U.S. patent application number 15/677122 was filed with the patent office on 2017-11-30 for telescopic strut for an external fixator.
The applicant listed for this patent is Stryker European Holdings I, LLC. Invention is credited to Joel Bouquet, Philippe Lehmann.
Application Number | 20170340357 15/677122 |
Document ID | / |
Family ID | 52001611 |
Filed Date | 2017-11-30 |
United States Patent
Application |
20170340357 |
Kind Code |
A1 |
Lehmann; Philippe ; et
al. |
November 30, 2017 |
TELESCOPIC STRUT FOR AN EXTERNAL FIXATOR
Abstract
A telescopic strut for use with an external fixator comprising
an axially extending rod; an axially extending tube moveably
recurring the rod for varying the length of the rod and tube
combination along a longitudinal axis; the tube having first and
second ends, the second end having a pin extending therethrough; a
locking system mounted on the tube first end for adjusting the
position of the rod in the tube and fixing the length of the rod
and tube combination; a coupling element having a tubular sleeve
with a threaded outer surface mounted on an outer surface of the
second end of the tube, the sleeve having two diametrically opposed
slots receiving the pin and an adjustment element threadably
mounted on the sleeve outer surface for axial movement along the
axis, the adjustment element having a surface contacting the pin to
limit the movement of the pin in the slots.
Inventors: |
Lehmann; Philippe;
(Lamboing, CH) ; Bouquet; Joel; (Solothurn,
CH) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Stryker European Holdings I, LLC |
Kalamazoo |
MI |
US |
|
|
Family ID: |
52001611 |
Appl. No.: |
15/677122 |
Filed: |
August 15, 2017 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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14549949 |
Nov 21, 2014 |
9763694 |
|
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15677122 |
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13589624 |
Aug 20, 2012 |
8906021 |
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14549949 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
A61B 17/66 20130101;
A61B 17/62 20130101 |
International
Class: |
A61B 17/66 20060101
A61B017/66; A61B 17/62 20060101 A61B017/62 |
Claims
1. (canceled)
2. A system for adjusting a relative orientation of a pair of
spaced rings of an external fixator, comprising; a rod extending
between a first end and a second end along a first axis; a tubular
element extending between a first end and a second end along the
first axis, the first end of the tubular element for receiving the
first end of the rod; a first coupling element attached to the
second end of the rod for coupling the rod to one of the pair of
spaced rings, the first coupling element comprising: a tube having
a first end and a second end opposite the first end, the first end
of the tube being fixed to the second end of the rod, the second
end of the tube having an outer part-spherical surface and an inner
part-spherical recess; a shaft extending from a first end to a
second end, the second end of the shaft having a part-spherical
recess that at least partially overlies and is in contact with the
outer part-spherical surface of the tube; and a nut extending from
a first end to a second end, the first end of the nut being
positioned within the second end of the tube and having an outer
part-spherical surface in contact with the part-spherical recess of
the tube, the second end of the nut being positioned within the
second end of the shaft, the shaft and the nut each being
articulable with respect to the tube; and a second coupling element
attached to the second end of the tubular element for coupling the
tubular element to the other of the pair of spaced rings.
3. The system of claim 2, wherein the outer part-spherical surface
of the tube includes a roughened area.
4. The system of claim 3, wherein the roughened area includes
ridges.
5. The system of claim 2, wherein the first coupling further
includes a tightening element extending at least partially through
a bore in the shaft and a bore in the nut.
6. The system of claim 5, wherein the first coupling element has a
loosened condition in which the shaft and the nut are each
articulable with respect to the tube, and a tightened condition in
which the shaft and the nut are locked from articulating with
respect to the tube.
7. The system of claim 6, wherein in the loosened condition of the
first coupling element, the nut has a first position relative to
the tightening element, and in the tightened condition of the first
coupling element, the nut has a second position relative to the
tightening element, actuation of the tightening element sliding the
nut from the first position to the second position.
8. The system of claim 7, wherein the tightening element is a screw
having outer threads coupled to inner threads of the nut.
9. The system of claim 7, wherein the second end of the tube
includes at least two longitudinal slits therein.
10. The system of claim 9, wherein the second end of the tube is in
a flexed condition when the first coupling element is in the
tightened condition, and in an unflexed condition when the first
coupling element is in the loosened condition.
11. The system of claim 6, wherein the bore of the shaft includes a
first bore portion in the first end of the shaft having a first
diameter and a second bore portion in the second end of the shaft
having a second diameter larger than the first diameter, the first
bore portion being continuous with the second bore portion.
12. The system of claim 11, wherein the tightening element extends
through the first and second bore portions of the shaft.
13. The system of claim 12, wherein the second end of the nut has
an outer diameter that is smaller than the second diameter of the
second bore portion and larger than the first diameter of the first
bore portion.
14. The system of claim 11, wherein the first bore portion, the
second bore portion, and the shaft each extend along a second
axis.
15. The system of claim 14, wherein in the loosened condition of
the first coupling element, the first axis is moveable with respect
to the second axis, and in the tightened condition of the first
coupling element, the first axis is fixed with respect to the
second axis.
16. The system of claim 2, wherein the second coupling element
comprises: a second tube having a first end and a second end
opposite the first end, the first end of the second tube being
fixed to the second end of the tubular element, the second end of
the second tube having an outer part-spherical surface and an inner
part-spherical recess; a second shaft extending from a first end to
a second end, the second end of the second shaft having a
part-spherical recess that at least partially overlies and is in
contact with the outer part-spherical surface of the second tube;
and a second nut extending from a first end to a second end, the
first end of the second nut being positioned within the second end
of the second tube and having an outer part-spherical surface in
contact with the part-spherical recess of the second tube, the
second end of the second nut being positioned within the second end
of the second shaft, the second shaft and the second nut each being
articulable with respect to the second tube.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. patent
application Ser. No. 14/549,949, filed on Nov. 21, 2014, which is a
continuation of U.S. patent application Ser. No. 13/589,624 filed
on Aug. 20, 2012 and issued as U.S. Pat. No. 8,906,021, the
disclosures of which are both hereby incorporated herein by
reference.
BACKGROUND OF THE INVENTION
[0002] The invention relates to a telescopic strut for an external
fixator, especially for use with an external ring fixator.
[0003] A plurality of compression-distraction apparatus have been
designed and improved by Ilizarov and his group using two external
rings to be placed around the limb to be fixed. There are usually
at least two such rings, one proximal and one distal ring, which
are connected with a plurality of struts or rods. Preferably, these
struts are linked to the rings in a way that the attachment points
can be pivoted and the length of the strut can be varied to enable
adjustment of the external fixation rings.
[0004] Ilizarov has also provided some improvements for said
systems. European Patent No. 0 377 744 shows a telescopic strut for
such an external fixator. U.S. Pat. No. 4,615,338 shows a further
device to control the length of such telescopic struts.
[0005] A different external ring fixator having telescopic struts
is shown in U.S. Pat. Nos. 5,702,389 and 6,030,386. Other
telescopic struts are shown in U.S. Pat. Nos. 8,057,474 and
8,062,293 assigned to the assignee of the present invention, the
disclosures of which are incorporated herein by reference.
BRIEF SUMMARY OF THE INVENTION
[0006] However, these devices, which can be used to shorten or
lengthen the telescopic struts, are difficult to adjust and it is
one aspect of the invention to improve the ease of adjusting the
length of the rod. Furthermore, a simple method of length
adjustment and dynamization for each strut is desired.
[0007] Based on the prior art, it is therefore an aspect of the
invention to provide a telescopic strut, which can be readily and
quickly changed in its length.
[0008] It is another aspect of the invention, to allow, as an
alternative, fine adjustments of the struts.
[0009] In view of the above mentioned aspect it is furthermore
another aspect of the invention to allow a quick switch between the
two functions, i.e., to allow a quick first definition of the
length of the telescopic element, and additionally, to switch for a
fine adjustment of said length.
[0010] It is yet another aspect to provide a variable dynamization
function to the strut which allows micro-motion at a
fracture/fusion site to promote healing.
[0011] A telescopic strut of the present invention for use with an
external fixator includes an axially extending rod having a series
of circumferential grooves on an outer surface of the rod; an
axially extending tube is provided for receiving the rod. The tube
has a first end including a plurality of holes formed in a wall of
the tube and a second end having a pin extending therethrough. A
plurality of balls are provided for extending through the holes in
the first end of the tube. A sleeve having an eccentric bore
therethrough is mounted around the tube first end for contacting
the balls. The eccentric bore has a major diameter allowing the
balls to be located outside the grooves of the rod and a minor
diameter causing the balls to be held within the grooves on the
rod. A coupling element comprising a hollow tubular member is
slidably mounted on an outer surface of the tube second end, the
coupling element tubular member has two axially extending
diametrically opposed slots for receiving the pin and an adjustment
element is mounted on an outer surface of the coupling element
tubular member for movement thereon in the axial direction. The
adjustment member serves as a stop to limit the travel of the pin
in the two slots. The adjustment member may be threaded and mounted
on a mating thread on the coupling element tubular member.
[0012] A detent may be provided for holding the sleeve in a first
position where the major diameter engages the balls or a second
position where the minor diameter engages the balls. The means
includes a spring biasing the sleeve towards the second
position.
[0013] The grooves in the rod may be formed by a helical thread
extending along the axial extent thereof so that rotation of the
rod with the balls engaged lengthens the strut.
[0014] Alternately the grooves may be formed by a plurality of
radial ridges.
[0015] Preferably the balls are at least partially retained within
the holes of the leading end when contacted by the minor diameter
of the sleeve.
[0016] A telescopic strut of the present invention for use with an
external fixator may also comprise an axially extending rod, an
axially extending tube moveably receiving the rod for varying the
length of the rod and tube combination along a longitudinal axis.
The tube has first and second ends, the second end having a pin
extending therethrough. An adjustment system is mounted on the tube
first end for adjusting the position of the rod in the tube. A
connector element is provided having a tubular sleeve with a
threaded outer surface mounted on an outer surface of the second
end of the tube. The connector element can include a ball joint
which can be locked when the connector is fixed in a hole in a ring
of an external fixation frame. The sleeve has two axially extending
diametrically opposed slots for receiving the pin and an adjustment
element threadably mounted on a threaded portion of the tubular
sleeve outer surface for axial movement along the axis. The
adjustment element has an annular surface contacting the pin to
limit the movement of the pin in the slots.
[0017] The rod is threaded and is mounted in the end of the tube
such that relative rotation therebetween causes a length variation
of the rod and tube combination along the longitudinal axis.
[0018] The adjustment system may include radially moveable elements
which selectively engage and disengage the threaded rod to allow
axial sliding when disengaged and fine adjustment by the relative
rotation of the tube and rod when engaged to vary the strut
length.
[0019] The tubular sleeve is coupled to an opening in an external
fixation ring by releasable connectors which allow rotation of the
sleeve and tube about the axis of the rod and tube to vary the
axial length of rod and tube when the radially moveable elements
are engaged.
[0020] The two slots in the connector sleeve each have a first end
and the adjustment element can move the pin into contact with the
slot first end to prevent the pin from moving in the two slots. The
sleeve outer surface includes markings showing the distance between
the slot first end and the pin wherein the markings are in 1 mm
increments.
[0021] The pin may include a pair of protruding ends for receiving
a tool for rotating the tubular sleeve and tube relative to the rod
for varying the length of the strut.
[0022] An additional telescoping strut of the present invention for
an external fixator comprises a threaded rod, a tube threadably
receiving the rod with the tube and rod extending along a
longitudinal axis. The tube has a first end with a pin extending
therethrough. An adjustment element is provided for fixing the
relative axial position of the tube and rod; and a dynamization
system mounted on the first end of the tube, the system comprising
a sleeve slidably mounted on the tube with the pin extending
through a pair of diametrically opposed slots on the sleeve such
that the pin can move in the axial direction with respect to the
slots; an adjustable stop element mounted on the sleeve movable to
limit the level of the pin in the slots. The adjustable stop
element is a nut mounted on a threaded outer surface of the
sleeve.
BRIEF DESCRIPTION OF THE DRAWINGS
[0023] The invention is now described with reference to the
enclosed drawings, showing preferred embodiments of the telescopic
strut:
[0024] FIG. 1 is an elevation view of a telescopic strut according
to the invention;
[0025] FIG. 2 is an exploded view of the length adjusting portion
of the telescopic strut according to FIG. 1;
[0026] FIG. 3 is a side view in cross-section of the telescopic
strut according to FIG. 1;
[0027] FIG. 4 is a cross section of the rod along line-4 in FIG.
3;
[0028] FIG. 5 is an elevation view of the coupling element
connected to the threaded rod of the strut for coupling the strut
to a ring of an external fixation system;
[0029] FIG. 6 is a cross-sectional view of the connector of FIG.
5;
[0030] FIG. 7 is an elevation view of a coupling element connected
to the tubular portion of the strut of the present invention for
connecting the strut to a second ring element of an external
fixation system;
[0031] FIG. 8 is a cross-sectional view of the connection element
of FIG. 7;
[0032] FIG. 9 shows an adjustment wrench for adjusting the
dynamization of the strut of the present invention;
[0033] FIG. 10 shows the same adjustment wrench adjusting the
length of the strut of the present invention; and
[0034] FIG. 11 is an isometric view of the wrench shown in FIGS. 9
and 10.
DETAILED DESCRIPTION
[0035] Referring to FIG. 1 there is shown a perspective view of a
telescopic strut according to the invention generally denoted as
10. The telescopic strut comprises two free ends 11 and 12, which
include coupling elements 100 and 200 being attachment points for
connecting the strut to two external rings to be placed around the
limb to be treated. The attachment coupling elements 100 and 200
according to this embodiment preferably comprise ball joints as
will be discussed below, but this entirely depends on the kind of
fixation element for which the rod is used.
[0036] FIG. 1 shows the main components of the telescopic strut.
There is an outer tube tubular element 21 having a bore in which
the threaded rod 22 is partially located. Tube 21 has a bore
therein for receiving rod 22 the bore can be only partially through
tubular element 21 leaving a solid end adjacent coupling 200. The
outer tube 21 has mating thread elements 30 for engaging threaded
rod 222 which is located within a sleeve 23 at an end of tubular
element 21 and are better seen in FIG. 2 as well as FIG. 3 and will
be described below. In the preferred embodiment sleeve 23 comprises
a bayonet groove 24 for a quick change between the desired quick
length change mode and the fine adjustment mode. The sleeve 23 can
be switched between two rotational positions for this, i.e., to
lock and unlock movement the axial direction. Therefore the groove
24 has a U-form, the ends of the groove 24 defining the two
positions with the help of a bolt 26 provided within the groove 24.
The recessed ends 24a and 24b of the groove 24 are oriented in
axial direction of the telescopic strut. These ends face in the
same direction, towards the spring 27, as can be seen in FIG. 1 and
the exploded view of FIG. 2, to allow displacement of the bolt 26
against the force of spring 27.
[0037] A security mechanism, to avoid unintentional switching, is
realized by an additional nut 25, blocking the bolt 26 in one of
the free ends of groove 24.
[0038] FIG. 3 shows a view in cross-section of the telescopic strut
according to FIG. 1. Sleeve 23 can be pushed against action of
spring 27 provided on the outer tube 21 and which spring is biased
with help of nut 25. Then the sleeve 23 is turned around 90.degree.
and is arrested within the other free end 24a or 24b of the groove
24. It is preferred that this position is fixed through nut 25.
[0039] The turning angle of 90 degrees is defined in view of the
way the quick length adjustment mode is working. This can be seen
in FIG. 4 being a representation of a cross section of the rod
along line 4-4 in FIG. 3. It can be seen from FIG. 4 that the
sleeve 23 has a non-cylindrical inner bore. The bore can be, e.g.,
elliptical. The shorter diameter of the bore is sufficient to
accommodate the outer diameter of the foremost portion 25a of outer
tube 21 shown in FIG. 2, which is cylindrical. Foremost portion 25a
comprises on both sides a plurality of preferably, four holes 38 to
accommodate one ball 28 each. Of course, it is also possible to
provide only two balls on each side or five or more. Three or four
balls have been proven to be sufficient without lengthening the
sleeve 23 too much.
[0040] The inner diameter of outer tube 21 is greater than the
outer thread portion of the rod 22 which is cylindrical. Therefore,
the rod 22 can be pushed into the outer tube 21, when the bolt 26
is in a position which allows the sleeve 32 to be oriented as shown
in FIG. 4. Then the balls 28 can freely move against the inner wall
of sleeve 23 and the rod 22 can be axially pushed. For that the sum
of the outer diameter of the rod 22 and twice the diameter of the
balls 28 is less or nearly equal to the inner diameter of the
sleeve 23.
[0041] Separation of the threaded rod 22 from the outer tube 21 is
prevented through an abutment screw 29 which is screwed into a
corresponding thread within the threaded rod 22 and which can abut
on a corresponding shoulder within the tube 21 as shown in FIG.
3
[0042] By turning the sleeve 23 around the bolt 26, i.e., by
90.degree., the balls 28 will be moved because of the elliptic
inner shape within the sleeve 23. In this way the balls 28 are
pushed through holes 38 towards the grooves of the thread 22 for
interlocking, i.e., connecting the thread with the outer tube 21,
because the balls 28 stand within both parts and leave no room to
allow a direct axial movement of the threaded rod 22.
[0043] In this position the threaded rod 22 still can be moved
axially through rotational movement of tube 21 being directly
coupled via bolt 26 to sleeve 23 against the threaded rod 22 which
can rotate in view of the balls 28 pressed in its threads. This
allows for the fine adjustment.
[0044] Thus the elements allow for a quick change between free
axial adjustment of the telescopic strut, if the balls 28 do not
engage the threaded rod 22. If the balls do engage rod 22 then a
fine adjustment through rotation of the outer tube 21/rod 22 is
allowed. The balls 28 are engaging the one or subsequent grooves of
the threaded rod 22, e.g., depending on the pitch of thread of the
rod 22. The pitch angle of the thread can be chosen, e.g., between
30 and 60 degrees and especially between 40 and 50 degrees.
[0045] It is clear that this fine adjustment is only possible, if
at least one free end 11 or 12 of the telescopic strut can be
rotated while fixed within an external fixator ring.
[0046] Within another embodiment (not shown) a helically threaded
rod is replaced by a rod having a plurality of radial grooves. Each
of these grooves has dimensions to accommodate one of the balls 28.
In other words, the threaded rod having a groove providing a pitch
is replaced by a sequence of separated adjacent radial grooves. It
is thus possible to use such a rod with a flank lead to block the
device in a plurality of positions. However, with radial grooves it
is not possible to allow a fine tuning through rotation of tube
21.
[0047] Referring to FIGS. 5 and 6, there is shown a first coupling
element adapted to engage a bore in a ring of an external fixation
system. Typically the rings of an external fixation system are
circular or part circular and have a plurality of through holes
located between inner and outer diameters of the rings. FIGS. 5 and
6 show first coupling element 100, including a shaft 102 with a
threaded portion 104 and a pivoting tubular end portion 106 adapted
to thread on an end of rod 22 of strut 10. As can be seen in
cross-sectional view FIG. 6, the inner bore 108 of end 106 includes
threads 110 adapted to be screwed onto the end of rod 22. Pivot end
106 includes an end portion 112 having an outer part-spherical
surface 114 and an inner part spherical surface 116. Outer
part-spherical surface 114 may include roughened areas or ridges
118 so that it may be locked against a part spherical recess 120 on
shaft portion 102 when the assembly is tightened. Pivot portion 106
is coupled to shaft portion 102 via a threaded nut 122 having a
part spherical surface 124 adapted to engage inner part spherical
surface 116 of pivot end 106. Nut 122 includes a threaded inner
bore diameter 126. Nut 122 also includes a generally cylindrical
leading end 128, which slidably engages a bore 130 within shaft
102. Shaft 102 includes a further bore portion 132 for receiving a
screw 134, which bore has a smaller diameter than bore portion 130
so that leading end 128 of nut portion 122 may slidably engage the
larger diameter bore 130 and still receive a threaded shaft 133 of
a screw or tightening element 134 mounted in bore portion 132. Bore
portions 130, 132 and shaft 133 extend along an axis 140. Screw
element 134 may be threaded into the threaded bore 126 of nut 122
via an outer threaded portion 136 thereon. Tightening element 134
includes a drive head 138, which may be square or hexagonal so that
a tool may be applied to rotate element 134 thereby moving surface
124 of nut 122 into tight engagement with inner surface 116 of
pivot end 106. Portion 112 of pivot element 106 may have two or
more longitudinal slits therein so that it may flex outwardly into
engagement with part-spherical surface 120 upon movement of nut 122
toward surface 116 resulting from rotation of threaded tightening
element or screw 134.
[0048] In use threaded portion 104 of coupling 100 is inserted
through a hole in the external fixation system ring (not shown) and
a nut is threaded onto thread 104 of shaft 102 to attach coupling
element 100 to the ring. When this is done axis 140 of end 102 is
co-axial with a central axis of the bore in the ring. When the end
of rod 22 is threaded into pivot end 106, it can be selectively
locked in position or rotated about the ball joint in any direction
about axis 140 of coupling 100 on part-spherical surfaces 114 and
120 depending on whether screw element 134 and nut 122 are either
in a loosened position or a tightened down position. When tightened
roughened surface 118 engages inner surface 116 which ensures no
movement of rod 22 with respect to the axis 140 of the hole in the
ring and of portion 102.
[0049] Referring to FIGS. 7 and 8, a second coupling element 200 is
shown. Coupling element 200 includes many of the features of
coupling 100, including a shaft 102a with a threaded portion 104a.
Likewise, a screw 134a with drive head 138a is coupled to a nut
122a having the part spherical outer surface 124a. Also likewise,
the coupling element 200 includes a pivoting tubular end portion
106a extending along an axis 203, which has a leading end 112a with
part spherical surface 114a for contacting an inner surface 120a of
element 102a. Tubular end 106a is slidably mounted on end 21a of
shaft 21. End portion 106a includes a hollow end portion 108a
fixedly receiving shaft 21 or an extension thereof such that pivot
end portion 106a and shaft 21 cannot rotate relative to one
another. Portion 106a now includes a threaded outer portion 202
upon which a rotatable internally threaded nut 204 is mounted.
Rotation of nut 204 on threaded portion 202 moves the nut 204 along
axis 203 either away from or toward end 108a and shaft 21. An
O-ring 206 is mounted in a groove 208 within nut 204 to hold nut
204 in a particular axial location upon rotation of nut 204 on
threaded portion 202. Tubular element 106a further includes a pair
of slots 210 diametrically opposite one another in a wall of
tubular element 106a. Shaft portion 21 includes a pin 212 extending
therethrough which pin 212 is fixed to the end of shaft 21 such as
by a press fit. Upon assembly, pin 212 extends through both slots
210 in 106a and extends outwardly beyond the outer surface on each
side of tubular member 106a, a distance preferably approximately
equal to the diameter of nut 204. Since tubular end portion 106a is
slidable on end 21a of shaft 21 the engagement of slot 210 and pin
212 hold the tubular end portion 106a on end 21a. As will be
discussed below, the engagement of end surface 214 of nut 204 with
pin 212 as it moves within slot 210, provides for dynamization
within the strut 10 by allowing the surgeon to set a dynamization
distance of, for example, 0 mm to 5 mm by rotation of nut 204. This
distance would be set by rotating nut 204 on thread 202. Typically,
1 mm spaced markings placed on the outer surface of tubular element
106a would indicate the distance.
[0050] In use, the telescopic strut would be used as described
above and in U.S. Pat. No. 8,057,474, the teachings of which are
hereby incorporated by reference, with the exception of the
dynamization system discussed above. The surgeon connects strut 10
with coupling elements 100 and 200 to respective first and second
external fixation frame members such as rings or plates with the
threadable elements 134, 134a loosened so that the part-spherical
ball joints are free to rotate. The surgeon adjusts the length of
the strut initially using the quick length adjustment mode and then
the fine adjustment mode until the fractured bones are in the
desired alignment. At this point, the screws 134, 134a are both
tightened thereby locking the strut in the desired angular and
length position with respect to both the first and second ring
members. A further finer adjustment is needed then one of the ball
joints must be loosened by rotating a screw 134a which allows for
rotating the tubular shaft 21 or rod 22. Preferably the ball joint
200 is loosened by rotating screw 134a. The surgeon then sets the
dynamization system by rotating nut 204. If no dynamization is
required surface 214 of nut 204 is placed against pin 212.
Obviously multiple struts 10 may be used in the frame system.
[0051] Referring to FIGS. 9-11, there is shown the use of a wrench
300 used to both make the fine adjustments of the length of strut
10, as well as set the dynamization distance between pin 212 and
surface 214 of nut 204. Wrench 300 includes a first end 302 with a
curved opening 304 defining first lobe 306, second lobe 308, and
third lobe 310 adapted to respectively engage one of a plurality of
grooves 215 on the outside of nut 204. As seen in FIG. 9, lobes
306, 308, and 310 engage three different grooves 215. Thus rotation
of wrench 300 can move nut 204 on thread 202 either toward or away
from pin 212. Tubular member 106a includes a series of markings 217
either cut or etched into the outer surface of tubular element 106a
at 1 mm increments. Thus, the surgeon can set the dynamization by
turning nut 204 thereby moving surface 214 with respect to pin 212.
Preferably markings 217 are spaced 1 mm so that the exact amount of
dynamization can be determined by counting the number of markings
217 between surface 214 and the under surface of pin 212.
[0052] Wrench 300 has a second end 320 with a pair of hook shaped
elements 322 and 324, which each include a U-shaped recessed
opening 326, which receives the ends of pin 212 which extend beyond
the outer surface of tubular element 106s. As shown in FIG. 10,
when end 320 is hooked over both ends of pin 212, wrench 320 can be
used to rotate shaft 21. End 21a is slidably mounted within tubular
element 106a however rotation of end 21a via pin 212 rotates
tubular portion 106a via the engagement of pin 212 and slot 210
thus providing fine tuning of the length of strut 10. As discussed
above, in order to accomplish this, the ball joint within coupling
element 200 must be released by appropriately turning screw 134a.
Once the correct length is achieved, the ball joint is again locked
via rotation of screw 134a. Locking end 112a of sleeve 106a against
surface 120a via threaded element 134a prevents rotation of shaft
21 about any axis
[0053] Although the invention herein has been described with
reference to particular embodiments, it is to be understood that
these embodiments are merely illustrative of the principles and
applications of the present invention. It is therefore to be
understood that numerous modifications may be made to the
illustrative embodiments and that other arrangements may be devised
without departing from the spirit and scope of the present
invention as defined by the appended claims.
* * * * *