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Claims  |
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What is claimed is:
1. A surgical instrument support structure comprising:
a support bracket;
an elongated leg assembly slidably connected to said support bracket for
longitudinal movement with respect thereto, said leg assembly including a
gear rack member;
a gear brace connected to said support bracket, said gear brace being
rotatable relative to said support bracket;
a gear member rotatably connected to said gear brace, said gear member
being selectively engageable with said gear rack member;
a ratchet mechanism engageable with said gear member for controlling the
rotation of said gear member; and
an arm assembly extending from said leg assembly for holding a surgical
instrument.
2. A surgical instrument support structure in accordance with claim 1
including a crank engageable with said gear member for rotation thereof.
3. A surgical instrument support structure in accordance with claim 2
wherein said crank includes a pawl that is engageable with said gear
member.
4. A surgical instrument support structure in accordance with claim 1
wherein said arm assembly is rotatable relative to said leg assembly.
5. A surgical instrument support structure in accordance with claim 1
wherein said gear rack member is movable between an engaged position
wherein said gear rack member is engaged with said gear member and a
disengaged position wherein said gear rack member is disengaged from said
gear member.
6. A surgical instrument support structure in accordance with claim 5
including a jacket member extending longitudinally adjacent said gear rack
member.
7. A surgical instrument support structure in accordance with claim 6
wherein said jacket member has at least one pin and said gear rack member
has at least one cam portion that coacts with said pin.
8. A surgical instrument support structure in accordance with claim 5
including an external adjustment collar connected to said gear rack member
for moving said gear rack member between said engaged position and said
disengaged position.
9. A support structure in accordance with claim 8 including an adjustment
handgrip that is connected to said adjustment collar.
10. A support structure in accordance with claim 9 wherein said handgrip is
configured for one-handed operation.
11. A surgical instrument support structure comprising:
a support bracket;
an elongated leg assembly slidably connected to said support bracket for
longitudinal movement with respect thereto, said leg assembly including a
gear rack member;
a gear brace connected to said support bracket;
a gear member rotatably connected to said gear brace, said gear member
being selectively engageable with said gear rack member, said gear rack
member being movable between an engaged position wherein said gear rack
member is engaged with said gear member and a disengaged position wherein
said gear rack member is disengaged from said gear member;
a jacket member extending longitudinally adjacent said gear rack member,
said jacket member having at least one pin and said gear rack member
having at least one cam portion that coacts with said pin;
a ratchet mechanism engageable with said gear member for controlling the
rotation of said gear member; and
an arm assembly extending from said leg assembly for holding a surgical
instrument.
12. A surgical instrument support structure in accordance with claim 11
wherein said pin is movable relative to said cam portion between an
engaged position wherein said gear rack member is engaged with said gear
member and a disengaged position wherein said gear rack is disengaged from
said gear.
13. A surgical instrument support structure comprising:
a support bracket;
an upwardly extending leg assembly having a longitudinal axial and slidably
connected to said support bracket, said leg assembly being selectively
movable between a raised position and a lowered position;
a gear assembly connected to said support bracket, said gear assembly being
rotatable about said longitudinal axis of said leg assembly, gear assembly
including a gear member that is engageable with said leg assembly for
Selective movement of said leg assembly between said raised position and
said lowered position; and
an arm assembly extending from said leg assembly, said arm assembly
including a holding portion for holding a surgical instrument.
14. A surgical instrument support structure in accordance with claim 13
wherein said support bracket is detachably connectable to an operating
room bed side rail.
15. A surgical instrument support structure in accordance with claim 14
including an end rail that is connectable to an operating room bed, said
support bracket being detachably connectable to said end rail.
16. A surgical instrument support structure in accordance with claim 13
wherein said leg assembly includes a gear rack member that is engageable
with said gear member.
17. A surgical instrument support structure in accordance with claim 16
wherein said gear rack member is movable between an engaged position and a
disengaged position.
18. A surgical instrument support structure in accordance with claim 17
including a jacket extending longitudinally adjacent said gear rack.
19. A surgical instrument support structure in accordance with claim 18
wherein said jacket has at least one pin and said gear rack member has at
least one cam portion that is engageable with said pin.
20. A surgical instrument support structure in accordance with claim 19
wherein said pin is movable relative to said cam portion between an
engaged position wherein said gear rack member is engaged with said gear
member and a disengaged position wherein said gear rack member is
disengaged with said gear member.
21. A surgical instrument support structure in accordance with claim 13
wherein said gear assembly includes a ratcheting crank mechanism for
adjusting said movement of said leg assembly.
22. A surgical instrument support structure in accordance with claim 13
including a force measuring gauge connected to said holding portion.
23. A surgical instrument support structure comprising:
a support bracket;
an upwardly extending leg assembly slidably connected to said support
bracket, said leg assembly being selectively movable between a raised
position and a lowered position;
a gear assembly connected to said support bracket, said gear assembly
including a gear member that is engageable with said leg assembly for
selective movement of said leg assembly between said raised position and
said lowered position, said leg assembly including a gear rack member that
is engageable with said gear member, said gear rack member being movable
between an engaged position and a disengaged position;
a jacket extending longitudinally adjacent said gear rack, said jacket
having at least one pin and said gear rack member having at least one cam
portion that is engageable with said pin; and
an arm assembly extending from said leg assembly, said arm assembly
including a holding portion for holding a surgical instrument.
24. A surgical instrument support structure, comprising:
a support bracket;
an upwardly extending leg assembly slidably connected to said support
bracket, said leg assembly including a gear rack member that is
selectively movable between a raised position and a lowered position;
a gear assembly connected to said support bracket, said gear assembly
including a rotatably mounted gear member that is engageable with said
gear rack member for selective movement of said leg assembly between said
raised position and said lowered position, said gear rack member being
selectively movable between a position in engagement with said gear member
and a position in disengagement with said gear member, said gear rack
member being spring biased toward a position in engagement with said gear
member; and
an arm assembly extending from said leg assembly, said arm assembly
including a holding portion for holding a surgical instrument. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention relates generally to surgical instruments and, more
particularly, to a support structure for supporting an abdominal lift for
use in laparoscopic surgery.
BACKGROUND OF THE INVENTION
Laparoscopic surgical procedures have been around for many years and have
recently have become more available due to advances in technology relating
to the laparoscope or video imaging system. They are much less intrusive
to the patient than typical open surgical procedures. While an open
surgical procedure may involve one primary incision that is at least 6-9
centimeters long, a laparoscopic procedure typically uses smaller
incisions, each only around 5-11 millimeters in length. In open surgery,
the surgeon cuts muscle. In laparoscopic surgery, the surgeon generally
does not cut muscle. Because they are less intrusive than open surgical
procedures, laparoscopic procedures have resulted in much shorter surgical
procedures and recovery times.
Laparoscopic procedures have typically involved insufflation of the
abdominal or peritoneal cavity with carbon dioxide and/or other gases in
order to create a pneumoperitoneum. The pneumoperitoneum establishes an
open space inside the peritoneal cavity to enable the surgeon to move the
laparoscope around and see inside.
Typically, the pneumoperitoneum is established by puncturing the abdominal
wall with a Veress needle and injecting gas from an insufflator through
the Veress needle to a pressure of around 12 mm Hg.
After insufflation, a trocar is advanced through the opening in the
abdominal wall and into the peritoneal cavity. The trocar is a tube or
cannula that usually has a gaseous seal to contain the carbon dioxide
within the peritoneal cavity and maintain insufflation. The cannula is
used for insertion of other medical instruments, such as a laparoscope,
therethrough and into the peritoneal cavity.
There may be difficulties associated with insufflation of the peritoneal
cavity. First and foremost is postoperative pain which patients may
experience in the abdomen or shoulder area due to migrating gas. This
occurs when insufflation causes excess gas pressure in the peritoneal
cavity. Excess gas pressure may also compress the pleural cavities thus
making respiration difficult. Other possible difficulties associated with
insufflation in laparoscopic surgery include subcutaneous emphysema, blood
vessel penetration, etc.
The attendant difficulties of insufflation have led to alternatives to
insufflation wherein a pneumoperitoneum is established by elevating the
abdominal wall with a mechanical lift. The lift is introduced
percutaneously into the peritoneal cavity before establishing a
pneumoperitoneum. The lift is elevated mechanically in order to distend
the abdomen. When the abdomen is distended, ambient air enters the
peritoneum through the puncture opening in the abdomen and a
pneumoperitoneum at or near ambient air pressure is established.
By establishing a pneumoperitoneum at ambient air pressure, insufflation
and the concomitant need for gaseous seals in endoscopic instruments and
trocars for maintaining a relatively high gas pressure in the peritoneal
cavity is eliminated. Thus, the attendant difficulties of insufflation, as
well as the need for costly equipment, is eliminated.
The prior art includes several abdominal lift devices. In International
Patent Application PCT/US92/4456 a lift is disclosed that has two radially
extending blades that are rotatable. The blades are closed together for
initial insertion into the abdominal cavity. After insertion, the blades
are spread or fanned. When the lift is elevated, the blades contact and
elevate the inner surface of the abdominal wall.
Societe 3X, a French company, markets an abdominal lift and support
structure. The lift is shown and described in International Patent
Application Serial No. PCT/FR91/227. The lift includes a series of curves
forming a generally triangular shape. The tip of the lift is turned
downwardly slightly. The support structure includes a crane and boom
design. Gross adjustments are made by sliding the supporting legs and the
boom within their respective holders. A mechanical screw-jack is used for
fine adjustment.
U.S. Pat. No. 5,183,033 describes a method for lifting an abdominal wall
with a set of linear and non-linear abdominal lifts. International Patent
Application PCT/U.S. No. 92/4392 describes a variety of mechanical rods,
arms and/or balloons for mechanically lifting an abdominal wall during
laparoscopic surgery.
There are some other prior art structures for elevating and/or supporting
abdominal lifts in laparoscopic surgery. U.S. Pat. No. 5,183,033
illustrates support structures using winches or U-shaped bars for use in
laparoscopic surgery.
Further, there are a number of prior art support structures for supporting
mechanical lifts used in open surgery. For example, see U.S. Pat. Nos.
5,109,831 and 4,143,652.
The adjustment capabilities of these prior art devices are limited. It
would be desirable to provide a support structure for holding an abdominal
lift in an elevated position that is mechanically operable by the surgeon
at the operating room table and has a variety of position adjustments. It
would be desirable to provide a mechanical lift adjustment having both
gross and fine adjustment capabilities and can be adjusted for left or
right-handed operation. Also, it would be desirable to provide a latch
mechanism associated with the lift mechanism wherein a leg assembly of the
support structure automatically engages a base in order to fix the height
of the abdominal lift.
SUMMARY OF THE INVENTION
The support structure for holding an abdominal lift in accordance with the
invention is mechanically operable by the surgeon at an operating room
table and has a variety of position adjustments. It has a mechanical lift
adjustment for both gross and fine adjustment which can be adjusted for
left or right-handed operation.
The support structure is detachably and slidably attachable to an operating
room table. It includes a support bracket that attaches to the side rails
of an operating room table. In an alternative aspect of the invention, an
end rail is provided for attachment to the side rails of an operating room
table and the support bracket is detachably and slidably connectable to
the end rail. Thus, the support structure can be positioned at the end of
an operating room table.
An upstanding leg assembly is rotatably and slidably attached to the
support bracket. An arm assembly is rotatably and slidably connected to
the leg assembly. The distal end of the arm assembly has a holding portion
for holding an abdominal lift.
The leg assembly includes a gear rack member which is engageable with a
gear member. The gear member is held by a gear brace that is connected to
the support bracket. The gear member ratchets for vertical adjustment of
the leg assembly.
The gear rack member is movable between an engaged position wherein the
gear rack member is engaged with the gear member and a disengaged position
wherein the gear rack member is disengaged from the gear member. When the
gear rack member and gear member are engaged, then the leg assembly is
prevented from sliding downwardly relative to the support bracket. When
the gear rack member is disengaged from the gear member, the leg assembly
slides freely relative to the support bracket for gross vertical
adjustment.
A spring biases the gear rack member toward the engaged position. Thus, the
gear rack member is automatically engaged with the gear member.
The gear rack member is movable within a gear jacket inside the leg
assembly. The jacket has a pin that coacts with a cam portion on the gear
rack member in order to move the gear rack member between the engaged
position and disengaged position.
The gear brace is rotatable relative to the support bracket whereby the
gear brace and gear member can be adjusted for either left or right-handed
operation.
In an alternative aspect of the invention, the holding portion of the arm
assembly includes a force measuring gauge for monitoring and controlling
the lift force on the surgical device being held by the support structure.
These and other aspects and attributes of the present invention will be
discussed with reference to the following drawings and accompanying
specification.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a support structure for supporting an
abdominal lift in accordance with the invention wherein the support
structure is attached to the side rail of an operating room bed and
supports an abdominal lift during laparoscopic surgery;
FIG. 2 is a perspective view of a support structure for supporting an
abdominal lift in accordance with the invention including an end rail
wherein the support structure is connected to the end rail and supports an
abdominal lift during a laparoscopic surgery;
FIG. 3 is an elevational view of a portion of the arm assembly of the
support structure attached to an abdominal lift that is inserted into the
abdomen;
FIG. 4 is an enlarged perspective view of the support structure as shown in
FIG. 2;
FIG. 5 is an exploded view of the support structure shown in FIG. 4;
FIG. 6 is an elevational view, shown in partial cross-section, of the leg
assembly and gear assembly of the support structure;
FIG. 7 is an elevational view, shown in partial cross-section, of a portion
of the leg assembly with the gear inserted therein; and
FIG. 8 is a partial perspective view of an alternative holding portion and
force measuring gauge in accordance with the invention.
DETAILED DESCRIPTION OF THE INVENTION
The following is a detailed description of the invention. The detailed
description is not intended to be an exhaustive description of all
embodiments within the scope of the invention and is not intended to limit
the scope of the claims to the disclosed embodiments. Other embodiments
within the scope of the claims will be apparent to those skilled in the
art.
Referring to FIG. 1, a support structure 10 for supporting an abdominal
lift in accordance with the invention is shown. The support structure 10
is clamped to the side rail 12 of an operating room table. The support
structure as shown is supporting an abdominal lift during laparoscopic
surgery. The two surgeons are inserting a laparoscope and laparoscopic
surgical instruments into a pneumoperitoneum established by the abdominal
lift. The surgeons view a monitor 18 which displays the view seen by the
laparoscope.
Referring to FIG. 2, a support structure 10 for supporting an abdominal
lift is clamped on an end rail 20 which is attachable to the side rails 12
of the operating room table. Thus, the support structure 10 may be mounted
at the end of the operating room table to gain access to the patient from
the end of the table.
Referring to FIG. 3, a preferred use of the support structure 10 is to
elevate and support an abdominal lift 22. The abdominal lift 22 shown in
FIG. 3 is of the type described in detail in copending patent application
Ser. No. 08/108,895, entitled Abdominal Lift Device, the disclosure of
which is incorporated by reference herein. The cavity under the lift is a
pneumoperitoneum 24 providing a work area for laparoscopic surgery.
Referring to FIG. 4, the support structure in accordance with the invention
includes an arm assembly 26, a leg assembly 28 and a base assembly 30.
The base assembly 30 includes a support bracket 32 is connectable to either
a side rail 12 of an operating room table or an end rail 20 as shown in
FIGS. 2, 4 and 5. Referring to FIG. 5, tightening knobs 33 are threaded
through the support bracket 32 to clamp down on the side rail 12 or end
rail 20 in order to hold the support bracket 32 in place. The end rail 20
is constructed from two halves 21 and 23 that are connected to each other.
Hangers 27 and 29 are provided on the two halves 21 and 23 for hanging the
end rail 20 on the side rails 12 of an operating room bed as shown in FIG.
2.
Referring to FIGS. 4 and 5, the arm assembly 26 includes a holding portion
40. The holding portion 40 has a detachable tip 42 which is inserted into
a shaft 44. A clip 46 is used to fasten the tip 42 to the shaft 44. The
shaft 44 has an end cap 48. The shaft 44 is rotatably held by a collar 50
that is inserted into a slotted retaining member 52 that fits within the
distal end of arm portion 54.
A tightening knob 56 is threaded into the collar 50 in order to tighten
down and hold the shaft 44 within the collar 50. A tightening knob 58 is
insertable into the arm portion 54 in order to tighten down and hold the
slotted retaining member 52 within the arm portion 54.
The arm portion 54 extends upwardly from the leg assembly 28. The arm
portion 54 is bent in two places at 45.degree. angles. Thus, the distal
end of the arm portion 54 is oriented at a 90.degree. angle relative to
the proximal end of the arm portion 54 and the distal end of the arm
portion 54 extends horizontally.
The bottom of the arm assembly 26 is connected to the top of the leg
assembly 28 (FIGS. 4 and 5). The bottom of the arm portion 54 has a collar
60 that receives an upwardly extending tube 62 that is part of the leg
assembly 28. As shown in FIG. 6, the upper end of the tube 62 is slidably
inserted between the collar 60 and the arm portion 54 and abuts the collar
60. A tightening knob 64 is threaded into the collar 60 in order to
tighten down on and hold the tube 62. When the tightening knob 64 is
loosened, the arm portion 54 may be rotated relative to the tube 62 in
order to rotate the arm assembly 26 relative to the leg assembly 28.
Referring to FIGS. 5 and 6, a gear rack 66 extends within the tube 62. A
horizontal slot 70 in the gear rack 66 receives a pin 68 extending across
the diameter of the tube 62 at its bottom end. The pin 68 and slot 70
cooperate to restrict vertical motion and permit horizontal motion of the
gear rack 66 relative to the tube 62. Thus, when the gear rack 66 is
raised by the gear 72 as discussed below, the tube 62 and entire leg
assembly 28 are carried with it.
Referring to FIGS. 4-6, the gear rack 66 is actuated by a gear assembly 71.
The gear assembly 71 includes a gear 72 and crank 76 rotatably mounted on
a gear brace 74. A spring loaded pawl 78 on the crank 76 and a spring
loaded ratchet 80 on the gear brace 74 cooperate with the gear 72 in order
to crank the gear 72 clockwise and prevent counter-clockwise rotation.
As shown in FIG. 6, the gear 72 extends through a slot 84 in the tube 62
and engages the gear rack 66. By rotating the crank 76 clockwise, the gear
72 is rotated clockwise and the gear rack 66 is ratcheted in an upward
direction. Thus, the gear assembly 71 functions as a lift mechanism that
lifts the leg assembly 28 and provides a fine height adjustment.
Referring to FIGS. 4 and 5, the leg assembly 28 is slidably contained
within a tubular member or can 86. The can 86 is contained between two
swivel rings 88 and 90 which are welded to the support bracket 32. The
gear brace 74 is welded to the can 86. Thus, the gear 72, gear brace 74,
can 86, swivel rings 88 and 90 and support bracket 32 are connected
together and form a base assembly 30 which receives the leg assembly 28.
The swivel rings 88 and 90 permit the can 86 to rotate relative to the
support bracket 32. The can 86 defines a slot 82 that permits the gear 72
to extend through to engage the gear rack 66 inside the leg assembly 28.
When the gear assembly 71 is rotated from a right-handed orientation as
shown in solid lines in FIG. 4, to a left-handed orientation as shown in
phantom lines in FIG. 4, the can 86, tube 62 and gear rack 66 are all
rotated with the gear assembly 71. A tightening knob 91 is threaded into
one of the rings 90 for tightening down on and holding the can 86 in order
to prevent it from rotating.
The gear rack 66 is movable within the tube 62 between an engaged position
as shown in FIG. 6 and a disengaged position as shown in FIG. 7. When the
gear rack 66 is engaged with the gear 72, the leg assembly 28 cannot move
downwardly because the gear 72 is restricted by the pawl 80. Thus, the
gear rack 66 functions as a latch mechanism for latching the leg assembly
28 to the base assembly 30 and preventing downward movement of the leg
assembly 28. When the gear rack 66 is disengaged, then the leg assembly 28
is released and free to move upwardly or downwardly relative to the base
assembly 30 for gross height adjustment.
The gear rack 66 is adjusted between its engaged and disengaged positions
by vertical movement of a pair of camming pins 92 and 94 extending within
a pair of camming slots 96 and 98 in the gear rack 66. The camming pins 92
and 94 are rigidly connected to a gear jacket 100 that envelopes the gear
rack 66 inside the tube 62.
The gear jacket 100 is vertically slidable within the tube 62. The jacket
100 is connected to an adjust collar 102 through a pin 104 (FIG. 5) that
extends through a vertically extending slot 106 in the tube 62. The slot
106 permits the pin 104 to slide vertically within it. The adjust collar
102 wraps around the tube 62 and is vertically slidable relative to the
tube 62. Thus, the gear jacket 100 can be moved in a vertical direction by
vertical movement of the adjust collar 102.
When the adjust collar 102 and gear jacket 100 are lifted, the camming pins
92 and 94 are lifted upwardly within the camming slots 96 and 98 and
thereby disengage the gear rack 66 from the gear 72, as shown in FIG. 7.
When the adjust collar 102 and gear jacket 100 are lowered, the camming
pins 92 and 94 are lowered within the camming slots 96 and 98 and thereby
cause the gear rack 66 to engage the gear 72 as shown in FIG. 6.
Referring to FIGS. 5 and 6, a spring 108 extending from the bottom of the
jacket 100 to the tube 62 biases the jacket 100 to a lowered position
relative to the tube 62 wherein the gear rack 66 is engaged with the gear
72. Thus, when the adjust collar 102 is released after having been
manually lifted for gross vertical adjustment of the leg assembly 28, the
gear jacket 100 snaps downwardly and the gear rack 66 and gear 72 are
immediately and automatically engaged.
Referring to FIGS. 4 and 5, a handgrip 110 and lift wire 112 may be
provided on the arm portion 54 for lifting the adjust collar 102. The lift
wire 112 extends downwardly and wraps around the tube 62 underneath the
adjust collar 102. When the handgrip 110 is squeezed and pulled upwardly,
it raises the lift wire 112 which in turn raises the adjust collar 102.
Thus, the handgrip 110 can be operated with one hand to disengage the gear
rack 66 and gear 72 for gross vertical adjustment of the leg assembly 28.
Referring to FIG. 8, an alternative holding portion 114 may optionally
include a force measuring gauge 116 that is calibrated to show the lifting
force being applied to a surgical device 22 that is suspended from the
holding portion 114. Preferably, the force measuring gauge is either a
conventional strain gauge, piezoelectric gauge or semi-conductor strain
gauge. For use in supporting an abdominal lift, the gauge is preferably
calibrated to show lifting forces in the range of 0 to 25 pounds. The lift
force is preferably displayed on the holding portion 114. As shown in FIG.
8, there are two windows 120 wherein one window is a conventional bar
graph display of relative force and the other window is a conventional
numerical display of force in pounds, kilograms, etc.
During use as shown in FIGS. 1 and 2, the support structure 10 may be used
in a variety of surgical applications. In particular, the support
structure may be used to support an abdominal lift 22 during endoscopic
surgery. Fine adjustment of the elevation of the abdominal lift may be
accomplished by ratcheting the support structure 10 upwardly. For gross
adjustment, the adjust collar 102 is lifted to disengage the gear rack
from the gear and permit the entire support structure to be manually
raised and lowered.
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