femur 40
as shown in FIG. 6. Repeat this step for the other two bone screws
1. The femur 40 should be reduced by the surgeon at this point with
a small gap between the fragments. The slot 50 in the sleeve 5 can
be matched or lined up with the slot 11 in the trailing end 7 to
drive both the sleeve 5 and the main shaft 2 as shown in FIG. 2,
but this is not necessary. The tool 30 may be inserted into only
the slot 11 when not aligned with slot 50 as shown in FIG. 4 upon
insertion of the bone screw 1. A guide tool (not shown) may be used
to align the screws 1 for insertion of multiple screws 1.
Continue to tighten the screws 1 in a pattern sequence to reduce
the fracture 41 evenly. Even if the sleeve slot 50 is not engaged
with the insertion tool 30, the second set of threads 10 will begin
to rotate with the main shaft 2 due to the pressure and friction of
the bone against the sleeve 5. Since the pitch of the leading
threads 9 is greater than that of the trailing threads 10,
compression of the bone fragments will occur, closing the gap at
the fracture 41 and compressing the fragments together in secure
engagement. FIG. 7 illustrates the three fully inserted bone screws
1 across the fractured neck 43 of a femur 40.
Once healing begins to occur and forces begin to act on the hip
joint, absorption of the bone may occur effectively causing a
shortening of the bone at the neck 43. Since the smooth inner
diameter of the sleeve 5 is not engaged to the unthreaded shaft 3,
when this shortening occurs, the forces on the femur cause the
shaft 3 to slide through the sleeve 5. This may cause the trailing
end 7 to slightly protrude out of the femur 40, but this is
desirable rather than having the absorption cause the screw 1 to
penetrate through the head 42 and into the joint capsule which
would occur if the second threads 10 were not longitudinally
slidable on the unthreaded shaft portion 3. The penetration into
the joint capsule is not desirable because it would interfere with
the joint articulation and cause pain.
When the surgeon has determined that healing of the fracture 41 is
complete, the screws 1 may be removed. The main shaft portion 2 of
the screw should be screwed out with an appropriate tool 30. The
sleeve 5 may stay in the femur 40 at this point or be rotated out
with the shaft 2. Screw out the shaft 2 until there is room to
remove the sleeve 5. When there is room, screw the sleeve 5 out on
the unthreaded shaft portion 3 by utilizing both the slots 11 and
slots 50. Then finish removing the main shaft 2 from the femur
40.
The invention described herein is a bone screw 1, particularly
suited for femoral neck features, which incorporates two sets of
spaced apart screw threads 9 and 10, the second set 10 being
provided on the trailing end 7 of the screw 1 on a slidable sleeve
member 5 to allow the unthreaded shaft portion 3 of the screw to
slide through the sleeve and back out of the femur in a direction
opposite the head 42 of the femur when absorption occurs during the
healing process. While this invention has been described and
exemplified in terms of a particularly advantageous embodiment,
those skilled in the art can appreciate that modifications can be
made without departing from the spirit and scope of this
invention.
* * * * *