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Claims  |
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I claim:
1. A surgical endoscope support device for supporting a surgical endoscope
at an end of an external support arm over, and proximate to, a surgical
site of a patient, the endoscope support device comprising:
a socket housing having substantially flattened upper and lower outer
surfaces, an outer side surface between the upper and lower surfaces, and
a centrally positioned inner bore communicating between the upper and
lower surfaces, the inner bore having a spherical surface;
a pivot having substantially flattened upper and lower surfaces
positionable within the inner bore of the socket housing, in pivotable
contact with the spherical surface of the inner bore, such that the pivot
lower surface extends beyond the socket housing lower surface, the pivot
including a cylindrical bore through the center of the pivot, the
cylindrical bore having a substantially uniform inner diameter along a
long axis of the cylindrical bore, the cylindrical bore adaptable for
slidable telescoping engagement of the surgical endoscope through the
cylindrical bore; and
means for attaching the outer surface of the socket housing to the external
support arm.
2. The endoscope support device of claim 1 in which the socket housing
includes a cylindrical counter bore in the upper surface centered around
the open communication between the inner bore and the upper surface, the
counter bore having a threaded wall, and further comprising a pivot
retaining ring having an outer threaded surface complimentary to the
threaded wall of the counter bore and a spherical inner surface such that
when the pivot retaining ring is threaded into the counter bore, the
spherical inner surface is continuous with the spherical surface of the
inner bore of the socket housing.
3. The endoscope support device of claim 1 in which the socket housing
includes a cylindrical side bore extending from the outer side to the
inner bore along an axis directed towards the geometric center of the
spherical surface of the inner bore, the side bore in open communication
with the inner bore and the outer side, the side bore having a threaded
wall, and further comprising a snub screw having complimentary thread to
the threaded wall of the side bore such that an end of the screw, when
threaded into the side bore, may abut the pivot.
4. The endoscope support device of claim 1 in which the socket housing and
pivot are constructed with bio-compatible, sterilizable surgical grade
metal.
5. The endoscope support device of claim 1 in which the socket housing and
pivot are constructed with bio-compatible, sterilizable surgical grade
polymer.
6. The endoscope support device of claim 1 in which the socket housing is
constructed with bio-compatible, sterilizable surgical grade metal and the
pivot is constructed with bio-compatible, sterilizable surgical grade
polymer.
7. The endoscope support device of claim 1 further comprising a skirt
positionable at the lower surface of the socket housing extending between
the lower surface and the patient.
8. The endoscope support device of claim 7 in which the skirt is
constructed with a resilient polymer.
9. A surgical endoscope support device for supporting a surgical endoscope
at an end of an external support arm over, and proximate to, a surgical
site of a patient, the endoscope support device comprising:
a support and pivot body including a socket housing and a pivot, the socket
housing having substantially flattened upper and lower outer surfaces, an
outer side surface extending between the upper and lower surfaces, and a
centrally positioned inner bore in open communication between the upper
and lower surfaces, the inner bore having a spherical surface, and the
pivot having substantially flattened upper and lower surfaces positionable
within the inner bore of the socket housing, in pivotable contact with the
spherical surface of the inner bore, such that the pivot lower surface
extends beyond the socket housing lower surface, the pivot including a
cylindrical bore through the center of the pivot, the cylindrical bore
having a substantially uniform inner diameter along a long axis of the
cylindrical bore;
an endoscope adapter having a substantially cylindrical outer wall and a
substantially cylindrical central bore, the outer wall having an outer
dimension substantially equivalent to the inner diameter of the
cylindrical bore of the pivot ball for a sufficiently snug fit when the
endoscope adapter is positioned within the cylindrical bore, the central
bore of the adapter being adaptable for slidable telescoping engagement of
the surgical endoscope through the central bore; and
means for attaching the outer surface of the socket housing to the external
support arm.
10. The endoscope support device of claim 9 in which the socket housing
includes a cylindrical counter bore in the upper surface centered around
the open communication between the inner bore and the upper surface, the
counter bore having a threaded wall, and further comprising a pivot
retaining ring having an outer threaded surface complimentary to the
threaded wall of the counter bore and an a spherical inner surface such
that when the pivot retaining ring is threaded into the counter bore, the
spherical inner surface is continuous with the spherical surface of the
inner bore of the socket housing.
11. The endoscope support device of claim 9 in which the socket housing
includes a cylindrical side bore extending from the outer side to the
inner bore along an axis directed towards the geometric center of the
spherical surface of the inner bore, the side bore in open communication
with the inner bore and the outer side, the side bore having a threaded
wall, and further comprising a snub screw having complimentary thread to
the threaded wall of the side bore such that an end of the screw, when
threaded into the side bore, may abut the pivot.
12. The endoscope support device of claim 9 in which the socket housing and
pivot are constructed with bio-compatible, sterilizable surgical grade
metal.
13. The endoscope support device of claim 9 in which the socket housing and
pivot are constructed with biocompatible, sterilizable surgical grade
polymer.
14. The endoscope support device of claim 9 in which the socket housing is
constructed with biocompatible, sterilizable surgical grade metal and the
pivot is constructed with biocompatible, sterilizable surgical grade
polymer.
15. The endoscope support device of claim 9 in which the endoscope adapter
is constructed with biocompatible, sterilizable surgical grade metal.
16. The endoscope support device of claim 9 in which the endoscope adapter
is constructed with biocompatible, sterilizable surgical grade polymer.
17. The endoscope support device of claim 9 in which the endoscope adapter
includes a plurality of ribs on the outer wall.
18. The endoscope support device of claim 9 further comprising a skirt
positionable at the lower surface of the socket housing extending between
the lower surface and the patient.
19. The endoscope support device of claim 18 in which the skirt is
constructed with a resilient polymer.
20. The endoscope support device of claim 18 in which the endoscope adapter
central bore includes a taper in the central bore at that end of the
central bore proximate the lower surface narrowing the inner diameter of
the central bore. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention relates generally to positioning devices for supporting
instruments and in particular to a support and pivot assembly for holding
a surgical endoscope.
BACKGROUND OF THE INVENTION
The use of endoscopes to assist surgeons during surgical procedures has
grown dramatically over the last several decades. For example, in surgical
procedures involving the knee, the endoscope has become an indispensable
tool for the surgeon in providing access within the patient through
minimal incisions bringing in illumination, and through optics the surgeon
may view the internal surgical field. One or more additional ports may
also be available through which the surgeon may pass other surgical
instruments, irrigation fluids, and/or vacuum for removing debris and
irrigation fluids. Many endoscopes use fiber optics so that they may
remain flexible and are useful for traversing long, tortuous channels such
as the upper and lower gastrointestinal tracts.
Other endoscopes are rigid in nature and may or may not use internal
optical fiber pathways. Rigid endoscopes are useful during procedures such
as arthroscopy and laparoscopy because of the physical demands placed on
the scopes during the procedures. The use of fiber optics has become
increasingly popular because of its ability to be coupled with video
imaging equipment. The surgeons and their assistants are able to all
follow, as a group, the procedure on a video monitor versus the other
alternative which is to look directly into the scope through an ocular
lens system to directly view the procedure. This older method
substantially precludes anyone besides the surgeon from directly viewing
the surgical procedure.
As is often the case, once the endoscope has been positioned to view the
operative procedure within the patient's body, the endoscope needs to be
held stationary in that position for the period of time that the procedure
is underway. Occasionally, the endoscope will be maneuvered in order to
view the procedure from a different angle or to carry the operative
procedure to a different area of the patient's body. Once the endoscope is
maneuvered, it is then desirable to once again hold the endoscope
stationary in that new position.
In the early days of operating with endoscopes, the surgeon was usually the
person to insert the endoscope and also the one to hold the endoscope.
This had the disadvantage of taking away at least one of the surgeon's
hands from the operation. It was not too long before duties of holding the
endoscope were passed along to assistants in the operating room who were
called to assist in the case in order to hold the endoscope. The
occasional repositioning would be undertaken by the surgeon after which
the assistant would take over holding the scope. Either way, with the
surgeon holding the scope or the assistant holding the endoscope, after a
period of time the person becomes quite fatigued and their ability to hold
the endoscope stationary markedly deteriorates. Untoward or unexpected
movement of the endoscope at critical moments in the surgery could lead to
very deleterious results, placing the patient in unnecessary danger.
Various mechanical means have been adapted for use in the operative field
in order to stabilize endoscopes over long periods of time. One such
device is known as a Greenfield support which essentially is a support
using alternating cylinders and balls threaded over a cable attached to a
mount at one end and a lever at the other end for placing the cable on
tension. By levering a tension force through the cable, the alternating
balls and cylinders are jammed together, stiffening the entire support
arm. The distinct advantage in such a system is that the support, when
loose is extremely flexible along its entire length, essentially being as
floppy as the cable within. The support is positioned and then the cable
is tensioned, the balls and cylinders stiffen into their prearranged
positions and the support becomes stable in that position. Such a support
is extremely versatile in providing for numerous positioning
possibilities. The distinct disadvantage is that when the levering arm is
released, the entire support becomes loose along its entire length from
the instrument mounted at one end to the lever at the other end.
Greenfield supports require the surgeon to carefully control the working
head of the support prior to release of the tensioned cable. Attempts to
reposition while tensioned also results in unexpected motions because no
one can predict at which cylinder to ball interface the motion will occur.
Motion may occur in a Greenfield support at a substantial distance
unacceptably far from the operative site.
Alternative supports have been described using jointed retracting arms
restrained to one to two degrees of freedom depending on the number of
joints employed and the type of joint, but with an appropriate number of
joints, pivoting about all three axes is attainable. The disadvantage of
such systems is that motion about any given axis is carried out at
distinctly different positions along the articulated support arm.
Therefore, any motion along one of the three axes may necessarily have to
be carried at a substantial distance unacceptably far from the operative
site. For example, a motion in a joint that would cause translation of the
endoscope may not be possible and possibly dangerous to the patient
because of the endoscope's position within, and relative to, the patient's
body and anatomical structures within the patient's body. Thus, even
though these types of supports may allow for translation and rotation
about all three axes, in reality these types of systems are severely
limited because they do not take into account the physical restraints
placed on the endoscope by virtue of its being positioned within the
patient's body.
U.S. Pat. No. 5,441,042 issued to Putman on Aug. 15, 1995 is an example of
just such a multi-articulated support arm. The endoscope instrument holder
as contemplated by Putman has a clamp held distally on the arm with a
knurled screw for clamping down on the endoscope body. There is no degree
of freedom of motion at the clamp to endoscope junction. The first
allowable motion is some distance away from and proximal to the clamp and
as shown only provides motion in two of the three axes, one of those axes
being translation along the long axis of the clamp and its associated rod.
Consequently, simple rotation around the pivot proximal to the clamp will
result in large motions of the endoscope through the arc of that pivot,
having a radius equivalent to the length of the rod and the clamp. Such
gross motions are usually not acceptable during a surgical procedure.
Surgeons relying on operating endoscopes need to be able to securely
support the endoscope when positioned so that extraneous motion is
eliminated but yet retain the ability to fine tune the positioning of the
endoscope as the surgical procedure goes forward. There is a need for an
endoscope support and pivot that will provide a surgeon the ability to
stabilize the endoscope when needed and yet carry out fine translation and
rotational motions, through all three planes, at the site of surgery.
SUMMARY OF THE INVENTION
The present invention discloses a surgical endoscope support device for
supporting a surgical endoscope at an end of a support arm over, and
proximate to, a surgical site of a patient comprising a socket housing and
a pivot ball, the socket housing having substantially flattened upper and
lower outer surfaces, an outer side surface between the upper and lower
surfaces, and a centrally positioned inner bore communicating between the
upper and lower surfaces, the inner bore having a spherical surface, the
pivot ball, positionable within the inner bore of the socket housing, in
pivotable contact with the spherical surface of the inner bore, the pivot
ball including a cylindrical bore through the center of the pivot ball,
the cylindrical bore having a substantially uniform inner diameter along a
long axis of the cylindrical bore, the cylindrical bore adaptable for
slidable telescoping engagement of the surgical endoscope through the
cylindrical bore, and a universal type attachment for attaching the outer
surface of the socket housing to any one of the many support arms
available.
A preferred embodiment of the surgical endoscope support device comprises a
support and pivot body and an endoscope adapter, the support and pivot
body including a socket housing and a pivot ball, the socket housing
having substantially flattened upper and lower outer surfaces, an outer
side surface extending between the upper and lower surfaces, and a
centrally positioned inner bore in open communication between the upper
and lower surfaces, the inner bore having a spherical surface, and the
pivot ball, positionable within the inner bore of the socket housing, in
pivotable contact with the spherical surface of the inner bore, the pivot
ball including a cylindrical bore through the center of the pivot ball,
the cylindrical bore having a substantially uniform inner diameter along a
long axis of the cylindrical bore, the endoscope adapter having a
substantially cylindrical outer wall and a substantially cylindrical
central bore, the outer wall having an outer dimension substantially
equivalent to the inner diameter of the cylindrical bore of the pivot ball
for a sufficiently snug fit when the endoscope adapter is positioned
within the cylindrical bore, the central bore of the adapter being
adaptable for slidable telescoping engagement of the surgical endoscope
through the central bore and a universal type attachment for attaching the
outer surface of the socket housing to any one of the many support arms.
The ball and socket design coupled with the central bore of the pivot ball,
with or without the adapter, is useful to a surgeon using an endoscope to
position the endoscope over the skin incision in the patient. The present
invention provides for motion of the endoscope in all three planes from a
single, localized point within the endoscope support and pivot. Therefore,
the arc of rotation is no longer than that portion of the endoscope itself
extending beyond the localized point. By placing the endoscope support and
pivot proximate the skin of the patient, this radius, in essence, also
becomes the smallest radius of motion possible. The surgeon may advance
the endocsope into the patient or withdraw the endoscope in a slidable
telescoping translation through the long axis of the central bore, and may
translate the distal tip of the endoscope through an arc having a radius
no longer than that length of endoscope extending from the endoscope
support and pivot into the patient. Sideways translational movements of
the endoscope at the skin surface of the patient are minimal, thus
substantially limiting any sideways forces that the endoscope may exert on
the tissues the endoscope traverses through and thus substantially
diminishing the likelihood of injury to these tissues.
The endoscope support and pivot of the present invention may be constructed
from any number of bio-compatible polymers, copolymers, metals and metal
alloys suitable for use as surgical grade material capable of being
cleaned and sterilizable in an autoclave or gas sterilizer. To facilitate
cleaning, the invention anticipates the addition of a threaded retaining
ring for use within the upper surface that, when removed, facilitates
removal of the pivot ball from the inner bore of the socket housing.
The endoscope adapter is intended to have a snug fit within the central
bore so as to not come out while using the endoscope. To facilitate a snug
friction fit, the present invention anticipates the use of ribs raised in
the outer surface of the endoscope adapter. These ribs are particular
beneficial when the endoscope adapter is constructed with polymeric
compounds that are deformable and are crushed when the endoscope adapter
is pushed into the central bore.
The slidable telescoping fit between the endoscope adapter and endoscope
should also maintain a gentle friction fit to eliminate inadvertent
sliding of the endoscope when not pushing or pulling the endoscope. The
present invention anticipates placing a slight taper at the lower end of
the endoscope adapter bore narrowing the inner diameter. This is
especially useful when using polymeric compounds that are deformable, yet
retain some resiliency. Coupling the taper with selection of those
polymers with greater surface lubrisity provides for a reasonably stable
support of the endoscope, without movement through the endoscope adapter
bore, unless under gentle urging by the surgeon.
An additional advantage of the present invention is use of a snub screw to
increase control over the pivot ball. The pivot ball and socket may be
constructed to tolerances that will provide sufficient friction between
the parts to prevent motion unless urged to do so by the surgeon. Addition
of a snub screw provides increased reliability in preventing unwanted and
potentially dangerous movement of the endoscope.
Other objects of the present invention and many of the attendant advantages
of the present invention will be readily appreciated as the same become
better understood by reference to the following detailed description when
considered in connection with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a partially cross sectioned, partially exploded, side elevational
view of an embodiment of the present invention;
FIG. 2 is a top plan view of the embodiment of the present invention
depicted in FIG. 1;
FIG. 3 is a perspective, partially exploded, view of the present invention
depicted in FIG. 1 shown in relation to a typical support arm, shown in
phantom;
FIG. 4 is a perspective view of the present invention depicted in FIG. 1
shown set up with an endoscope, shown in phantom;
FIG. 5 is a perspective view of the present invention depicted in FIG. 3
shown set up in a typical support arm and positioned adjacent a portion of
a patient, both shown in phantom.
DETAILED DESCRIPTION OF THE INVENTION
Referring to the Figures, wherein like numbers refer to like components,
there is depicted in FIGS. 1 and 2 an embodiment of the present invention
disclosed as an endoscope support and pivot head 10 including a pivot body
12 and an endoscope adapter 14. Pivot body 12 comprises a socket housing
16, a pivot ball 18 adapted to fit within socket housing 16, a pivot ball
retaining ring 20, a pivot ball snub screw 22, and an adaptable support
mount 24. Pivot ball 18 includes a central cylinder wall 26 defining a
central bore 28.
Endoscope adapter 14 includes an adapter cylinder 30 having an outer
cylinder wall 32 and an inner cylinder wall 34 which defines an adapter
bore 36. Endoscope adapter 14 also includes an adapter taper 38 at the
lower end of adapter bore 36, a stop flange 40, multiple fitting ribs 42
on outer cylinder wall 32 and a flange tab 44.
Pivot body 12 is comprised of a ball and socket joint mechanism wherein
pivot ball 18 is free to articulate within socket housing 16. The present
invention anticipates that these two components may be constructed out of
any bio-compatible material that is suitable for use in surgical
instruments and capable of undergoing sterilization in either an autoclave
or through gas sterilization. There are a number of available materials
such as stainless steel and other metal alloys as well as polymer and
copolymer compounds including such polymers as polyvinyl chloride,
polyethylene, and related plastics.
Strict adherence to surgical technique and sterilization necessitates that
surgical instruments be thoroughly cleaned and sterilized. To facilitate
removal of the pivot ball, ball retaining ring 20 has been incorporated
into the design of socket housing 16 to provide ease of removal of pivot
ball 18 from socket housing 16. Ball retaining ring 20 is threaded at its
outer perimeter and has a spherical inner surface that matches, and is
continuous with, the inner spherical surface of socket housing 16 when
ball retaining ring 20 is threaded into place. Ball retaining ring 20
provides users of the present invention the ease of completely dismantling
all the component parts for easy cleaning and sterilization as well as
direct visualization of all of the component parts to ensure that all the
parts are in proper working order and are thoroughly cleaned.
The present invention anticipates that pivot ball 18 is adaptable to
receive an endoscope instrument through its central bore 28 in a
relatively snug yet slidable telescoping arrangement. Since endoscopes
come in various different outer diameters, pivot ball 18 may be
manufactured so as to provide the user a selection of pivot balls, each
having a different center bore inner diameter. Use of ball retaining ring
20 provides for easy removal of one pivot ball and replacement with
another if the surgeon changes endoscopes having different outer diameters
during a procedure.
Recognizing the versatility of the present invention, it is preferred that
pivot ball 18 and socket housing 16 be manufactured as standard, single
sized components. Endoscope adapter 14 may be used then as an alternative
interface between an endoscope and adapter bore 36, with the inner
diameter of central bore 28 and the outer diameter of outer cylinder wall
32 standardized and complementary to each other so as to fit snugly
without unintended motion between the two components.
This has an advantage in that endoscope adapter 14, overall, is a smaller
component than pivot ball 18. A number of different sizes of endoscope
adapter 14, with varying diameters for adapter bore 36, are anticipated
for the present invention and useful for supporting all endoscopes. The
size range for the diameters of adapter bore 36 is as broad, and numerous,
as are the number of endoscopes available now and in the future.
Manufacturing costs are substantially less when using an insert such as
endoscope adapter 14, because of its smaller size and having a
standardized outer cylinder wall 32.
Endoscope adapter 14 may be manufactured from a number of different
materials much like pivot body 12, and endoscope adapter 14 may also be
disposable. The present invention anticipates that a set of multiple sizes
of endoscope adapter 14 may be provided with each support and pivot head
10, each having a different internal diameter for adapter bore 36. The
present invention also anticipates that multiple sizes of endoscope
adapter 14 may be provided separately further diminishing costs. A
surgical facility need only obtain one standard ball and socket that is
re-sterilizable and reusable and purchase disposable sets of the smaller
adapter.
Socket housing 16 and pivot ball 18 may be manufactured to provide
sufficient friction between the mating surfaces of socket housing 16 and
pivot ball 18 so as to provide adequate support for a mounted endoscope
preventing independent motion of pivot ball 18 relative to socket housing
16. Such manufacturing, however, demands close tolerances and use of
materials that will not easily break down over time when manufactured at
such close tolerances. A useful addition is pivot ball snub screw 22 which
provides the surgeon the capability of controlling the amount of friction,
and thus the stability, of pivot ball 18 relative to socket housing 16.
Additionally, a resilient polymeric or rubber snub screw tip 23 may be
used in association with snub screw 22 at its contact with the surface of
pivot ball 18 to diminish the likelihood of wear on the outer surface of
pivot ball 18 in contact with snub screw 22.
Endoscope adapter 14 anticipates the use of several other optional
features. One feature is multiple fitting ribs 42 on outer cylinder wall
32. Multiple fitting ribs 42 are useful for providing a substantially snug
fit between endoscope adapter 14 and central cylinder wall 26 of pivot
ball 18 when endoscope adapter 14 is pushed into central bore 28. As shown
in FIGS. 1 and 3, ribs 42 are substantially parallel to the long axis of
endoscope adapter 14. The present invention anticipates that ribs 42 may
take on a number of different orientations, not shown, most notably as
ribs circumferentially placed about the outer cylinder wall 32 transverse
to the long axis of endoscope adapter 14.
Other optional additions to endoscope adapter 14 are flange 40 and flange
tab 44. Flange 40 is useful as a stop when endoscope adapter 14 is pressed
into central bore 28 of pivot ball 18. Flange tab 44 is useful for
providing a grasping tab to facilitate removal of endoscope adapter 14.
Flange tab 44 may be grasped by the surgeon or an assistant and also by
using a surgical instrument such as a hemostat or clamp.
Endoscope adapter 14 also anticipates the use of adapter taper 38 to
improve the fit between an endoscope and inner cylinder wall 34 of
endoscope adapter 14. The adapter taper 38 is particularly useful when
endoscope adapter 14 is manufactured out of a polymeric compound. The
deformability of polymers, coupled with the general characteristics of
resilience, enables adapter taper 38 to snugly fit against the surface of
an endoscope. This snug fit, coupled with such factors as surface
lubrisity of the polymers used, provides adequate support to the endoscope
while still enabling slidable, telescoping movement of the endoscope
relative to endoscope adapter 14 with gentle urging from the surgeon.
Turning to FIG. 3, there is also shown a skirt 46 with an inner rim ridge
48 for abutting against the lower edge of pivot body 12 when skirt 46 is
placed on pivot body 12 as shown in FIG. 4. Skirt 46 is manufactured from
polymers and preferably is a closed cell foam, but may be open cell or
solid. Skirt 46 may also be used to further dampen unwanted vibrations in
the entire system by acting as a vibration dampener when attached to pivot
body 12 and then put in contact with the surface of the patient. This is
particularly beneficial in neurosurgical applications where the risk of
injury to the soft brain structures is markedly greater. The fine work and
small space within which a neuroendoscope is placed also benefits from the
vibration dampening effects of skirt 46.
Additionally, there is shown a support arm 50 adapted for receiving
adaptable support mount 24. The type or structure of support arm 50 is of
no particular importance to the present invention. The present invention
is useful with all types and makes of support arms, such as Greenfield
support arms or other articulated arms such as support arm 50. The type of
support arm is immaterial because once the endoscope support and pivot of
the present invention is put in place over the surgical field, the support
arm is locked into its position and does not need to be moved again for
the remainder of the surgical procedure. Therefore, support arm 50 may be
of any type and adaptable support mount 24 may be changed to correspond to
the mating portion of the support arm chosen.
In operation, and referring to FIGS. 1 through 5, the entire endoscope
support and pivot head 10 is sterilized and then assembled by placing
pivot ball 18 into socket housing 16 and screwing ball retaining ring 20
into place. In the preferred embodiment, an appropriate endoscope adapter
14 is chosen so as to match the outer diameter of the endoscope, such as
an endocsope 52, that the surgeon will use. Endoscope adapter 14 is then
pushed into central bore 28 of pivot ball 18 abutting flange 40 against
pivot ball 18. An alternative arrangement of the present invention is to
manufacture pivot ball 18 in a range of central bore 28 diameters. Then
depending on the endoscope to be used, the pivot ball having the
corresponding central bore 28 diameter is chosen and the endoscope is
placed directly through central bore 28.
Endoscope support and pivot head 10 and a support arm, such as support arm
50, are then brought into the sterile surgical field. Endoscope support
and pivot head 10 is mounted to the support arm at adaptable support mount
24 and pivot body 12 is positioned over the surgical site and incision in
the patient. Skirt 46 may or may not be needed , but is shown in position
in FIG. 4. Skirt 46 is mountable onto the lower portion of socket body 12
and useful as a barrier around the surgical incision site such as the
trephine in a patient's skull surface 54.
Endoscope 52 is now positionable within central bore 36 of endoscope
adapter 14 and is in slidable telescoping relation to central bore 36.
Endoscope 52 is controllable by the operating surgeon in all three planes
as shown by bidirectional arrow 56 in the z axis by slidable telescoping
movement of the endoscope through adapter bore 36 along the long axis of
endoscope adapter 14 and bidirectional arrow 58 for the x and y axes as
provided by the articulation of pivot ball 18 in socket housing 16.
It is anticipated that the present invention is useful for all rigid
endoscopes for all surgical procedures involving those rigid endoscopes in
different anatomical locations. One such example is the use of a
neuroendoscope within endoscope support and pivot 10 positioned over a
trephine through a patient's skull to provide viewing and surgical access
within a patient's brain. The endoscope may be slowly and methodically
advanced through endoscope adapter 14 along the direction of
bi-directional arrow 56. The pivoting relationship of pivot ball 18 to
socket housing 16 allows the surgeon to impose pivoting directions in the
x and y planes as is shown by bidirectional arrow 58. In this way, the
surgeon is able to approach, reposition, back off and approach again to
different anatomical structures within a patient's brain minimizing motion
of the endoscope by localizing the pivot point to a single point within
endoscope support and pivot 10 immediately adjacent to and just over the
incision.
This endoscope motion control is a substantial improvement over the prior
art. Use of a Greenfield or an articulating arm imposes translation
motions that substantially exceed the total width of the trephine hole
because motion may be imparted in these supports at articulation joints
considerably distant from the surgical incision. Additionally, and
particularly in neurosurgery, the soft structure of the brain is easily
damaged by unacceptably extensive lateral or translational motions. With
the present invention, lateral and translational motions are limited to an
arc equal to just that length of the endoscope extending beyond the point
of rotation of pivot ball 16. This is effectively a substantially smaller
arc and radius when compared to the prior art where the radius of the arc
includes not only the length of the endoscope, but also that portion of
the articulating arm proximal to the endoscope involved in carrying out
the motion.
The foregoing is considered as illustrative only of the principles of the
invention, and since numerous modifications and changes will regularly
occur to those skilled in the art, it is not desired to limit the
invention to the exact construction and operation shown and described
herein and accordingly, all suitable modifications and equivalents may be
resorted to falling within the scope of the present invention.
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