U.S. patent application number 12/765903 was filed with the patent office on 2010-08-12 for precision assembleable surgical tool handle.
This patent application is currently assigned to Greatbatch Medical S.A. Invention is credited to Thomas Lamadon, Andre Lechot.
Application Number | 20100204702 12/765903 |
Document ID | / |
Family ID | 39152838 |
Filed Date | 2010-08-12 |
United States Patent
Application |
20100204702 |
Kind Code |
A1 |
Lechot; Andre ; et
al. |
August 12, 2010 |
PRECISION ASSEMBLEABLE SURGICAL TOOL HANDLE
Abstract
A precision adjustable surgical tool holder/driver is provided
which is easily disassembled for cleaning and precisely
reassembled. The holder/driver has a positionable handle allowing
adjustment of the position of the handle about the spindle of the
holder to enable the "handedness" of the holder to be changed in
order to accommodate a user while operating from the left or right
side of the patient, standing behind or in-front of the patient, or
for use in different surgical methods. The holder/driver includes a
"limited-play" capture mechanism, which connects the drive end of
the housing to its locking sleeve via a limited-play locking
device. The limited-play locking device utilizes a disengageable,
precision fitted bayonet pin and seat combination in part to
accomplish the precision reassembly feature of the present
invention.
Inventors: |
Lechot; Andre; (Orvin,
CH) ; Lamadon; Thomas; (Les Verrineres-des-Joux,
FR) |
Correspondence
Address: |
Greatbatch Ltd.
10,000 Wehrle Drive
Clarence
NY
14031
US
|
Assignee: |
Greatbatch Medical S.A
Clarence
NY
|
Family ID: |
39152838 |
Appl. No.: |
12/765903 |
Filed: |
April 23, 2010 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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11536792 |
Sep 29, 2006 |
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12765903 |
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PCT/IB03/01725 |
Apr 28, 2003 |
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11536792 |
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60765692 |
Feb 6, 2006 |
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Current U.S.
Class: |
606/80 |
Current CPC
Class: |
A61B 17/1633 20130101;
A61B 17/1666 20130101; A61B 2017/320032 20130101; A61B 17/1631
20130101 |
Class at
Publication: |
606/80 |
International
Class: |
A61B 17/16 20060101
A61B017/16 |
Claims
1. A tool handle, which comprises: a) a housing extending along a
first longitudinal axis from a proximal housing portion to a
housing bend portion deviating from the first longitudinal axis
thereof to a distal housing portion, wherein the housing comprises
first and second housing parts; and b) a locking sleeve comprising
a sleeve sidewall extending from a proximal sleeve portion having a
proximal sleeve end to a distal mouth portion, wherein the locking
sleeve encloses the housing from the proximal housing portion to
the sleeve mouth portion cradling the housing bend portion to
prevent rotation of the first and second housing parts relative to
the locking sleeve.
2. The tool handle of claim 1 wherein the housing bend portion
deviates from the longitudinal axis at an acute angle to the distal
housing portion.
3. The tool handle of claim 1 wherein a proximal locking ring
supported on the locking sleeve has at least one proximal locking
ring pin aligned perpendicular to the first longitudinal axis and
sized to travel along a locking sleeve bayonet slot provided in the
locking sleeve sidewall, wherein with the housing received in the
locking sleeve having the sleeve mouth portion cradling the housing
bend portion, the proximal locking ring is manipulatable to move
the proximal locking ring pin along the locking sleeve bayonet slot
to thereby retain the first and second housing parts contacting
each other, and wherein the proximal locking ring is manipulatable
to cause the proximal locking ring pin to travel in a reverse
direction along the locking sleeve bayonet slot to thereby permit
axial movement of the locking sleeve with respect to the housing to
separate them from each other for subsequent separation of the
first and second housing parts from their contact relationship.
4. The tool handle of claim 3 wherein the locking sleeve bayonet
slot provided through the sleeve sidewall is spaced distally from
the proximal sleeve end.
5. The tool handle of claim 1 wherein the locking sleeve has two
locking sleeve bayonet slots through the sleeve sidewall, the
locking sleeve bayonet slots being aligned diametrically opposite
each other and wherein the first and second housing parts each
comprise proximal housing bayonet slots extending distally from
respective proximal ends thereof.
6. The tool handle of claim 5 wherein the proximal locking ring has
two proximal locking ring pins oriented perpendicular to the first
longitudinal axis and aligned diametrically opposite each other and
wherein with the locking sleeve enclosing the housing from the
proximal housing portion to the sleeve mouth portion cradling the
housing bend portion, the proximal locking ring pins are sized to
travel along the respective locking sleeve bayonet slots aligned
with the proximal housing bayonet slots provided in the respective
first and second housing parts so that the proximal locking ring is
manipulatable to move the proximal locking ring pins along both the
locking sleeve bayonet slots and the proximal housing bayonet slots
to retain the first and second housing parts contacting each other.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] The present application is a divisional of U.S. patent
application Ser. No. 11/536,792, filed Sep. 29, 2006, which claims
priority from U.S. Provisional Patent Application Ser. No.
60/765,692, filed 6 Feb. 2006, which is a continuation-in-part of
PCT application No. PCT/1B03/01725, filed 28 Apr. 2003.
FIELD OF THE INVENTION
[0002] The present invention is in the field of surgical tools and
accessories for performing orthopedic surgery. More particularly,
the present invention relates to handles tool holders useful in
orthopedic surgical procedures, the handles/holders being precision
surgical tool handles with a limited-play interconnect
mechanism.
BACKGROUND
[0003] Complicated mechanical devices have crevices and recesses
that are difficult, if not almost impossible, to clean with ease.
Devices that are not properly cleaned and sterilized contribute to
the risk of disease transfer from patient to patient following the
emergence of certain "prions" that are not killed by normal
hospital sterilization and need to be physically removed by
washing/rinsing. Although surgical tool handles are known in the
field (see PCT/GB2002/02934 to Chana, incorporated herein by
reference), those using "J-slot" (bayonet type) interconnect
mechanisms can be subject to play at the interconnections. It would
be beneficial in the field to have an interconnect mechanism that
has the advantages of the existing "J-slot" interconnect
mechanisms, but is less subject to play in the connection.
SUMMARY
[0004] The present invention comprises an adjustable reamer spindle
designed to aid a surgeon to better control the instrument.
Adjustment of the position of the handle axis of the spindle
enables the axis through the palm/grip of each hand to change in
order to provide maximum control in different orientations. The
adjustment is desirable in order to accommodate operating on the
left or right side of the patient standing behind or in front of
the patient, or the use of a different surgical approach. Further,
adjustment is important to accommodate the differing needs of
surgeons who are naturally left or right handed. In such an
instrument that is intended for either right or left handed use, or
both CW and CCW rotation in use, it is important to provide an
interconnect mechanism that minimizes axial play when used with
either hand, or both CW and CCW rotation.
[0005] The present invention comprises a precision surgical tool
holder/handle which is assembleable over and over again to precise
radial, axial and length relationships of its components. The
precision tool driver has a precision spindle housing in which a
drive train is retained. The drive chain has a drive attachment end
connectable to a means for rotating the drive chain, and a tool
holder end connectable to a surgical tool head. The tool holder end
has an axis of rotation relative to the spindle housing, and an
axial displacement aspect relative to a tool end of the spindle
housing. The axis of rotation is precisely defined by the
relationship between the spindle housing and the drive chain at the
tool holder end of the drive chain. The axial displacement aspect
is definable as the distance between the tool end of the spindle
housing and the tool holder end.
[0006] The handle has a fitted locking sleeve which closely
receives the spindle housing and drive chain combination. The
locking sleeve has a sleeve axis which is disposed precisely
parallel to the axis of rotation when the spindle housing and drive
chain combination is received by the locking sleeve. The locking
sleeve has a mating means interfacing with the spindle housing
which precisely fixes a radial aspect relationship between the
spindle housing and the locking sleeve when the spindle housing is
received by the locking sleeve.
[0007] A precision locking device is retained on the locking
sleeve. The locking device has an annular collar slideable on the
drive end of the locking sleeve, between a sleeve shoulder and a
collar ring. The annular collar has a handle attached to it, a
collar axis, and an attachment point at which the handle is fixed
to the annular collar. Typically, the attachment point is disposed
on a radius of the collar axis. The collar ring is releaseably
engageable to bias the collar against the sleeve shoulder at a
precision radial interface to precisely fix the radial aspect
relationship between the attachment point and the collar
radius.
[0008] A releaseable capture mechanism is provided to integrate the
assemblies of the present invention into a working whole. The
capture mechanism is embodied in part in each of: the spindle
housing/drive chain, locking sleeve and locking device assemblies.
The capture mechanism comprises a precision bayonet-type connection
cooperatively involving the spindle housing, the locking sleeve and
the locking device. The precision bayonet connection includes the
collar ring which has an internal surface from which at least two
bayonet pins extend radially inward. The bayonet pins pass through
retainer slots disposed in the locking sleeve, as described
elsewhere. When the locking sleeve assembly is slid over the
spindle housing/drive chain assembly, the bayonet pins are received
into bayonet slots on the spindle housing corresponding to the
retainer slots on the locking sleeve. The bayonet slots are
disposed to releaseably engage the bayonet pins. At least one of
the bayonet slots has a precision pin seat to engage a precision
bayonet pin head on its corresponding bayonet pin.
[0009] When the capture mechanism is engaged, the spindle
housing/drive chain assembly, the fitted locking sleeve assembly
and the locking device all cooperate through the capture mechanism
to provide the present precision surgical tool driver repeatably
assembleable to precise radial, axial and length aspect
relationships of its components and the device overall.
[0010] The releaseable capture mechanism has a precision
bayonet-type connection between the spindle housing, the locking
sleeve and the locking device. The collar ring has an internal
surface from which at least two bayonet pins extend radially
inward, and pass through retainer slots disposed in the end of the
locking sleeve. The retainer slots correspond to bayonet slots in
the spindle housing. The bayonet slots are disposed to releaseably
engage the bayonet pins. At least one of the bayonet slots has a
precision pin seat to engaging a precision bayonet pin head on its
corresponding precision bayonet pin.
[0011] The spindle housing and drive chain combination, the fitted
locking sleeve, the locking device and the capture mechanism all
cooperating to provide the present repeatably assembleable
precision surgical tool driver.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012] FIG. 1 is a side view of the reamer spindle of the present
invention.
[0013] FIG. 2 is a top view of the reamer spindle of the present
invention.
[0014] FIG. 3 is a section view taken along line 3-3 shown in FIG.
2.
[0015] FIG. 4 is a plan view showing a traditional reamer spindle
of the prior art being used in a minimally invasive approach for
reaming the acetabular socket.
[0016] FIG. 5 is a plan view showing the reamer spindle of the
present invention being used in a minimally invasive approach for
reaming the acetabular socket.
[0017] FIG. 6 is an exploded assembly of an alternative embodiment
of the present invention.
[0018] FIG. 7 is an alternative shape housing of the alternative
embodiment shown in FIG. 6.
[0019] FIG. 8 is a perspective view of an alternate embodiment of
the invention having a repositionable handle.
[0020] FIG. 9A is an exploded view of the alternate embodiment of
FIG. 8.
[0021] FIG. 9B is a close up of a portion of the exploded view of
the alternate embodiment of FIG. 8.
[0022] FIG. 9C is a cross-sectional view of the adjustable handle
portion of the alternate embodiment of FIG. 8.
[0023] FIG. 9D is a perspective drawing of the principle assemblies
of the present invention illustrating their axial, radial and
length aspects wherein the precision features of the device
reside.
[0024] FIG. 10 is a perspective view of key components of the
alternate embodiment of FIG. 8.
[0025] FIGS. 11A and 11B are end-on views of the drive ends of the
spindle housing and the locking sleeve assembly, illustrating a
limited play interconnection between the housing and the sleeve,
with the fitted bayonet pin disengaged from its seat (A), and
engaged in its seat (B).
[0026] FIG. 11C is an alternative embodiment of the fitted bayonet
pin and seat features of the limited-play interconnection of FIGS.
11A and 11B.
[0027] FIG. 12 is a perspective end view of the spindle housing
showing the bayonet pin J-slots, one of which includes a close
tolerance, fitted bayonet pin seat.
[0028] FIGS. 13A and 13B are instructional illustrations of a
manner in which the locking device can be operated.
[0029] FIG. 14 is a plan view of a surgical reamer kit of the
invention.
DETAILED DESCRIPTION OF THE INVENTION
[0030] Referring now to the drawings, the details of embodiments of
the present invention are graphically and schematically
illustrated. Like elements in the drawings are represented by like
numbers, and any similar elements are represented by like numbers
with a different lower case letter suffix.
[0031] In one embodiment, the present invention comprises a reamer
spindle 115 as shown in FIGS. 1-3, and 5. The reamer spindle 115
has a housing 113 containing a drive shaft 107. The drive shaft 107
has a proximal end drive fitting 104 adapted to be attachable to a
controllable motive source (not shown). The motive source is
provided to rotate the drive shaft 107 inside the reamer spindle
115. The drive shaft 107 has a distal end tool holder fitting 120
for holding a tool head 10, such as a reamer in the embodiment
illustrated (see FIG. 5). The drive fitting 104 and the tool
holding fitting 120 are disposed to mate with a complimentary
fitting on a motive source and a tool head 10, respectively.
[0032] In the embodiments illustrated, the tool holding fitting 120
is illustrated as comprising a complementary part of a bayonet-type
connection mechanism. However, as further illustrated below, a
complementary part of a bayonet-type mechanism can be used at other
connections on a tool spindle 115. The tool holding fitting 120 had
a slide 106 carrying a pin 111. The pin 111 works cooperatively
with the catch 110 located in the head 108 to form the bayonet for
capturing the complementary fitting on a tool head 10, while
allowing easy release. The tool heads 10 (reamers in this
embodiment) selected for use with the reamer spindle 115 can be
shaped and sized for cutting different osseous sites within the
body. It is widely known that reamers can be designed to cut the
patella in a knee or the glenoid in a shoulder or the socket 45 in
an acetabulum 40 as shown in FIGS. 4 and 5.
[0033] Referring to FIGS. 4 and 5, the reamer spindle 115 of the
present invention and the spindle 15 of the prior art invention are
shown passing through a miniature incision 35 in the patient's skin
30. In prior art FIG. 4, the reamer spindle 15 is shown approaching
the acetabulum 40 in a preferred orientation for reaming the socket
45. A difficulty with the prior art spindle 15 is that, as shown,
the shaft 3 can impinge on the miniature incision 35 at edge 37 of
the incision. The current surgical protocols are being pushed to
the limits and the incision sizes are being reduced with the intent
of increasing the patient's recovery speed. In some cases, surgeons
are using a two-incision approach, one to reach the acetabulum and
the other to reach the femur. Depending on the situation, either
the one incision or the two incision technique can result in less
trauma to the patient, thus requiring the instruments to be
flexible and more optimally designed to make up for the lack of
operating space.
[0034] The reamer 115 of FIG. 3 shows a present reamer spindle 115,
which has a bent housing 113 containing the drive shaft 107. The
drive shaft 107 can be selected from a variety of current torque
transmitting mechanisms or devices including a Nickel Titanium
shaft, a flexible round or flat wire wound cable, a series of gear
driven shafts, or a series of shafts interconnected by universal
joints. The drive shaft 107 can also be selected from any torque
transmission mechanism or device deemed appropriate for the
application, as selectable by one of ordinary skill in the art for
practice in the present invention. As illustrated, the drive shaft
107 can be held to the housing 113 with an optional series of
bearing surfaces 118 and 119 which keep the drive shaft 107 from
bearing against/riding on the inside of the housing 113, and can
act as a shield to protect the inner housing from blood. Other
means for holding the shaft to the housing would be acceptable. The
most important feature of the drive shaft 107 is that it conforms
to the selected housing 113 and sufficiently supplies torque to the
tool head 10. In these examples, the housing 113 is hollow and
maintains the drive end fitting 104 substantially collinear with
the tool holder fitting 120 (see FIGS. 3 and 6), but as illustrated
below, other configurations are intended as well.
[0035] Referring now to FIG. 6, an alternative embodiment is shown.
Similar to FIGS. 1-3 and 5, the reamer spindle 215 has a housing
113 in two parts 213 and 214 containing a drive shaft 207. The
drive shaft 207 has a proximal end drive fitting 204 adapted to be
attachable to a controllable motive source (not shown). The motive
source is provided to rotate the drive shaft 207 inside the reamer
spindle 215. The drive shaft 707 has a distal end tool holder
fitting 220 for holding a tool head 10. The drive fitting 204 and
the tool holding fitting 220 are disposed to mate with a
complementary fitting on a motive source and a tool head 10,
respectively. The drive shaft 207 can be selected from a variety of
current torque transmitting mechanisms or devices including a
Nickel Titanium shaft, a flexible round or flat wire wound cable
shaft, a series of gear driven shafts, or a series of linkages 208
interconnected by universal joints 209. The drive shaft 207 can
also be selected from any torque transmission mechanism or device
deemed appropriate for the application. In this embodiment, the
shaft 207 is constructed from a series of linkages 208 containing
universal joints 209 and bearing members 218 which rest against
journey supports 218a in the housing parts 213 and 214.
[0036] The drive shaft 207 can be flexible substantially throughout
its length, but, since it is not necessary to feed the drive shaft
207 into the housing 113, it is required to be flexible only along
portions of its length received in curved portions of the housing
113. Along straight portions of its length, the drive shaft 207 can
be rigid. Flexibility in drive shaft 207 is required only to allow
its rotation within curved portions of the housing 113. As noted
above, the drive shaft 207 can be conventional, wound-wire cable
flexible along its length, and having one or more alternating
layers wound in opposite directions. A protective, friction
reducing sheath (not shown) can be provided on such a drive shaft.
Other types of flexible drive shafts also can be used. Spaced
bearing journals (not shown) and/or lubricant can be provided
within outer shaft 50. That is to allow proper positioning of the
drive shaft 56 in outer shaft 50, and to reduce resistance to
rotation of drive shaft 56 within outer shaft 50.
[0037] The tool holder fitting 220 preferably comprise a
complementary part of a bayonet-type mechanism with a slide 206
carrying a pin component 211. The pin 211 works cooperatively with
the catch 210 located in the head 208 to form the bayonet for
capturing different size reamers while allowing their easy release
for size interchangeability and cleaning. The drive shaft 207 is
set in housing parts 213 and 214, which are separable for
cleaning.
[0038] There are many ways of connecting the housing part 213 and
214 together. For example, the drive shaft 207 can include a
capture mechanism 247 which is adapted to receive the front ends of
the housing parts 213 and 214 aligning each with one another and
encapsulating the drive shaft 107 to protect the patient's skin
from contacting the torque transmitting shaft 207 during operation.
Once the housing parts 213 and 214 are aligned, a locking mechanism
250 comprised of a ring 255 and a catch 260, which is located in
the housing member 213, interact with one another to retain the
housing parts 213 and 214 in a closed fashion. As with the
embodiment described in FIGS. 1-3, and 5, it is preferable to have
the drive end 204 substantially collinear with the holding
mechanism 220 along axis 216. The housing parts 213 and 214 are
shown preferably in FIG. 6 in a bent configuration. However, the
reamer spindle 215 can embody a housing in two parts, wherein the
housing parts 313 and 314 are straight and have no bend, as shown
in FIG. 7.
[0039] Referring now to FIG. 8 et seq., alternatively, the drive
end 404 is situated along an axis parallel to, but offset from, the
axis 416 of the tool holder fitting 420. A bend 480 in the housing
is optimally placed at a location to pass through the miniature
incision (see FIG. 5) without impinging on the skin 30 at location
37 while still maintaining the same surgical protocol. The drive
end fitting 404 and the tool holder fitting 420 have parallel axes,
so that an inline force applied to the drive fitting 404 results in
an axial force applied to the tool holder fitting 420. This allows
the surgeon to maintain the existing surgical technique and
accomplish the same result as when a prior reamer spindle 15 is
used with its straight drive shaft 3 (see FIG. 4). Thus, the
surgeon is able to apply a load directly along the path of
reaming.
[0040] In the embodiment of the reamer spindle 515 illustrated in
FIG. 8, the drive end 404 is situated along an axis parallel to,
but offset from, the axis 416 of the tool holder fitting 420.
Further, as shown in FIGS. 9A and 9B, a repositionable handle 500
doubles as a component of the capture device 450 in order to hold
the two housing parts 413 and 414 together. The capture mechanism
447 and capture device 450 slide over the front ends 448 of the
housing parts 413 and 414, aligning each with one another and thus
encapsulating the drive shaft 507 in order to protect the patient's
skin from contacting the torque transmitting shaft 507 after the
present device is assembled.
[0041] FIGS. 9A, 9B and 9C show how the housing parts 413 and 414
are aligned and locked in place in this embodiment of the spindle
515. The housing parts 413 and 414 are oriented with respect to
each other when the locking sleeve 502 (having an internal diameter
larger than the outside diameter of the assembled housing 413, 414)
slides over them and abuts against a bend 480 in the housing parts
413 and 414. Optionally, a facilitating surface may be disposed
between the housing parts 413 and 414 and the locking sleeve 502 to
facilitate assembly, such as a thin Teflon.RTM. coating or sleeves
(not shown). A mouth section 502' of the locking sleeve 502 cradles
the bend 480 of the assembled housing parts 413 & 414 and
prevents rotation of the locking sleeve relative to the housing
parts 413 and 414.
[0042] The sleeve drive end 548 of the locking sleeve 502 comprises
a capture mechanism 447 which connects the housing drive end 448 of
the housing parts 413 and 414 to the locking sleeve 502 via a
locking device 450. In one embodiment, the locking device 450 had
an annular collar 482 onto which a handle 500 was affixed. The
collar 482 includes a face 482' having pin recesses 482'' into
which sleeve pins 484 are receivable. The sleeve pins 484 are fixed
to a sleeve shoulder 502'' of the locking sleeve 502. The sleeve
pins 484 are disposed to be received into the pin recesses 482''.
The relationship between the sleeve pins 484 and pin recesses is
disposed to provide torsionally rigidly to hold the handle 500 in
any one of a number of positions (eight in one embodiment)
according to the preference of the surgeon. Alternatively, the
sleeve shoulder 502'' can have fingers or other projections (not
shown) that mate with the recesses 482''. A collar spring 486
biases the annular collar 482 into engagement with the sleeve pins
484 by a bias against the annular collar 482. In the embodiment
illustrated this is accomplished by the collar spring 486 applying
spring pressure against an internal shoulder 482''' in the annular
collar 482 and against a collar locking ring 455. The collar
locking ring 455 includes collar pins 490 which are affixed
thereto. The collar pins are received in and extend through sleeve
bayonet slots 492 in the drive end 548 of the locking sleeve 502.
At least one of the sleeve bayonet slots 492 has a close-end 493
(see FIG. 9B), thus retaining the locking device 450, including the
collar ring 455 and bias spring 486, on the drive end 548 of the
locking sleeve 502, thus keeping the component part of the capture
mechanism 447 together when the spindle 515 is disassembled.
[0043] In order for the locking device 450 to engage and connect to
the drive end 448 of the assembled housing parts 413 and 414, the
collar pins 490 (490a and 490b) extend through the sleeve bayonet
slots 492 sufficiently to additionally be received in the housing
bayonet slots 392 on the assembled housing parts 413 and 414 (see
FIG. 10). As shown in FIG. 10, the housing 413, 414 is held
together via the collar pins 490 which engage the bayonet slots 392
in each of the housing parts 413 and 414. The illustration in FIG.
10 has the annular sleeve 502, the collar spring 486 and the
locking collar 482 removed for clarity.
[0044] The collar pins 490 of the collar locking ring 455 and the
housing bayonet slots 392 interact with one another to retain the
housing parts 413 and 414 in an assembled condition, while
concurrently biasing the collar spring 486 so as to engage the
annular collar 482 (and thus the handle 500) with the sleeve pins
484. Optionally, the bias force of the collar spring 486 can be
selected to enable the surgeon to selectively disengage the collar
482 from the sleeve pins 484 and reposition the angle of the handle
500 relative to the locking sleeve 502 in an alternative position,
while avoiding disassembly of the spindle 515.
[0045] A most important object of the present invention is a
precision surgical tool driver which is repeatably assembleable to
precise radial, axial and length aspect relationships of its
component assemblies. The precision of the device reside in its
features which allow it to be disassembled multiple times, and upon
each reassembly, the physical dimensions defined by the aspect
relationships between its component assemblies are precisely
duplicated in the reassembled tool driver. See FIG. 9D as an
illustration of this. The present precision tool driver comprises
three main assemblies and a capture mechanism for precisely
interconnecting the main assemblies.
[0046] One assembly is a combination spindle housing/drive chain
615. The precision spindle housing 413,414 has an interior disposed
to receive and retain the drive train (or drive shaft) 207. The
drive chain has a drive attachment end 404 and a tool holder end
420. The drive attachment end 404 is configured to interface with a
motive means (not shown) for rotating the drive train 207. Such
motive means are known in the field. The tool holder end is
configured to connect to a surgical tool head, such tool holder
connector configuration being known in the field. The tool holder
end 420 of the drive train 207 has an axis of rotation aspect A
which is parallel relative to the tool end 620 of the spindle
housing 413, 414 from which it extends. The precision of the axis
of rotation aspect A is defined by the relationship between the
spindle housing 413,414 and the drive train 207 at the tool holder
end 420 of the drive train. More specifically, this relationship is
defined by the high precision of the bearing or bushing interface
between the spindle housing 413, 414 and the drive train 207 at the
tool end 620 of the housing. This relationship is such that the
spindle tool end 620 and the tool holder end 420 are always
substantially coaxial along the axis of rotation A when the drive
train 207 and the spindle housing 413, 414 are assembled. The tool
holder end 420 also has an axial displacement aspect d relative to
the tool end 620 of the spindle sleeve. The axial displacement
aspect d is the distance between an end point 620 on the spindle
housing 413, 414 and the tool holder end 420. The precision of the
axial displacement aspect d is defined by the relationship between
the spindle housing and the drive train at the tool holder end of
the drive train, which aspect is substantially always the same when
the drive train 207 and the housing 413, 414 are assembled.
[0047] Another assembly is the precision filled locking sleeve
which closely receives the spindle housing and drive train
combination 615. In the embodiment illustrated the drive end 404 of
the spindle housing/drive train assembly 615 slides into and is
closely received by the locking sleeve 502. The locking sleeve 502
has a sleeve axis B. The locking sleeve 502 is configured to
precisely receive and retain the spindle housing 413, 414 so that
the sleeve axis B is parallel to the axis of rotation aspect A of
the tool holder end 420 of the drive train 207. The locking sleeve
502 also has a mating means 502 which interfaces with the spindle
housing 413, 414 to precisely fix the radial aspect of the locking
sleeve 502 relative to the spindle housing 413, 414 upon receipt of
the spindle housing by the locking sleeve. This is to say, the
mating means 502' assures the spindle housing 413, 414 is
repeatably receivable in the locking sleeve in the same radial
orientation relative to each other. Additionally, in the embodiment
illustrated, the mating means 502' provides a precise travel limit
on how far the locking sleeve 502 can slide along the spindle
housing 413, 414.
[0048] The third assembly noted above is the precision locking
device 450, which is retained on the locking sleeve 502. The
locking device 450 comprises an annular collar 482 slidable on the
drive end 483 of the locking sleeve 502 between a sleeve shoulder
502'' and a collar ring 455. The collar ring 455 retains the collar
482 on the locking sleeve 502, and incorporates features of a
precision bayonet connection, further described elsewhere herein.
The collar 482 has a handle 500 attached to it, a collar axis B'
through its centerline and a point of attachment 625 of the handle
500 to the collar 482. The collar axis B' is substantially
collinear with the sleeve axis B, and in the embodiment
illustrated, is coaxial. The point of attachment 625 is disposed
along a selected radius C of the collar axis. The collar ring 455
is releaseably engageable to bias/hold the collar 482 against the
sleeve shoulder 502'' at a precision radial interface 484 and 482',
a first part 484 of which is on the sleeve shoulder 502'' and the
second part 482' being on the annular collar 482. The precision
radial interface precisely fixes the radial aspect relationship
between the point of attachment and the collar axis radius. In the
embodiment illustrated, the radial aspect relationship, between the
point of attachment of the collar axis to the locking sleeve axis
B.
[0049] FIGS. 11A-11C and 12 illustrate the "limited-play" features
of the capture mechanism 447, which connects the housing drive end
448 of the housing 413, 414 to the locking sleeve 502 via the
locking device 450. FIGS. 11A and 11B are end-on views of the drive
ends of the spindle housing and the locking sleeve assembly, with
the fitted bayonet pin disengaged from its seat 620 (in FIG. 11A),
and engaged in its seat 620 (in FIG. 11B). In the embodiment shown
in FIG. 11A, to engage the housing 413, 414, locking device 450 of
the capture mechanism 447 has two collar pins 490a and 490b held by
the collar ring 455. One is a fixed collar pin 490a and the other
is an extendable collar pin 490b. The extendable collar pin 490b
has a fitted bayonet pin head 600 at the end of the collar pin 490b
disposed in the interior of the collar ring 455, and a push-button
cap 604 at the other end of the collar pin 490b disposed anterior
to the collar ring 455 and a pin spring 614 disposed about the
shaft of the pin 612. The extendable collar pin 490b is slideably
received in a pin passage 610 in the collar ring 455. In the
embodiment shown, the pin passage 610 also serves a spring chamber
for receiving the pin spring 614. The pin spring 614 provides a
biasing force against the push-button cap 604 and the collar ring
455, which normally displaces the push-button cap 604 away from the
collar ring 455.
[0050] The collar pins 490a and 490b are received in and extend
through sleeve bayonet slots 492a and 492b in the drive end 548 of
the locking sleeve 502 (also see FIG. 10). The collar pins 490a and
490b extend through their respective sleeve bayonet slots 492a and
492b sufficiently to be received in their respective housing
bayonet slots 392a and 392b on the assembled housing parts 413, 414
(also see FIG. 10). The fitted bayonet slot 390b for receiving the
fitted bayonet pin 490b includes a head seat 620. The head seat 620
is disposed to closely receive and securely engage the bayonet pin
head 600 of the fitted bayonet pin 290b under the bias force of the
pin spring 614. The relationship of the configuration of the pin
head 600 and the head seal 620 is disposed to enable the close and
securely engagement of the pin head in the head seat. This may be
accomplished by any of a number of means known to the ordinary
skilled artisan for practice in the present invention, including
chamfering or beveling the surface of the head seat 620 to closely
receive a complementary surface of the pin head 600.
[0051] As shown in FIG. 11B, the housing parts 413 and 414 are held
together via the collar pins 490a and 490b which engage their
respective bayonet slots 392a and 392b in each of the housing parts
413 and 414. The collar pins 490a and 490b of the collar locking
ring 455 and the housing bayonet slots 392a and 392b interact with
one another to retain the housing parts 413 and 414 in an assembled
condition. Thus, the locking device 450 can engage and connect to
the drive end 448 of the assembled housing parts 413 and 414. When
the depicted embodiment of the present invention is in its
assembled condition, as in FIG. 11B, depressing the push-button cap
604 to overcome the bias force causes the pin head 600 to be
disengaged from the head seat 620 and to extend beyond the bayonet
slot 392b. While the push-button cap is so depressed, the bayonet
connection of the locking device 450 can be disengaged in a
conventional manner, and the spindle housing 413, 414 can be
separated from the capture mechanism 447.
[0052] FIG. 11C is an alternative embodiment of the fitted bayonet
pin and seat features of the limited-play interconnection of FIGS.
11A and 11B. In this embodiment, head seat 620a comprises both the
spindle housing 413, 414 and the locking sleeve 502. This
configuration of the pin head seat 620a allows the pin head 600 to
be closely receive by and securely engaged with both the spindle
housing 413, 414 and the locking sleeve 502, to reduce further the
possibility of play in the interconnection between the two
assemblies.
[0053] Its form helps it to lodge itself in the diameter cut at the
end of one of the J-slots in the external locking sleeve. This cut
diameter is identical to the largest diameter of the mobile pin.
The path of the J-slot outside of this specific diameter is sized
according to the smaller diameter of the mobile pin. The pin then
slides the length of the J-slot and clicks into the diameter cut at
the end of one of the J-slots in the external locking sleeve. The
corresponding slot in the internal z-sleeve must be cut in order
that the large diameter of the mobile pin can slide the entire
length of the external J-slot. This slot is in fact an L-slot of
which the diameter is that of the larger diameter of the fixed
pin.
[0054] FIG. 12 is a perspective end view of the spindle housing
413, 414 showing the bayonet J-slots 392a and 392b. In some of the
embodiments illustrated, one of the two bayonet slots 390 includes
a close tolerance, fitted bayonet pin seat 620. However, as known
to the ordinary skilled artisan, more than two bayonet slots may be
practiced in the present invention. Additionally, as shown in FIG.
12, there may be multiple bayonet slots 392b, each having a close
tolerance, fitted bayonet pin seat 620. FIGS. 13A and 13B are
instructional illustrations of a manner in which the locking device
can be operated to engage (FIG. 13A) or to disengage (FIG. 13B) the
drive end of the spindle housing.
[0055] Referring now to FIG. 14, collectively, these different
types of housing parts 213-214, 313-314, and 413-414 can be
provided as a kit 600 having a selection of different sized reamer
housings 113, tool heads 10, an impactor 602, acetabular implants
(not shown), femoral hip prostheses 604, and acetabular cup
prostheses 606, the selection of different reamer housing
configurations allowing the surgeon to select between a bent,
offset configuration or a straight configuration of the reamer
spindle depending on the surgeons approach, which may vary during
the same operation of between different patients.
[0056] While the above description contains many specifics, these
should not be construed as limitations on the scope of the
invention, but rather as exemplifications of one or another
preferred embodiment thereof. Other variations are possible, which
would be obvious to one skilled in the art. Accordingly, the scope
of the invention should be determined by the scope of the appended
claims and their equivalents, and not just by the embodiments.
* * * * *