Title of Invention

AN INJECTION PORT FOR SUBCUTANEOUS PLACEMENT WITHIN A BODY

Abstract The invention relates to an injection port (30,50,60,80) for subcutaneous placement within a body comprising: an elongated flexible substantially non-rigid body (30) having first and second ends (34,36) and a wall (32) therebetween, said wall (32) is such that it will self seal after being punctured, said body comprising a fluid reservoir (48) surrounded by said wall (32); and a flexible elongated tubular catheter (42) attached to said body (30) which is in fluid communication with said reservoir (48). The said body (30) having a length between said ends (34,36) of 5mm to 20mm, and an outer diameter of 5mm to 12mm, and in that an adjustable gastric band connected to the tube (42).
Full Text Field of the Invention
This invention relates generally to the field of medicine, and more specifically to
medical devices. More particularly, the invention relates to an injection port for
subcutaneous placement within a body.
Background of the invention
Surgeons routinely implant subcutaneous injection ports in patients requiring
long term, periodic fluid injections such as for chemotherapy and gastric band
adjustments. The injection port connects to a flexible tube catheter to transport
the fluid to the affected area (subclavian vein, etc.) or the gastric band. Current
injection ports comprise a rigid metal or plastic housing, which is about 25mm in
diameter and 15mm tall. A thick, silicone septum captured within the rigid
housing covers an inner chamber that fluidly communicates with the catheter.
The surgeon uses a hypodermic needle to inject fluid into the chamber through
the silicone septum.
Typically the surgeon fastens the injection port with suture to fascia and beneath
the fat and skin layers, primarily to prevent the port from flipping over, but also
to prevent the injection port from migrating in the body. Since the septum is
accessible from only one side of the injection port, flipping over requires
interventional surgery to right the port for subsequent injections.


For some patients, the surgeon may place the injection port in the lower
abdomen, thus burying the port beneath a fat layer that may be several
centimeters thick. Usually a surgeon can locate the port with palpation alone.
However, if there is a very thick, intervening fat layer, such as on extremely
obese, gastric band patients, the surgeon must also use fluoroscopy, ultrasound,
or other means to locate the port. Furthermore, the surgeon must inject the
needle in a direction approximately perpendicular to the injection port, and hit
the target area of the septum, which is only about 12-15mm in diameter. For
some patients, the

surgeon may place the injection port on the sternum or upper right chest, just
beneath the skin layers. Although easy to locate with palpation, some patients
regard the protruding port as uncomfortable or cosmetically objectionable.
What is needed, therefore, is a subcutaneously implantable injection port that is
made of relatively soft and flexible materials, and ideally, that looks and feels
more (than current injection ports) like a large, natural blood vessel. What is also
needed is a subcutaneously implantable injection port that is penetrable with a
hypodermic needle, independent of the orientation of the injection port in bodily
tissue, and that is self-sealing when the needle is removed. What is further
needed is a subcutaneously implantable injection port that a surgeon may
position in the body more quickly and with less dissection than is required for
conventional injection ports.
Summary of the Invention
Accordingly, there is provided An injection port for subcutaneous placement
within a body comprising: an elongated flexible substantially non-rigid body
having first and second ends and a wall therebetween, said wall is such that it
will self seal after being punctured, said body comprising a fluid reservoir


surrounded by said wall ; and a flexible elongated tubular catheter attached to
said body which is in fluid communication with said reservoir, characterized in
that said body having a length between said ends of 5mm to 20mm, and an
outer diameter of 5mm to 12mm, and in that an adjustable gastric band
connected to the tube .
The invention thus provides an injection port for subcutaneous placement within
a body. The injection port includes an elongated flexible substantially non-rigid
body having first and second ends and a wall therebetween. The wall is made
from one or more materials such that it will self seal after being punctured by a
needle. The body of the device further includes and a fluid reservoir surrounded
by the wall. Lastly, the injection port includes a flexible elongated tubular
catheter attached to the body which is in fluid communication with the reservoir.
Brief Description Of The Accompanying Drawings
We present the specific, novel features of this invention in the appended claims.
The reader may best understand, however, the organization and methods of
operation of this invention by referring to the detailed description and the
following drawings:
Fig. 1 is an isometric view of an injection port of the prior art;
Fig. 2 is a cross sectional view of the injection port of the prior art shown in Fig.
1;


FIG. 3 is an isometric view of a first embodiment of a flexible injection port 30;
FIG. 4 is a sectional view of flexible injection port 30 shown in FIG. 3;
FIG. 5 is an enlarged, longitudinal sectional view of flexible injection port 30 penetrated
by a hypodermic needle 100;
FIG. 6 is a cross sectional view of a second embodiment of a flexible injection port 50;
FIG. 7 is a cross sectional view of a third embodiment of a flexible injection port 60;
FIG. 8 is an isometric view of a fourth embodiment of a flexible injection port 80;
FIG. 9 is a cross sectional view of flexible injection port 80;
FIG. 10 shows injection port 30 subcutaneously implanted near a fascia layer 124 in a
patient;
FIG. 11 shows injection port 30 subcutaneously implanted near a skin layer 120 in a
patient; and
FIG. 12 shows injection port 30 subcutaneously implanted in a fat layer 122 in a patient.
Detailed Description of the Invention
Referring now to the drawings, FIGS. 1 and 2 show an injection port 10 of the prior art.
Injection port 10 generally has a truncated, conical configuration, and comprises a body
portion 12, a housing 14, a seal element 16, and a catheter element 18. The body portion 12
is made of a flexible, rubberized material with a cavity 20 formed inside. A catheter support
22 integrally forms in body portion 12. Housing 14 is made of a corrosion resistant metal,

and has a reduced, upwardly facing entry passage 24. Seal element 16 is made of a
rubberized material, which is easily penetrable by a hypodermic needle or the like, and
provides a penetrable seal for passage 24. Housing 14 and seal element 16 define an open
cavity 20 in injection port 10 for receiving and containing a fluid. Catheter element 18
extends through catheter support 22 of body portion 12 and through housing 14 so that
catheter element 18 extends into cavity 20 for providing communication between cavity 20
and the exterior of injection port 10 for dispensing fluid from the cavity 20 into the body of
a patient.
A surgeon implants injection port 10 subcutaneously in a patient. To introduce a fluid
such as a medication or a saline solution, the surgeon inserts a hypodermic needle or the like
into the patient so that the tip of the needle passes through seal element 16 and into cavity
20. Due to the relatively small size of passage 24, each time the surgeon introduces a fluid
into the patient, the surgeon must insert the needle through seal element 16 and the same
localized area of the skin and tissue of the patient. Accordingly, seal element 16 may
become significantly damaged and eventually develop a leak. Also, the localized skin area
and underlying tissue may not heal in the desired manner. Further, because housing 14 is
made of metal, it can cause barbing of the needle tip, causing increased trauma to the patient
upon withdrawal of the needle. Still further, because of the truncated conical configuration
of injection port 10 and the metallic construction of housing 14, injection port 10 can cause
substantial discomfort to a patient, particularly if the area of the patient adjacent the injection
port is accidentally bumped or bruised. In addition, because of the truncated conical
configuration of injection port 10, it can cause a relatively unattractive mound on the body
of a patient. Still further, since fluid can only be introduced in cavity 20 through passage 24,
a surgeon must insert a needle into injection port 10 in substantially perpendicular relation to
the skin so that often the adjacent area of tissue or skin of the patient cannot effectively
support the needle.
When using injection port 10 of the prior art in a laparoscopic procedure such as
implantation of a gastric band, it is necessary for the surgeon to assemble injection port 10 to
catheter element 18 during the laparoscopic procedure. This is because injection port 10 is
too large to pass through a standard size (12mm diameter) laparoscopic port, which is used
for access to the stomach inside the abdominal cavity. The surgeon must introduce the

gastric band and the catheter into the abdominal cavity without the injection port attached to
the free end of the catheter. Once the surgeon has secured the gastric band around the
stomach, the surgeon externalizes the free end of the catheter through the abdominal muscle
and fascia layers, subcutaneous fat layer, and the skin to assemble the injection port to the
free end of the catheter. Then the surgeon implants the injection port subcutaneously at the
desired location on the patient's abdomen or chest. The surgeon must take extra time to
assemble the injection port to the catheter. Also, the surgeon must skillfully connect the
injection port to the catheter during less than ideal conditions. Consequently, there is the
potential complication of an undiscovered leak developing at the connection of the catheter
to the port.
FIG. 3 is an isometric view of a first embodiment of the present invention showing a
flexible injection port or body 30, that generally comprises a first end 34, a second end 36,
and a cylindrical injection portion 32 extending there between. A surgeon may use a
hypodermic needle or the like to penetrate injection portion 32 and introduce a fluid such as
a medication or saline solution into flexible injection port 30. Injection portion 32 self-seals
when the surgeon removes the hypodermic needle. Injection portion 32 may have a length,
but is not limited to, approximately 5-20 cm. Injection portion 32 may have a diameter,
but is not limited to, approximately 5-12 mm. A catheter 42 attaches to first end 34 and
distributes fluid injected into flexible injection port 30 to another portion of the patient's
body. Catheter 42 is made from a silicone rubber or other biocompatible polymer such as
known in the art for application to conventional injection ports, such as shown in FIGs 1 and
2. A tether 38 having an eye loop 40 extends from second end 36. A surgeon may use a
conventional surgical grasping instrument to grasp tether 38, or a surgical suture tied to eye
loop 40, or a combination of both grasper and suture, to facilitate placement of flexible
injection port 30 in the body.
Although flexible injection port 30 is shown in FIG. 3 to be essentially straight, it is
possible to construct it with a curved or non-straight shape in order to facilitate placement in
the body, or to conform to the body anatomy at the implant location. Since flexible injection

port 30 is made of relatively soft and flexible materials, the surgeon may temporarily
straighten it, for example, when introducing it into the body through a laparoscopic port.
FIG. 4 is a cross sectional view of flexible injection port 30, taken at line 4-4 of injection
portion 32 as shown in FIG. 3. At this location and anywhere along the length of injection
portion 32, flexible injection port 30 includes an outer tube 44 may exerts a radial,
compressive force on an inner tube 46. Flexible injection port 30 includes a fluid reservoir
48 that extends the entire length of injection portion 32 and fluidly communicates with
catheter 42. The total wall thickness is approximately in the range of 2 - 4mm.
FIG. 5 is a longitudinal sectional view of flexible injection port 30, showing a
hypodermic needle 100 penetrating through injection portion 32 so that distal tip 102 of
hypodermic needle 100 is inside of fluid reservoir 48. First end 34, second end 36, tether
38, eye loop 40, and inner tube 46 are integrally molded from an elastomer such as, for
example, silicone rubber, latex rubber, or polyurethane rubber. The molded elastomer may
have a durometer approximately in the range of 40-60, but is not limited to that range.
Catheter 42 may be bonded inside of first end 34 using any one of a number of bonding
agents and techniques well known in the art, in order to fluidly communicate with reservoir
48. Outer tube 44 may be made of a PTFE shrink-wrap material, or a similar, biocompatible
shrink-wrap. During the manufacturing process, outer tube 44 may be loosely assembled in
the pre-shrunken configuration over inner tube 46. Then the application of heat causes outer
tube 44 to conform very tightly around inner tube 46. Outer tube 44 therefore applies a
significant compressive force on the softer, inner tube 46 to enhance the ability of inner tube
46 to close the puncture created by hypodermic needle 100.
FIG. 6 is a cross sectional view of a second embodiment of the present invention
showing a flexible injection port 50, which is externally similar to the first embodiment
shown in FIG. 3. Flexible injection port 50 includes an outer tube 52, an inner tube 54, and
an inner lining 56. Outer tube 52 and inner tube 54 are the same as outer tube 44 and inner
tube 46, respectively, of the first embodiment in FIG. 4. Inner lining 56 may be an extruded

plastic, thin wall tube, such as polyethylene or PTFE, tightly assembled inside of inner tube
54 to provide internal support to inner tube 54. By supporting inner tube 54 in this way, a
greater compressive force may be applied by outer tube 52 onto inner tube 54, to further
enhance the self-sealing capability. The material of inner lining 56 may be selected to have
a higher needle penetration resistance than inner tube 54. This difference in penetration
resistance provides the surgeon with tactile feedback that the needle tip has penetrated into
fluid reservoir 58. Inner lining 56 may also be constructed of a metallic mesh and be similar
in many respects to a vascular stent. Again, the total wall thickness is approximately in the
range of 2-4 mm.
FIG. 7 is a cross sectional view of a third embodiment of the present invention showing a
flexible injection port 60, which also is externally similar to the first embodiment shown in
FIG. 3. Flexible injection port 60 comprises a plurality of layers 61, which for this third
embodiment includes a first layer 62, a second layer 64, a third layer 66, a fourth layer 68,
and a fifth layer 70, which surrounds a fluid reservoir 72. . Once penetrated by a needle
that is inserted at an acute angle, the punctures created through the layers are not aligned to
allow leakage once the needle is removed. Each of layers 61 may be made of the same or a
different material than any of the other of layers 61, or may have the same or a different
thickness than any of the other of layers 61. Each of layers 61 may have a specific property
or functional contribution. For example, first layer 62 may be made of a material that is
permeable to tissue fluids in order to slowly release a medication contained in second layer
64. Fifth layer 70 may be made of silicone rubber having a durometer in the range of 20 -
30. Fourth layer 68 may be made of a heat shrinkable PTFE material, which applies a
radially compressive force on fifth layer 70 to enhance self-sealing. Third layer 66 may be
made of a material such as a metallic foil that acts as a diffusion barrier to prevent the loss of
fluid from fluid reservoir 72. Fourth layer 66 may be made of a high durometer silicone
rubber. Many other materials are possible, in a multiplicity of combinations, so that
injection port 60 may have characteristics especially suited for its particular application.
Diffusion of body fluids into and out of the soft port wall may also be reduced by any one of
various material treatment techniques, including, for example, vapor deposition of titanium
or another metal on a surface of the soft port, and coating with Paralene polymer. Other

coatings are also known in the art for micro bacterial protection. Again, the total wall
thickness is in the range of 2 - 4 mm.
FIG. 8 is a fourth embodiment of the present invention, a flexible injection port 80,
comprising a first end 84 that attaches to a catheter 92, a second end 86 and an injection
portion 82. Flexible injection port 80 further comprises a webbing 88 attached to and
covering at least injection portion 82, and made of a thin, flexible, implantable material such
as a polyester or polypropylene mesh, expanded PTFE, or the like. Webbing 88 provides
broad margins for stapling or suturing to an underlying tissue such as fascia, as well as a
large area for tissue in-growth, to enhance long-term stability and to substantially prevent
migration of flexible injection port 80. FIG. 9 is a cross sectional view of flexible injection
port 80, taken at line 9-9 of FIG. 8. Flexible injection port 80 comprises an outer tube 94
made of a heat shrinkable, PTFE material, and an inner tube 96 made of a silicone rubber
having a durometer of approximately 20-40. Webbing 88 includes a pair of webbing layers,
91 and 93, that may be bonded thermally or chemically tightly over at least injection portion
82 in the mid-plane of flexible injection port 80.
A surgeon may implant the present invention, as described for the preceding
embodiments and equivalents, in a number of locations in a patient's body. FIGs 10, 11,
and 12 show examples of flexible injection port 30 subcutaneously implanted in the
abdomen of a patient, although it is possible to implant flexible injection port 30 beneath the
skin in other portions of the body.
FIG. 10 depicts a first example of flexible injection port 30 subcutaneously implanted in
a patient's body. Flexible injection port 30 lies adjacent to a fascia layer 124 covering an
abdominal wall 126. Catheter 42 passes from the abdominal cavity 128 through an
abdominal opening 132, which the surgeon used together with a first incision 130 for
laparoscopic access earlier in the surgical procedure. The surgeon optionally may make a
second incision 134 offset from first incision 130, and use conventional, surgical grasping
and retracting instruments to pull flexible injection port 30 beneath a fat layer 122 and
adjacent to fascia layer 124. However, the surgeon may determine that it is not necessary to
make a second incision 134, and instead use first incision 130 to push flexible injection port
30 into position. In either situation, the surgeon dissects as little tissue as practical in order

to save surgery time and to minimize the size of enclosed cavities that may collect tissue
fluids and become sites for infection. The surgeon optionally may anchor flexible injection
port 30 to fascia layer 124 with a stay suture 102. Once the surgeon has placed flexible
injection port 30 in the desired location, the surgeon closes first incision 130 and second
incision 134 using conventional sutures or staples.
FIG. 11 shows a second example of flexible injection port 30 subcutaneously implanted
in a patient's body. Flexible injection port 30 lies immediately beneath skin layer 120 and
above fat layer 122. Catheter 42 passes through first incision 130 and abdominal opening
132 (the original laparoscopic port site) into abdominal cavity 128. The surgeon may use
finger or instrument dissection through first incision 130 to create a space under skin layer
120 for flexible injection port 30. The surgeon closes first incision 130 using conventional
sutures or staples. Normally it would not be necessary to close abdominal opening 132
through fascia layer 124 and abdominal wall 126, but the surgeon may do so in order to
promote healing and to prevent slippage of catheter 42 through abdominal opening 132.
The surgeon may prefer placement of flexible injection port 30 just beneath skin layer 120
for severely obese patients in which fat layer 122 is over 5-10 cm thick, so that the surgeon
may easily use palpation to locate flexible injection port 30 for later injections of fluid.
Also, conventional intravenous (IV) needles and techniques may be used for injecting the
fluid into flexible injection port 30, which is situated beneath the skin much like a natural
blood vessel. This may allow nurses and other clinicians who are trained in administering
IV's to assist the surgeon with fluid injections. Furthermore, if the clinician uses a
conventional IV needle, the "flashback" of fluid into the IV needle syringe tip provides the
clinician with visual feedback that the tip of the needle is properly penetrated into the
reservoir of flexible injection port 30. In fact, addition of a colorant to the fluid injected
further enhances this visual feedback. Non-toxic colorants that may be added to the saline
solution or medication are well known in the art.
FIG. 12 shows a third example of flexible injection port 30 subcutaneously implanted in
a patient's body. For this example, the surgeon does minimal or no dissection of tissue at
the laparoscopic port site. Catheter 42 passes from the abdominal cavity 128 through fascia
layer 124 and abdominal wall 126. The surgeon positions flexible injection port 30
vertically in fat layer 122 and beneath skin layer 120. Optionally, the surgeon may suture

abdominal opening 132 to prevent slippage of flexible injection port 30 into abdominal
cavity 128. The surgeon also may use a surgical scissors to trim off tether 38 from flexible
injection port 30, just prior to closing first incision 130 with conventional sutures or staples.
The present invention, a flexible injection port, as described in the preceding
embodiments and their equivalents, has numerous advantages over the prior art injection
ports. The flexible injection port may not require attachment to fascia, thus reducing the
duration of the surgical procedure. The flexible injection port may require a smaller incision
size and less tissue dissection for implantation, so that the patient has less pain, less scarring,
a faster recovery, and less possibility of infection. Due to the integral construction of the
flexible injection port and the catheter, the step of connecting the catheter to the injection
port during the surgical procedure is not necessary, thus potentially reducing the number of
surgical complications due to fluid leakage at the connection. Because the flexible injection
port may be implanted in the fat layer near the skin surface, the surgeon or a trained
clinician may use palpation to locate the injection port, and standard IV techniques to
administer fluid, yet the implant is still cosmetically acceptable to the patient. In addition,
shorter injection needles may be used to reduce patient anxiety during fluid administration.
The flexible injection port may have no metallic parts, resulting in a flexible and lightweight
implant for greater patient comfort and compatibility with magnetic resonance and
fluoroscopic x-ray imaging. Finally, the injection portion of the flexible injection port is
accessible with a hypodermic needle for most of the possible orientations of the flexible
injection port within the subcutaneous fat layer of the patient.
While preferred embodiments of the present invention have been shown and
described herein, it will be obvious to those skilled in the art that such embodiments are
provided by way of example only. Numerous variations, changes, and substitutions will
now occur to those skilled in the art without departing from the invention. For example,
the injection port may me coated with an anit-microbial coating such as triclosan. For
example, as would be apparent to those skilled in the art, the disclosures herein have
equal application in robotic-assisted surgery. In addition, it should be understood that
every structure described above has a function and such structure can be referred to as a
means for performing that function. Accordingly, it is intended that the invention be
limited only by the spirit and scope of the appended claims.

We Claim:
1. An injection port (30,50,60,80) for subcutaneous placement within a body
comprising:
a. an elongated flexible substantially non-rigid body (30) having first and
second ends (34,36) and a wall (32) therebetween, said wall (32) is such
that it will self seal after being punctured, said body comprising a fluid
reservoir (48) surrounded by said wall (32); and
b. a flexible elongated tubular catheter (42) attached to said body (30)
which is in fluid communication with said reservoir (48),
characterized in that said body (30) having a length between said ends
(34,36) of 5mm to 20mm, and an outer diameter of 5mm to 12mm, and in
that an adjustable gastric band connected to the tube (42).
2. The flexible injection port as claimed in claim 1 wherein said wall (32)
comprises an inner layer (46) and an outer layer (44), wherein said outer
layer (44) is in compression around said inner layer (46).

3. The flexible injection port as claimed in claim 2, wherein each of said inner
layer (46) and said outer layer (44) are made from a polymer material.
4. The flexible injection port as claimed in claim 2 wherein said outer layer
(44) is made of a heat shrinkable material, and said inner tube (46) is made
of an elastomer.
5. The flexible injection port as claimed in claim 1 wherein said wall (32)
comprises a layer (66) of fluid diffusion barrier material.
6. The flexible injection port as claimed in claim 1 comprising a webbing (88)
attached to and extending from an outer surface of said body (30).
7. The flexible injection port as claimed in claim 1, wherein said body (30) has
a diameter no greater than 12mm.
8. The flexible injection port as claimed in claim 1, wherein said wall (32)
comprises at least three layers (52,54,56) of material.

9. The flexible injection port as claimed in claim 8, wherein an innermost layer
(56) of material is made of a polymer having a higher puncture resistance
than the other of said at least three layers (52,54).
10.The flexible injection port as claimed in claim 10, wherein an innermost
layer (56) of material is made of a metallic mesh material and radially
supports said other layers (52,54).
11. An injection port for subcutaneous placement within a body comprising:
a. a tubular elongated flexible substantially non-rigid body having first and
second ends and a wall therebetween, substantially all of said wall is such
that it will self seal after being punctured, said body comprising a fluid
reservoir surrounded by said wall; and
b. a flexible elongated tubular catheter attached to said body which is in fluid
communication with said reservoir, and an adjustable gastric band
connected to the tube.


The invention relates to an injection port (30,50,60,80) for subcutaneous
placement within a body comprising: an elongated flexible substantially non-rigid
body (30) having first and second ends (34,36) and a wall (32) therebetween,
said wall (32) is such that it will self seal after being punctured, said body
comprising a fluid reservoir (48) surrounded by said wall (32); and a flexible
elongated tubular catheter (42) attached to said body (30) which is in fluid
communication with said reservoir (48). The said body (30) having a length
between said ends (34,36) of 5mm to 20mm, and an outer diameter of 5mm
to 12mm, and in that an adjustable gastric band connected to the tube (42).

Documents:

822-KOL-2004-ABSTRACT 1.1.pdf

822-kol-2004-abstract.pdf

822-KOL-2004-AMANDED CLAIMS.pdf

822-KOL-2004-AMANDED PAGES OF SPECIFICATION.pdf

822-kol-2004-assignment.pdf

822-kol-2004-claims.pdf

822-KOL-2004-CORRESPONDENCE 1.1.pdf

822-kol-2004-correspondence.pdf

822-KOL-2004-DESCRIPTION (COMPLETE) 1.1.pdf

822-kol-2004-description (complete).pdf

822-KOL-2004-DRAWINGS 1.1.pdf

822-kol-2004-drawings.pdf

822-KOL-2004-EXAMINATION REPORT REPLY RECIEVED.pdf

822-KOL-2004-EXAMINATION REPORT.pdf

822-KOL-2004-FORM 1 1.1.pdf

822-kol-2004-form 1.pdf

822-kol-2004-form 18.pdf

822-KOL-2004-FORM 2 1.1.pdf

822-kol-2004-form 2.pdf

822-kol-2004-form 26.pdf

822-KOL-2004-FORM 3.1.pdf

822-kol-2004-form 3.pdf

822-KOL-2004-FORM 5.1.pdf

822-kol-2004-form 5.pdf

822-KOL-2004-GRANTED-ABSTRACT.pdf

822-KOL-2004-GRANTED-CLAIMS.pdf

822-KOL-2004-GRANTED-DESCRIPTION (COMPLETE).pdf

822-KOL-2004-GRANTED-DRAWINGS.pdf

822-KOL-2004-GRANTED-FORM 1.pdf

822-KOL-2004-GRANTED-FORM 2.pdf

822-KOL-2004-GRANTED-SPECIFICATION.pdf

822-KOL-2004-OTHERS 1.1.pdf

822-KOL-2004-OTHERS.pdf

822-KOL-2004-PETITION UNDER RULE 137.pdf

822-KOL-2004-REPLY TO EXAMINATION REPORT.pdf

822-kol-2004-specification.pdf

822-kol-2004-translated copy of priority document.pdf


Patent Number 253057
Indian Patent Application Number 822/KOL/2004
PG Journal Number 25/2012
Publication Date 22-Jun-2012
Grant Date 20-Jun-2012
Date of Filing 15-Dec-2004
Name of Patentee ETHICON ENDO-SURGERY INC.
Applicant Address 4545 CREEK ROAD, CINCINNATI, OH 45242
Inventors:
# Inventor's Name Inventor's Address
1 HOW-LUN CHEN 4618 BELLEVIEW AVENUE, CINCINNATI, OHIO 45242
2 DALE R. SCHULZE 226 S. MECHANIC STREET, LEBANON, OHIO 45036
3 SEAN P. CONLON 6234C NORTH SHADOW HILL WAY, LOVELAND, OHIO 45140
PCT International Classification Number A61M 30/02
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/737942 2003-12-16 U.S.A.