U.S. patent application number 13/553926 was filed with the patent office on 2012-11-15 for surgical stapler with universal articulation and tissue pre-clamp.
This patent application is currently assigned to Tyco Healthcare Group LP. Invention is credited to John W. Beardsley, Clifford L. Emmons, Lee Ann Olson, David C. Racenet, Philip Roy, Ralph Stearns.
Application Number | 20120286022 13/553926 |
Document ID | / |
Family ID | 32093855 |
Filed Date | 2012-11-15 |
United States Patent
Application |
20120286022 |
Kind Code |
A1 |
Olson; Lee Ann ; et
al. |
November 15, 2012 |
Surgical Stapler with Universal Articulation and Tissue
Pre-Clamp
Abstract
A tool assembly for a surgical stapling device includes a
channel member for supporting a staple cartridge therein and an
anvil to deform a plurality of staples ejected from the staple
cartridge thereagainst. The tool assembly also includes a sled
which is movable to force the staples from the cartridge against
the anvil to staple tissue disposed between the anvil and the
staple cartridge. A dynamic clamping member is included which has a
pin which movably engages the anvil and a flange which movably
engages the channel assembly. The dynamic clamping member is
mounted to and movable with the sled. The pin and the flange of the
dynamic clamping member cooperating to oppose the forces associated
with clamping and stapling tissue and also to maintain a
substantially uniform gap between the anvil and the staple
cartridge during stapling of the tissue.
Inventors: |
Olson; Lee Ann;
(Wallingford, CT) ; Roy; Philip; (Orange, CT)
; Beardsley; John W.; (Wallingford, CT) ; Stearns;
Ralph; (Bozrah, CT) ; Racenet; David C.;
(Litchfield, CT) ; Emmons; Clifford L.; (Oakville,
CT) |
Assignee: |
Tyco Healthcare Group LP
Mansfield
MA
|
Family ID: |
32093855 |
Appl. No.: |
13/553926 |
Filed: |
July 20, 2012 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11998035 |
Nov 28, 2007 |
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13553926 |
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10529799 |
Mar 30, 2005 |
7726537 |
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PCT/US03/31716 |
Oct 6, 2003 |
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11998035 |
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60416372 |
Oct 4, 2002 |
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Current U.S.
Class: |
227/176.1 |
Current CPC
Class: |
A61B 17/07207 20130101;
A61B 2017/2927 20130101; A61B 2017/07285 20130101; A61B 2017/07214
20130101; A61B 17/072 20130101; A61B 2017/320024 20130101; A61B
2017/07278 20130101; A61B 2017/320052 20130101; A61B 2017/2939
20130101; A61B 2017/2929 20130101; A61B 17/068 20130101; A61B
2017/2932 20130101 |
Class at
Publication: |
227/176.1 |
International
Class: |
A61B 17/068 20060101
A61B017/068 |
Claims
1-8. (canceled)
9. A surgical stapling loading unit for connection to a surgical
stapler, the loading unit comprising a tool assembly having an
anvil assembly and a channel dimensioned to receive a replaceable
staple cartridge assembly, the staple cartridge assembly having a
plurality of surgical staples, the loading unit having a connector
portion for connecting to a shaft.
10. The loading unit according to claim 9, wherein the tool
assembly is pivotally mounted.
11. The loading unit according to claim 9, wherein the channel has
a bottom surface and upwardly extending side walls.
12. The loading unit according to claim 9, wherein the channel
includes a plurality of mechanical interfaces for matingly
receiving a corresponding plurality of mechanical interfaces
disposed on outer-facing surfaces of the staple cartridge
assembly.
13. The loading unit according to claim 9, wherein the staple
cartridge assembly includes a sled.
14. The loading unit according to claim 9, wherein the staple
cartridge assembly includes a dynamic clamping member.
15. The loading unit according to claim 14, wherein the dynamic
clamping member includes a knife blade.
16. The loading unit according to claim 9, wherein the staple
cartridge assembly includes a plurality of pushers.
17. The loading unit according to claim 9, wherein the anvil has a
plurality of staple forming recesses.
18. A surgical stapler having a housing and a shaft, the shaft
removably attachable to the connector portion of the loading unit
according to claim 9.
19. The surgical stapler according to claim 18, wherein the shaft
is removable from the housing.
20. The surgical stapler according to claim 18, wherein the stapler
further includes a handle assembly.
21. A kit having the loading unit according to claim 9 and a first
staple cartridge assembly and a second staple cartridge
assembly.
22. The kit according to claim 21, wherein the first staple
cartridge assembly has surgical fasteners of a different size than
the second staple cartridge assembly.
Description
CROSS REFERENCE TO RELATED APPLICATION
[0001] This application is a continuation of U.S. patent
application Ser. No. 10/529,799, filed Mar. 30, 2005, which claims
priority from U.S. Provisional Application Ser. No. 60/416,372,
filed on Oct. 4, 2002. Each of these applications is incorporated
herein in its entirety by reference.
BACKGROUND
[0002] 1. Technical Field
[0003] This application relates to a surgical stapling apparatus,
and more particularly, to an articulating endoscopic surgical
stapling apparatus which sequentially applies a plurality of
surgical fasteners to body tissue and subsequently incises the
fastened tissue.
[0004] 2. Background of Related Art
[0005] Surgical devices wherein tissue is first grasped or clamped
between opposing jaw structure and then joined by surgical
fasteners are well known in the art. Typically, a knife is employed
after the tissue is fastened to cut the tissue along a preferred
cutting path. The fasteners are typically in the form of surgical
staples but other types of fasteners can also be utilized to
accomplish the same or similar purpose.
[0006] Instruments for this purpose can include two elongated
members which are respectively used to capture or clamp tissue.
Typically, one of the members carries a staple cartridge which
houses a plurality of staples arranged in at least two lateral rows
while the other member has an anvil that defines a surface for
forming the staple legs as the staples are driven from the staple
cartridge. Generally, the stapling operation is effected by cam
bars or sleds that have cam surfaces that travel longitudinally
through the staple cartridge and staple pushers that sequentially
eject the staples from the staple cartridge. Typically, a knife
travels between the staple rows to longitudinally cut and/or open
the stapled tissue between the rows of formed staples.
[0007] One of the issues associated with prior stapler designs is
the tendency for the dynamic clamping member to skew or buckle as
it passes through the tissue due to the large forces generated
during stapling and cutting tissue. For example, prior dynamic
clamping member designs that carry the knife or cutting surface
provide cantilever-like designs which are designed to effectively
squeeze tissue ahead of the knife blade and the staple forming sled
to force fluids from the tissue which enhances tissue stapling and
contributes to a successful tissue staple. However, the large
forces required to staple and incise tissue tend to place undue
stresses on the cantilever knife design which may cause the knife
to skew or buckle during translation often requiring the surgeon to
fire the stapler very slowly through larger tissue structures to
avoid the possibility of the knife traveling off line.
[0008] It is an object of this disclosure to provide a surgical
stapler having an actuator, preferably, a dynamic clamping member
which enhances tissue stapling by forcing fluids out of the clamped
tissue before ejecting stapling into and stapling the tissue.
Another object of this disclosure is to provide a dynamic clamp
member that applies substantially clamping pressure upon the anvil
and cartridge assembly of the tool member of a surgical stapler as
the dynamic clamping member translates along and through the tool
assembly.
[0009] Another object of this disclosure is to provide a dynamic
clamping member that helps to provide a uniform tissue gap between
the tissue contacting surfaces of an anvil and a staple cartridge
in the immediate area of and during sequential, progressive staple
formation and tissue fastening, as well as in the area of and
during tissue cutting, if cutting is being performed.
SUMMARY
[0010] The present disclosure relates to a tool assembly for a
surgical stapler, which tool assembly includes a channel member for
supporting a staple cartridge therein and an anvil for deforming a
plurality of staples pushed from the staple cartridge thereagainst.
At least one sled is included which moves from a first position out
of operative engagement with the plurality of staples or staple
pushers to a subsequent positions which progressively and
sequentially force the staples from the staple cartridge through
the tissue disposed in the gap between the anvil and the staple
cartridge and against the anvil such that the staples deform and
staple or fasten the tissue. Typically and preferably, the sled
includes at least one angled surface which upon movement thereof
engages staple pushers that force the staples from the staple
cartridge and against the anvil.
[0011] The present disclosure also includes a dynamic clamping
member which is movable with the sled and which includes a first
mechanical interface which engages the anvil and a substantially
opposed second mechanical interface which engages the channel
assembly. The first and second mechanical interfaces of the dynamic
clamping member are in substantial vertical registration relative
to one another to oppose the forces associated with damping and
stapling tissue and to maintain a substantially uniform gap between
the anvil and the staple cartridge during stapling.
[0012] Preferably, the first mechanical interface of the dynamic
clamping member includes a pin which translates within a
corresponding slot disposed within the anvil upon movement of the
clamp assembly. The second mechanical interface of the dynamic
damping member preferably includes a central support or upward
extension which translates within a corresponding slot disposed
within the channel assembly upon movement of the dynamic clamping
member. Advantageously, the pin and the flange are dimensioned to
oppose the forces associated with the sled forcing the plurality of
staples against the anvil to staple tissue disposed
therebetween.
[0013] In one embodiment, the tool assembly includes a selectively
movable clamping collar which biases against a cam surface on the
anvil to close the anvil relative to the staple cartridge and grasp
tissue therebetween.
[0014] Another embodiment according to the present disclosure
relates to an articulating assembly for a surgical stapling device
which includes an elongated shaft having proximal and distal ends
and a longitudinal "X" axis defined therethrough. The shaft is
selectively rotatable about the longitudinal "X" axis. The
articulating assembly also includes a tool assembly which attaches
to the distal end of the shaft and includes a tube adapter which
pivotably mounts a pivot block to allow pivotable movement of the
tool assembly about a "Y" axis defined perpendicular to the "X"
axis and a "Z" axis define perpendicular to the "X" axis.
[0015] Preferably, the tool assembly also includes an anvil having
a bottom surface and a channel assembly to support a staple
cartridge therein. The staple cartridge includes a plurality of
staples therein and a tissue contacting upper surface which opposes
the bottom surface of the anvil. A movable sled is also included
which has at least one angled surface which is designed to force
the plurality of staples to deform against the bottom surface of
the anvil. The tool assembly also includes a dynamic clamping
member which moves with the sled to sever tissue after deformation
of the staples against the anvil. Preferably, rotation of the shaft
about the longitudinal "X" axis correspondingly rotates the tool
assembly about the longitudinal "X" axis.
[0016] In another embodiment, the tool assembly includes a
selectively movable clamping collar which biases against a cam
surface on the anvil to close the anvil relative to the staple
cartridge to grasp tissue therebetween.
[0017] In another embodiment, the dynamic damping member includes a
first mechanical interface which translates within a corresponding
slot disposed within the anvil upon movement of the sled and a
second mechanical interface which translates within a corresponding
slot disposed within the channel assembly upon movement of the
sled. Preferably, the first mechanical interface includes a pin and
the second mechanical interface includes a flange or plate.
Advantageously, the pin and the flange or plate are dimensioned
and/or positioned to oppose the forces associated with deforming
the plurality of staples against the anvil to staple tissue
disposed therebetween. These forces include those associated with
the resistance of compression of the tissue, and squeezing and
movement or flow of fluid within the tissue.
[0018] The present disclosure also relates to a tool assembly for a
surgical stapling device which includes an anvil having a
longitudinally disposed slot defined therethrough and a channel
assembly which also has a longitudinally disposed slot also defined
therethrough. A staple cartridge having a plurality of staples
disposed therein mechanically mounts to the channel assembly. A
sled is included preferably as part of the tool assembly and which
is selectively movable along the staple cartridge to force the
plurality of staples to deform against a bottom surface of the
anvil. The dynamic clamping assembly can include a bottom camming
surface or member, e.g., a flange, and an upwardly extending
support or extension which extends upwardly from the bottom
flange.
[0019] Preferably, the upwardly extending support or extension
includes a leading cutting edge for severing tissue and an aperture
defined through the dynamic clamping member for receiving a pin
therein. The pin is advantageously configured to ride along the
slot defined within the anvil and the bottom flange is
advantageously configured to mount through the sled and into the
slot defined within the channel assembly. Movement of the sled
moves the dynamic clamping member not only to staple tissue through
the staple cartridge but preferably also to sever tissue after
stapling it.
[0020] The pin and the bottom flange of the dynamic clamping member
are better positioned to cooperatively oppose the forces associated
with clamping and stapling tissue and maintain a substantially
uniform gap between the anvil and the staple cartridge during
progressive stapling as the dynamic clamping member translates
along the tool assembly. Preferably, the tool assembly includes a
selectively movable clamping collar which biases against a cam
surface on a proximal portion of the anvil to close or pre-clamp
the anvil relative to the staple cartridge to grasp tissue
therebetween.
BRIEF DESCRIPTION OF THE DRAWINGS
[0021] Various embodiments of the subject instrument are described
herein with reference to the drawings wherein:
[0022] FIG. 1A is a perspective view of a surgical stapler for use
with a tool assembly according to the present disclosure;
[0023] FIG. 1B is a perspective view of the tool assembly of the
surgical stapler according to the present disclosure;
[0024] FIG. 2 is an exploded view of the tool assembly of FIG.
1;
[0025] FIG. 3 is a right, perspective cross section of the tool
assembly of FIG. 1 showing internal components thereof;
[0026] FIG. 4 is a left, side, partial cross sectional view showing
a dynamic clamping member according to the present disclosure;
[0027] FIG. 5 is a top, perspective view showing an anvil for
forming a series of surgical fasteners according to the present
disclosure;
[0028] FIG. 6A is a side, perspective view of a channel assembly
for supporting a staple cartridge according to the present
disclosure;
[0029] FIG. 6B is a top, perspective view of the channel assembly
of FIG. 6A;
[0030] FIG. 7A is a side, perspective view of a sled for supporting
the dynamic clamping member according to the present
disclosure;
[0031] FIG. 7B is a top, perspective view of the sled of FIG.
7A;
[0032] FIG. 7C is a perspective view showing the dynamic clamping
member disposed within the sled;
[0033] FIG. 8 is a side, perspective view of a pivot block which
mounts the tool assembly to a shaft of the surgical stapler to
permit articulation of the tool assembly relative to the shaft;
[0034] FIG. 9 is a side, perspective view of an adapter for
mounting the pivot block to the shaft of the surgical stapler;
[0035] FIG. 10 is a side, perspective view of the dynamic clamping
member according to the present disclosure;
[0036] FIG. 11A is a front perspective view of a distal end of a
staple cartridge for use in accordance with the present
disclosure;
[0037] FIG. 11B is a side, cross sectional view of the tool
assembly shown in FIG. 1B and the cartridge assembly shown in FIG.
11A;
[0038] FIG. 11C is a bottom perspective view with parts separated
of the cartridge assembly of FIG. 11A;
[0039] FIG. 11D shows an enlarged view of the cooperative
relationship between the sled, the surgical fasteners and a
plurality of staple pushers which form part of the staple cartridge
of FIGS. 11A-11C;
[0040] FIG. 12 is a schematic illustration of a pulley-like drive
system for advancing the sled through the tissue;
[0041] FIG. 13 is a side cross sectional schematic view showing one
possible actuating mechanism for actuating a clamp to compress and
cut tissue;
[0042] FIG. 14 is a perspective view of an alternate dynamic
clamping member design according to the present disclosure.
DETAILED DESCRIPTION
[0043] FIG. 1A shows a surgical stapler, generally designated 1,
for use in various open, endoscopic or laparoscopic surgical
procedures. Stapler 1 includes a housing 3 having distal and
proximal ends 4 and 6, respectively, an elongated shaft 20 mounted
to housing 3, preferably to its distal end 4, and a handle assembly
generally designated 5. Shaft 20 has a distal end 20a to which is
operatively attached by attachment mechanism 20b to a disposable
loading unit 10. As also shown in FIG. 1B, disposable loading unit
(DLU) 10 is comprised of a tool assembly 100 and a shaft connector
portion 20c which are pivotally and operatively attached to each
other through connector mechanism C. Shaft connector portion 20c is
removably operatively attached to proximal end 24 of distal end 20a
of shaft 20.
[0044] It is within the scope of this disclosure that tool assembly
100 may be pivotally, operatively, integrally attached, for
example, through a connection mechanism such as C permanently and
directly to distal end 20a of shaft 20 of a disposable surgical
stapler. As is known, a used or spent disposable loading unit 10
can be removed from shaft 20 of a reusable or reposable open,
endoscopic or laparoscopic surgical stapler, and replaced with an
unused disposable unit. It is contemplated that shaft 20 with or
without an integral or removably attached disposable loading unit
can be selectively removable from housing 3.
[0045] Shaft connector portion 20 includes a proximal end 24 and a
distal end 22. As mentioned above, the proximal end 24 is can be
permanently or removably associated with a handle or other
actuating assemblies of a manually (or other, e.g., robotic or
computer) operated open or endoscopic surgical stapler 1 (or
system--not shown). Distal end 22 of shaft connector portion 20 is
operatively connected to tool assembly 100. Tool assembly 100, in
general, includes a cartridge channel assembly 120, an anvil
assembly 110 and a staple cartridge assembly 200. Tool assembly 100
also includes an actuator, preferably a dynamic clamping member
150, a sled 160, as well as staple pushers 228 and staples 350 once
an unspent or unused cartridge 200 is in or mounted in channel
assembly 120.
[0046] In the drawings and in the descriptions which follow, the
term "proximal", as is traditional, will refer for example to the
end of tool assembly 100 which is closer to the user, while the
term "distal" will refer to the end which is further from the
user.
[0047] Shaft connector portion 20c is preferably cylindrical and
defines an internal channel 25 at the distal end 22 thereof and
which is dimensioned to receive a tube adapter or adapter 40 which
will be described in more detail with respect to FIG. 9 below.
Shaft connector portion 20c also receives or houses actuators for
actuating tool assembly 100. As best shown in FIGS. 1A, 1B, 2 and
9, tool assembly 100 mounts to distal end 22 of shaft connector 20c
(or the distal end 20a of shaft 20). Commonly owned U.S.
application Ser. No. 60/479,379 includes one possible design of a
stapler with a tool assembly mounted thereto, the entire contents
of this application being incorporated by reference herein.
[0048] More particularly, tool assembly 100 is mounted onto tube
adapter 40 which includes an outer cylindrical surface 47 that is
slidingly received in friction-fit engagement and attached to
internal housing 25 of shaft connector 20c (or, again, to shaft
20). Herein, the description of the proximal connection or
attachment of tool assembly 100 to shaft connector 20c also applies
to its connection to shaft 20. Preferably, the outer surface 47 of
the tube adapter 40 includes at least one mechanical interface,
e.g., a cutout or notch 45, which mates with a corresponding
mechanical interface, e.g., a radially inwardly extending
protrusion or detent (not shown), disposed on the inner periphery
of internal housing 25 to lock the tube adapter 40 to the shaft
connector 20c. As a result, rotation of shaft 20 about an "X" axis
defined with respect to tool assembly 100 (See FIG. 3)
correspondingly rotates tool assembly 100 in the same
direction.
[0049] As best shown in FIGS. 1B, 3, 4, 8 and 9, the distal end of
tube adapter 40 includes a pair of opposing flanges 42a and 42b
which define a cavity 41 for pivotably receiving a pivot block 50
therein. More particularly, each flange 42a and 42b includes an
aperture 44a and 44b (FIG. 8) defined therein which receives pivot
pin 57 (FIG. 4) also received in apertures 52a, 52b of pivot block
50 to allow pivotable movement of pivot block 50 about a "Z" axis
defined as perpendicular to longitudinal axis "X" of tool assembly
100 (See FIGS. 3 and 8).
[0050] As explained in more detail below in the description of the
channel assembly 120, the proximal end of each upwardly extending
flange 121a and 121b of the channel assembly 120 includes a pair of
apertures 122a and 122b disposed therethrough which are dimensioned
to receive a pivot pin 59 (FIG. 6A). In turn, pivot pin 59 mounts
through apertures 53a, 53b of pivot block 50 to permit rotation of
the tool assembly 100 about the "Y" axis as needed during a given
surgical procedure (FIGS. 3 and 8).
[0051] An actuator or a plurality of actuators (not shown)
preferably pass through shaft connector portion 20c, tube adapter
40 and pivot block 50 and operably connect to tool assembly 100 to
permit the surgeon to articulate tool assembly 100 about the "Y"
and "Z" axes as needed during a surgical procedure. In addition,
shaft 20 of surgical stapler 1 is rotatable 3600 by the rotation of
knob "K". As a result, tool assembly 100 is articulatable at least
90 degrees in all directions. Various actuators, hand assemblies
and pivot blocks are envisioned which can be utilized to accomplish
this task some of which are identified in commonly-owned U.S. Pat.
Nos. 6,250,532 and 6,330,965 and U.S. Provisional Application Ser.
No. 60/479,379 filed on Jun. 17, 2003 entitled "Surgical Stapling
Device, the entire contents of all of which are hereby incorporated
by reference herein.
[0052] As best seen in FIGS. 1B and 2 and as mentioned above, tool
assembly 100 includes anvil assembly 110 and channel assembly 120.
Channel assembly 120 supports staple cartridge assembly 200, an
actuator, e.g., a dynamic clamping member 150, and a sled 160. As
such, these various assemblies and their respective internal
components, when assembled, cooperate to allow the tool assembly to
manipulate, grasp, clamp, fasten and, preferably, sever tissue 400
during a given surgical procedure as explained below.
[0053] Generally, the top and bottom halves of a portion of tool
assembly 100 are defined by anvil assembly 110 and cartridge
channel assembly 120. Staple cartridge assembly 200 mounts within
channel assembly 120 and includes an upper tissue contacting or
facing surface 231 which opposes a tissue contacting or facing
bottom anvil surface 114b of anvil assembly 110. As best seen in
FIG. 1B, anvil assembly 110 and channel assembly 120 (and, thus,
when mounted, staple cartridge assembly 200) are pivotably coupled
near the proximal end of tool assembly 100 to allow anvil assembly
110 to pivot with respect to channel assembly 120 (and staple
cartridge assembly 200). More particularly, anvil assembly 110 and
channel assembly 120 are pivotably coupled with respect to one
another by two mechanical elements, namely, upwardly extending
flanges 121a and 121b of channel assembly 120 and pre-clamping
collar 140.
[0054] More particularly, the proximal end of each sidewall or
upwardly extending flange 121a and 121b of channel assembly 120
includes a cut out, e.g., cul de sac 123a, 123b, which are
configured to pivotably receive a pair of corresponding protrusions
or detents 119a (not shown) and 119b which extend laterally from
the proximal end of the anvil assembly 110. This allows the anvil
assembly 110 to pivot with respect to the channel assembly 120.
[0055] Pre-clamping collar 140 is designed to encompass and clamp
or preferably pre-clamp the channel assembly 120 and the anvil
assembly 110 together in an approximated and clamp position prior
to tissue fastening. As can be appreciated, by moving pre-clamping
collar 140 distally the user can actuate/move the anvil assembly
110 from an open, first position toward channel assembly 120 to
approximate the jaws, i.e., the anvil 110 and cartridge 200, to a
second, closed position to grasp tissue 400 therebetween. The sled
160 can be actuated by the user to staple and subsequently incise
the tissue 400. The details of sled 160, dynamic clamping member
150 and the staple cartridge assembly 200 are described in further
detail below. Pre-clamp is understood to mean that damping collar
140 approximates and damps the anvil and cartridge assemblies from
or at the proximal end portions before stapling and before dynamic
damping member 150 (or 150'') subsequently progressively clamps the
anvil and cartridge assemblies in the area of stapling and
preferably cutting tissue as the dynamic damping member translates
through the tool assembly 100.
[0056] As best seen in FIGS. 7A, 7C, 11B and 11D, sled 160 includes
a pair of upwardly-extending cam wedges 161a and 161b (See FIG. 7A)
which, when actuated to move by the user, cam a series of surgical
fasteners 500 or staples (See FIG. 11D) into and through the tissue
400 (FIG. 11B) and against staple forming pockets 111 of anvil
assembly 110 to deform the fasteners 350 and fasten tissue 400
therewith. Dynamic damping member 150 is associated with, e.g.,
mounted on and rides on, or with or is connected to or integral
with and/or rides behind sled 160. It is envisioned that dynamic
damping member 150 can have cam wedges or cam surfaces attached or
integrally formed or be pushed by a leading distal surface
thereof.
[0057] As shown, dynamic clamping member 150 is disposed or seated
in sled 160 behind upwardly-extending wedges 161a and 161b such
after the surgical fasteners 500 are fired and formed against anvil
bottom surface 114b, the dynamic clamping member 150 severs tissue
400 between the two rows of fasteners 500. Details of the various
above-mentioned subassemblies and components of the tool assembly
100 and the inter-cooperating features among all the same are
described in more detail below with respect to the corresponding
figure drawings.
[0058] As shown in FIGS. 1B, 2, 4, 5, 6A and 11B, anvil assembly
110 preferably is elongated and includes a proximal end 116, a
distal end 118 and top and bottom surfaces 114a and 114b,
respectively. As explained above, a pair of rocker pins 119a (not
shown) and 119b are disposed near proximal end 116 and are designed
for pivotable engagement with corresponding pair of cutouts 123a
and 123b defined within the sidewalls 121a, 121b near the proximal
end of the channel assembly 120. It is contemplated that actuation
by conventional means (e.g., activated remotely; e.g., by a handle
assembly 5 (FIG. 1A)) will cause clamping collar 140 to move in a
distal direction and engage forward cam surface 115 of anvil
assembly 110. This will cause the anvil assembly 110 to pivot from
an open first position wherein the anvil assembly 110 and the
channel assembly 120 are disposed in spaced relation relative to
one another to a second closed position wherein anvil assembly 110
and staple cartridge assembly 120 cooperate to grasp tissue 400
therebetween, i.e., pre-clamp the tissue between tissue engaging
surface 114b of anvil and opposing tissue engaging surface 231 of
staple cartridge assembly 200.
[0059] More particularly, it is envisioned that the initial
grasping or pre-clamping of tissue essentially squeezes or forces
fluids laterally and axially from the tissue 400 thus reducing the
likelihood of the staples being hydraulically displaced during
staple deformation. Movement of clamping collar 140 proximally over
proximal cam surface 117 will pivot anvil assembly 110 about pins
119a, 119b to open the anvil assembly 110 relative to the staple
cartridge assembly 200. In accordance with this disclosure the
grasping, i.e., clamping of tissue by clamping collar 140 is
referred to as pre-clamping the tissue, i.e., before the dynamic
clamping member subsequently clamps, preferably, further damps or
compresses, tissue.
[0060] Preferably, anvil assembly 110 is made from a suitable heavy
gauge material such as, e.g., 301 surgical stainless steel (or
other high-strength and durable material) to resist the forces of
staple ejection and formation against the anvil bottom surface 114b
and especially at the distal end portion of the anvil assembly 110,
and to resist the forces associated with tissue expansion an/or
fluid flow within the tissue during pre-clamping damping collar 140
and subsequently damping by dynamic damping member 150, 150'' as
well as during the fastening and cutting processes. The use of the
heavy gauge material for the anvil assembly 110 allows aperture 154
and camming pin 159 of the presently disclosed dynamic clamping
member 150 to be advantageously positioned in substantial vertical
registration with bottom flange 152 of damping assembly 150.
[0061] As shown in FIG. 14, the heavy gauge material of the anvil
assembly 110 allows an improved different dynamic damping member
150'' (or dynamic damping member 150 of FIG. 10) to be utilized.
The design of dynamic damping member 150'' greatly reduces any
tendency of the clamping assembly 150 buckling due to opposing
compressive and tensile forces since as shown in FIG. 14, there is
only tensile stress along line "S" due to the bottom flange 152''
and the upper camming pin 159 (See FIG. 10) in aperture 154'' being
disposed in substantial vertical registration relative to one
another.
[0062] As a result and as best illustrated by FIGS. 4 and 11B,
during distal translation of the dynamic damping member 150 or
150'' through tissue 400, the combination of the heavy gauge
material of the anvil assembly 110 and the substantially vertical
alignment of the flange 152, knife edge 155 and camming pin 159
disposed in aperture 154 operate to further proximate (i.e.,
further clamp) the opposing tissue engaging surfaces (i.e., anvil
bottom surface 114b and upper facing surface 231 of staple
cartridge assembly 200) at a moving point which is distal to the
leading edge 155 of the knife 155a. The further damping of the
tissue distally relative to the translating dynamic clamping member
150 acts to maintain a maximum acceptable gap between the opposing
surface 114b and 231 and forces fluid from the tissue 400 which
enhances stapling and reduces the likelihood of hydraulically
displacing the staples 500 during deformation.
[0063] It is also envisioned that utilization of a heavy gauge
material for both anvil assembly 110 and pre-clamping collar 140
will also provide an enhanced clamping pressure along the length of
tissue 400 and help to provide a uniform gap between the respective
approximated anvil assembly 110 and cartridge 200 prior to firing
the stapler and translating the sled 160 and dynamic damping member
150 through the tissue 400. Moreover, utilizing pre-clamping collar
140 to pre-damp tissue 400 prior to deformation of the staples 500,
also tends to force some tissue fluid distally and axially
outwardly which again reduces the likelihood of hydraulically
displacing staples 500 during deformation to fasten tissue 400.
[0064] After tissue 400 is fastened and severed (as explained in
more detail below with respect to the operation of the dynamic
clamping member 150), the operator can release pre-clamping collar
140 through re-activation or reverse activation of the damping
actuator (not shown). As explained above, the operator actuates the
clamping actuator to move the pre-damping collar 140 proximally
against rear cam surface 117 which, in turn, forces anvil assembly
110 to pivot to an open position about rocker pins 119a and
119b.
[0065] As best shown in FIG. 5, anvil assembly 110 includes an
elongated cross or T-shaped channel or slot generally designated
112 having a depending central portion or leg 112a and a transverse
upper portion 112b. Slot 112 preferably extends longitudinally from
proximal end 113 of upper portion 114a of the anvil assembly 110 to
the distal end 118 thereof. Leg 112a starts from or enters
proximate end 113 of anvil assembly 110 and extends to distal end
118 and upper transverse portion 112b starts proximate cam 115 and
extends to distal end 118. Preferably, upper portion 112b is
dimensioned to slidingly receive transverse pin 159 that extends
within aperture 154 in upper portion 157 of central support or
extension 157 of dynamic damping member 150 (see FIG. 10). Pin 159
is dimensioned to slidingly lock the upper portion 157 of dynamic
clamping member 150 within the T-shaped channel 112 such that the
dynamic clamping member 150 is longitudinally-recipricable within
slot 112.
[0066] As mentioned above, the pin 159 and channel 112 arrangement
of the dynamic damping member 150 in the anvil assembly 110 and the
arrangement of the bottom flange through slot 126 in channel
assembly 120 (FIG. 6B) assures that dynamic damping member 150 and
its knife blade travel between the surgical fasteners 500 along an
ideal transverse and vertical cutting plane through the tissue 400.
That is, the pin 159--slot 112 and flange 152--slot 126
arrangements prevent the dynamic damping member 150 from skewing,
i.e., laterally displacing the anvil assembly 110 relative to
staple cartridge assembly 200 (either vertically ("Z" axis") or
transversely ("Y" axis)) during the fastening and severing
processes. Moreover and as explained above, these arrangements also
counteract the clamping forces associated with compression of
tissue in the gap between anvil assembly 110 and cartridge assembly
120 and the ejection and deformation of the staples 500 to keep the
anvil assembly 110 and the staple cartridge assembly 200 in
substantially uniform and close relation relative to one another
during the progressive, sequential deformation of staples 500 and
incision of the tissue 400 as dynamic clamping member 150 moves
from the proximal to distal ends of the anvil assembly 110, channel
assembly 120 or cartridge assembly 200.
[0067] As best shown in FIGS. 6A, 6B, 11A and 11B, channel assembly
120 is dimensioned to house staple cartridge assembly 200 therein.
More particularly, channel assembly 120 includes a bottom surface
128 having upwardly extending side walls or flanges 121a and 121b
which define elongated support channel 125 which, in turn, is
dimensioned to mountingly receive staple cartridge assembly 200
therein. Channel assembly 120 also includes a plurality of
mechanical interfaces, here apertures 127a, 127b, 127c and 127d,
which matingly receive a corresponding plurality of mechanical
interfaces, here, protrusions 235a, 235b, 235c and 235d, disposed
in the outer-facing surfaces of staple cartridge assembly 200
(FIGS. 2 and 11C).
[0068] Staple cartridge assembly 200 can be assembled and mounted
within channel assembly 120 during the manufacturing or assembly
process and sold as part of overall tool assembly 100, or staple
cartridge assembly 200 may be designed for selective mounting to
channel assembly 120 as needed and sold separately, e.g., as a
single use replacement, replaceable or disposable staple cartridge
assembly 200. Preferably, staple cartridge assembly 200 is
manufactured to include sled 160 and dynamic clamping member 150.
Alternatively and as discussed below with respect to FIG. 15,
dynamic clamping member 150 with a knife may be sold as part of the
replaceable staple cartridge assembly 200 without a knife blade
155a (but preferably with a knife blade 155a to enhance and/or
insure accurate cutting of tissue 400 after staple deformation.
Tool assembly 100 may also be sold as a kit that includes a variety
of staple cartridges 200 containing surgical fasteners 500 of
different sizes, and/or arranged to be ejected in different
patterns, any of which may be selectively-coupled to the channel
assembly 120 as desired for use during a particular operation.
[0069] The proximal end of each upwardly extending flange 121a and
121b of the channel assembly 120 includes the aforementioned cul de
sacs 123a, 123b which allow pins 119a and 119b of anvil assembly
110 to pivot therein, and apertures 122a and 122b which are
dimensioned to receive pivot pin 59. When assembled, pivot pin 59
also passes through apertures 53a, 53b of pivot block 50 along the
"Y" axis. Rotation of the pivot block 50 about the "Y" axis
correspondingly rotates tool assembly 100 about the "Y" axis.
Rotation of pivot block 50 about pin 57 along "Z" axis rotates tool
assembly 100 about the "Z" axis.
[0070] As best shown in FIG. 6B, bottom surface 128 of channel
assembly 120 also includes an elongated longitudinal slot 126 which
includes and communicates at its proximal end with a cut out or
notch 129. Notch 129 is dimensioned to allow bottom flange 152 of
dynamic clamping member 150 to pass therethrough. The narrower
portion of slot 126 is dimensioned to slidingly receive and allow
upward support or extension 151 to pass therethrough. More
particularly and as also shown in FIGS. 7A and 7B, bottom flange
152 of dynamic clamping member 150 is passed through opening or
channel 164 through cut out or notch 167 in the base of sled 160,
and through notch 129 in bottom wall 128 of channel assembly 120.
When bottom flange 152 of dynamic clamping member 150 is extended
below the surface of bottom wall 128 of channel 120, dynamic
clamping member 150 is moved distally so that bottom flange 152
slidingly engages the underside of bottom wall 128 adjacent slot
126 and upward extension 151 engages in channel 164. As can be
appreciated, this slidingly locks bottom flange 152 of the dynamic
damping member 150 and sled 160 within the channel assembly
120.
[0071] Bottom flange 152 of dynamic damping member 150 in
cooperation with the pin 159 and slot 112 arrangement of dynamic
damping member 150 and anvil assembly 110, slidingly secure the
dynamic clamping member 150 within opposing slots 126 and 112 and
prevents unintentional displacement of anvil assembly 110 relative
to staple cartridge assembly 200 (either vertically ("Z" axis") or
transversely ("Y" axis)) during the clamping, fastening and
severing procedures. As mentioned above, the heavy gauge material
of the anvil assembly 110 also reduces unintentional displacement
of the dynamic damping member 150 during distal translation
thereof. Thus, in addition to severing tissue 400, dynamic damping
member 150 of the present disclosure also acts to oppose the forces
associated with compression of tissue, deformation of the surgical
fasteners 500 and severing of tissue 400.
[0072] As mentioned above, bottom surface 128 of channel assembly
120 acts as a carrier to define elongated support channel 125 for
receiving the staple cartridge assembly 200. With respect to the
staple cartridge assembly 200, corresponding tabs 235a, 235b, 235c,
235d formed along staple cartridge assembly 200 and elongated
support channel 125 function to retain staple cartridge assembly
200 within support channel 125 (See FIG. 11C). Staple cartridge
assembly 200 also includes offset retention slots 225 for receiving
a plurality of fasteners 500 and staple pushers 228 therein. A
series of spaced-apart longitudinal slots 230 extend through staple
cartridge assembly 200 to accommodate a pair of upwardly extending,
bifurcated cam wedges 161a, 161b of sled 160. As best shown in FIG.
11A, a centrally-located, longitudinal slot 282 extends
substantially along the length of staple cartridge assembly 200 to
facilitate passage of upward extension 151 of dynamic damping
member 150 therethrough. When deformed using the embodiment shown,
the surgical fasteners 500 form two sets of three staple rows 232a
and 232b, one set to each side of slot 282.
[0073] When tool member 100 is assembled, sled 160 is slidingly
positioned between the staple cartridge assembly 200 and the
channel assembly 120 (See FIG. 3). Sled 160 and the inner-working
components of staple cartridge assembly 200 detailed above
operatively cooperate to deform staples 500. More particularly,
sled 160 includes upwardly extending, bifurcated cam wedges 161a
and 161b which engage and cooperate with a series of staple pushers
228 to drive staples 350 through slots 225 from cartridge assembly
200 and deform against staple forming pockets 11 of anvil assembly
100.
[0074] During operation of the surgical stapler 10, sled 160
translates preferably distally through longitudinal slots 230 of
staple cartridge assembly 200 to advance cam wedges 161a and 161b
into sequential contact with pushers 228, to cam and cause pushers
228 to translate vertically within retention slots 225 and urge
fasteners 500 from retention slots 225 against fastener forming
pockets 111 in bottom facing surface 114b of anvil assembly 110
(See FIG. 4). One such type of staple forming pocket or cavity 111
is shown and described in commonly owned U.S. Pat. No. 6,330,965
the entire contents of which are hereby incorporated by reference
herein.
[0075] As mentioned above, dynamic clamping member 150 is mounted
on and preferably rides atop, on or in sled 160 (FIGS. 7A and 7B).
In the embodiment shown, when assembled, the lower portion of
upward extension 151 of dynamic clamping member 150 is generally
positioned in slot 164 defined in sled 160 axially between the
proximally facing edge 166a of spacer 166 and the distally facing
edge 162b and upwardly extending proximal edge 162a of a rear
flange 162.
[0076] Dynamic clamping member 150 is secured to sled 160 through a
slot 167 that extends through the base of sled 160. More
particularly, the base of upward extension 151 of dynamic clamping
member 150 is securely disposed with the second slot 167 which
extends through the bottom of sled 160 and is defined by proximally
facing or trailing edge 166b of a spacer 166 and the distal edge
162b of flange 162. Specifically, the leading edge 153a (FIG. 10)
of upper extension 151 abuts against the trailing edge of spacer
166b and the trailing edge 153b (FIG. 10) of upper extension 151
abuts against distal edge 162b of flange 162 to axially secure
dynamic clamping member 150 to and axially in sled 160.
[0077] Leading edge 166a of the spacer 166 rides within and along
slot 282 of staple cartridge assembly 200 to positively guide the
sled 160 along an ideal stapling and cutting path preferably
centrally and axially through the tissue 400. Thus, upon distal
movement of sled 160 to eject surgical fasteners 500, dynamic
clamping member 150, securely disposed within sled 160, travels
along slot 282 of staple cartridge assembly 200 and sequentially
severs tissue 400 between the two rows 232a and 232b of formed
fasteners 500 (See FIG. 11A). As explained in more detail below
with respect to FIGS. 12 and 13, the distal end of sled 160 may
includes apertures 169a and 169b to receive a suitable elongated
flexible member, e.g., a cable 900, which upon movement thereof
advances sled 160 to form surgical fasteners 500 and sever tissue
400.
[0078] As best shown in FIG. 10, dynamic clamping member 150
includes an upper portion 157 having a transverse aperture 154 with
a pin 159 mountable or mounted therein, a central support or upward
extension 151 and substantially T-shaped bottom flange 152 which,
as described above, mutually cooperate to slidingly retain dynamic
clamping member 150 along an ideal cutting path during
longitudinal, distal movement of sled 160. The leading cutting edge
155, here, knife blade 155a, is dimensioned to ride within slot 282
of staple cartridge assembly 200 and separate tissue 400 once
stapled. It is envisioned that leading edge 155 of the dynamic
clamping member 150 may be serrated, beveled or notched to
facilitate tissue cutting. More particularly, it is contemplated
that the combination of the enhanced closure force as a result of
the heavy gauge material of the anvil assembly 110 together with
the above described uniquely designed or positioned dynamic
clamping member 150 (or dynamic clamping member 150'' of FIG. 14)
permits accurate cutting of tissue 400 when leading edge 155 is
advanced through tissue 400. It is also understood that the upper
camming member need not be a pin but can be any integral or
removable suitable outwardly protruding cam surface(s). The same
applies to bottom flange 152 which can be any suitable camming
surface, including a pin or a removable pin, a button to facilitate
mounting of the dynamic clamping member into the sled 160 or
channel assembly 120.
[0079] It is also envisioned that the strength of the over and
under camming configuration of dynamic clamping member 150 in
combination with the increased strength of anvil assembly 110
(i.e., made from a heavy gauge surgical stainless steel) also
prevents dynamic damping member 150 from cutting vertically offline
or buckling and eliminates the need to cantilever dynamic clamping
member 150 as it moves through tissue 400. In other words, by
preferably utilizing a heavy gauge material for the anvil assembly
110 (and possibly the channel assembly 120) and utilizing
substantially aligned upper and lower slidingly engaging surfaces
of the dynamic clamping member 150 (here, pin 159 and bottom flange
152) to ride between the anvil assembly 110 and the channel
assembly 120 in substantial vertical registration, the normal
forces associated with stapling and cutting tissue 400 are
sufficiently opposed thus maintaining a consistent maximum and
substantially uniform gap in the stapling and cutting area between
the opposing tissue contacting surfaces (i.e., staple cartridge
surface 231 and bottom anvil surface 114b) during the stapling and
cutting processes. Moreover, the provision of the heavy gauge
material for the anvil assembly 110 and the arrangement of the pin
159 and bottom flange 152 also operate to further proximate or
further clamp the tissue at a point distal to the dynamic damping
member 150 which forces fluid from the tissue 400 to further
enhance the stapling and cutting processes. It is envisioned that
alternative upper and lower sliding camming surfaces may be
employed to accomplish a similar purpose, e.g., plates, rails, ball
bearing etc.
[0080] From the foregoing and with reference to the various figure
drawings, those skilled in the art will appreciate that certain
modifications can also be made to the present disclosure without
departing from the scope of the present disclosure. For example,
the above-described tool assembly 100 may be part of or
incorporated into a disposable loading unit (DLU) such as disclosed
in U.S. Pat. No. 6,330,965 or attached directly to the distal end
of any known surgical stapling device. A handle assembly for
actuating the approximation member(s) can be selected from a
variety of actuating mechanisms including toggles, rotatable and
slideable knobs, pivotable levers or triggers, and any combination
thereof. The use of the above-described tool assembly 100 as part
of a robotic system is also envisioned.
[0081] It is also envisioned that many different actuators may be
employed to advance the sled 160 through the tissue 400. For
example, it is envisioned that the tool assembly 100 (or one of the
sub-assemblies associated therewith, i.e., channel assembly 120 or
staple cartridge assembly 200 or anvil assembly 110) may include
one or more pulleys to advance the sled 160 through the tissue 400
to staple and cut the same.
[0082] For example, as shown in FIG. 12A, a pair of cables, ropes,
threads or bands or belts 700a, 700b may be fed distally through
cartridge assembly 200 or channel assembly 120 through or around
respective pins, capstans, or pulleys 600a, 600b, and pass
proximally toward and attach to sled 160. Alternatively and as
shown in FIG. 128, a single belt can replace belts 700a and 700b
and can be passed through apertures 169a and 169b at the distal end
of sled 160, or passed into a gap 163 and around behind a pin 610
which is mounted through apertures 169a and 169b.
[0083] One or more pins 610 may be disposed within sled 160 such
that a proximal force "F" on the corresponding bands 700a and 700b
advances the sled 160 distally to eject and form staples 500
against anvil assembly 110 and cut tissue 400. It is envisioned
that the band or belts may be made from a high strength material
sold under the trademark Kevlar.RTM. or other man-made fibers or
materials available for generalized use in the industrial arts and
suitable for this intended surgical use. As can be appreciated,
utilizing a dual pin or pulley system as schematically shown in
FIG. 12 maintains the balance of the proximally-actuated forces "F"
on either side of staple cartridge assembly 200 as sled 160 moves
through tissue 400. As also can be appreciated, this assures
uniform and consistent stapling and cutting of tissue 400 by
dynamic clamping member 150.
[0084] FIG. 13 shows one possible suitable actuating system to
actuate pre-clamping collar 140 to force anvil assembly 110 to
close relative to staple cartridge assembly 200. More particularly,
a cable 900 may be utilized to move pre-clamping collar 140
distally onto and over cam surface 115 to close the anvil 110
relative to the staple cartridge assembly 200 and compress the
tissue 400. Preferably, cable 900 attaches to the pre-clamping
collar 140 at or near point 149 and is fed through a passageway in
anvil assembly 110 (or under a proximal portion of anvil assembly
110) and fed proximally through shaft 20. Actuating of cable 900 in
the direction "C" forces pre-damping collar 140 distally against
cam surface 115 to close anvil assembly 110 relative to staple
cartridge assembly 200. A return mechanism, e.g., a spring, cable
system or the like (not shown), may be employed to return
pre-clamping collar 140 to a pre-clamping orientation which
re-opens anvil assembly 110.
[0085] FIG. 14 shows an alternate embodiment of a dynamic damping
collar 150'' which includes an upper portion 157'' having a
transverse aperture 154 within which pin 159 is mountable or
mounted therein, upward extension 151 and substantially T-shaped
bottom flange 152'' which, as similarly described above with
respect to FIG. 10, mutually cooperate to slidingly retain dynamic
damping member 150'' along an ideal cutting path during
longitudinal, distal movement of sled 160. The leading cutting edge
155'' of knife blade 155a'' is dimensioned to ride within slot 282
of staple cartridge assembly 200 and separate tissue 400 once
stapled.
[0086] It is envisioned that the combination of the enhanced
closure force as a result of the heavy gauge material of the anvil
assembly 110 together with uniquely designed dynamic clamping
member 150'' permits accurate cutting of tissue 400 when leading
edge 155'' is advanced through tissue 400. It is also contemplated
that the strength of the over and under camming configuration of
dynamic clamping member 150'' in combination with the increased
strength of anvil assembly 110 (i.e., made from a heavy gauge
surgical stainless steel) also prevents dynamic damping member
150'' from cutting vertically offline or buckling and eliminates
the need to cantilever dynamic clamping member 150'' as it moves
through tissue 400. In other words, by preferably utilizing a heavy
gauge material for the anvil assembly 110 substantially aligning
upper and lower slidingly engaging surfaces in vertical
registration, dynamic clamping member 150'' rides between the anvil
assembly 110 and the channel assembly 120 in substantial vertical
registration and the forces associated with stapling and cutting
tissue 400 are sufficiently opposed thus maintaining a consistent
maximum and substantially uniform gap in the stapling and cutting
area between the opposing tissue contacting surfaces 231 and 114b
during the stapling and cutting processes.
[0087] The dynamic clamping member 150, 150'' of this disclosure is
an improvement over known clamping members. Since the upper and
lower camming surfaces are substantially opposed, i.e.,
substantially vertically aligned, the forces to which it is
subjected during its operation are substantially only tensile
forces. Consequently, the design of the dynamic clamping member 150
renders it significantly strong and significantly resistant to
buckling. Accordingly, the cutting edge 155 is unlikely to buckle.
Further, since the cutting edge 155 for cutting tissue is also
substantially aligned with the upper and lower camming surfaces 159
and 152, the dosing force of the dynamic damping member 150 is
imparted closer to and preferably more aligned with the cutting
edge. This enhances the cutting action of the cutting edge.
[0088] The preferred use of a damping collar 140 to pre-damp, i.e.,
initially approximate the anvil assembly 110 and cartridge assembly
200, in combination with the use of a dynamic clamping member 150
to subsequently clamp, preferably further damp, i.e., further
proximate, the anvil 110 and cartridge 200 assemblies, provides
several advantages. It enhances tissue stabilization and
compression. During pre-clamping and approximation, clamping collar
140 squeezes, i.e., pre-squeezes tissue, between and distally along
the respective tissue contracting or facing surfaces of the anvil
assembly 110 and cartridge assembly 120. During subsequent,
preferably further clamping and proximation with the dynamic
damping member 150, there is believed to be less fluid and fluid
flow in the tissue in the area of further damping. This enhances
obtaining a uniform tissue gap and better staple formation along
the tool assembly 100. With less fluid flow in the area of and
during stapling, staple legs more accurately hit their staple
pockets 111 in the anvil 110 forming surface. The advantages
pre-damping and subsequent clamping are further enhanced by use of
stronger heavier gauge anvil assembly 110, for example because
there is less of a tendency for distal end of anvil assembly 110 to
bow outwardly away from cartridge assembly 200. Also, the squeezing
effect on the tissue during pre-clamping and clamping is more
pronounced, increasingly so from the mid to distal end of the anvil
assembly 110. Consequently, tissue fluid is forced further distally
out to and past the distal end of the anvil assembly 110 and tool
assembly 100. This reduces fluid flow in the area of and during
stapling with the dynamic damping member 150. In addition to the
benefits explained above, this reduces the need to cantilever the
camming force out ahead of the clamping member 150, and allows the
upper camming surface here, pin 159, to be effectively disposed in
substantially vertical alignment meaning at least some portion of
the upper and lower camming surfaces 159, 152 are vertically
aligned. Thus, the most preferred arrangement and procedure is to
have a clamping collar 140 for pre-clamping, a dynamic clamping
member 150 for further clamping, and each being effected on a
strong, or, preferably, very strong anvil assembly 110.
[0089] The present disclosure also relates to a method of stapling
tissue and includes the steps of providing a stapler having a tool
assembly at a distal end thereof, the tool assembly including a
channel assembly for supporting a staple cartridge which carries a
plurality of staples and an anvil dimensioned having, e.g., shaped
pockets to deform the plurality of staples ejected from the staple
cartridge thereagainst. The tool assembly also includes a sled
which is movable from a first position to a subsequent position to
force the plurality of staples from the staple cartridge through
tissue and against the anvil, and a dynamic clamping member which
moves with the sled. The dynamic damping member includes a first
mechanical interface which slidingly engages the anvil and a second
mechanical interface which slidingly engages the channel assembly.
The first and second mechanical interfaces of the dynamic clamping
member are in substantial vertical registration relative to one
another to oppose the expansive forces associated with clamping,
stapling, and if a knife is engaged on the dynamic clamping member,
cutting tissue.
[0090] The method according to the present invention also includes
the steps of: approximating and grasping tissue between the
opposing surfaces of the anvil and the staple cartridge; clamping
the anvil and staple cartridge in position about the tissue; and
firing the stapler to advance the sled and the dynamic clamping
member distally to eject the staples from the staple cartridge to
deform against the anvil to fasten the tissue and to subsequently
cut the tissue along a predetermined cutting path. The firing step
can employ the substantially over and under dynamic clamping member
to further proximate the opposing surfaces of the anvil assembly
and the staple cartridge at progressively moving points which are
distal to the knife during translation of the dynamic damping
member.
[0091] Although the subject surgical stapler and various assemblies
associated therewith have been described with respect to preferred
embodiments, it will be readily apparent to those having ordinary
skill in the art to which it appertains that changes and
modifications may be made thereto without departing from the spirit
or scope of the subject devices. While several embodiments of the
disclosure have been shown in the drawings and described herein, it
is not intended that the disclosure be limited thereto, as it is
intended that the disclosure be as broad in scope as the art will
allow and that the specification be read likewise. Therefore, the
above description should not be construed as limiting, but merely
as exemplifications of preferred embodiments. Those skilled in the
art will envision other modifications within the scope and spirit
of the claims appended hereto.
* * * * *