U.S. patent application number 11/317284 was filed with the patent office on 2006-08-17 for implantable access port.
Invention is credited to Michael Fowler, David A. Smith.
Application Number | 20060184141 11/317284 |
Document ID | / |
Family ID | 26812073 |
Filed Date | 2006-08-17 |
United States Patent
Application |
20060184141 |
Kind Code |
A1 |
Smith; David A. ; et
al. |
August 17, 2006 |
Implantable access port
Abstract
An implantable access port for use in transferring a fluid
transdermally between an external fluid storage or dispensing
device and a site within a patient's body is disclosed. The access
port includes a base, a bowl-shaped reservoir defined within the
base by a smooth surfaced wall, and a septum secured to the base
and enclosing the reservoir within the base. The access port also
includes a reservoir outlet defined centrally within the reservoir.
The bowl-shaped reservoir is defined by a continuous
smooth-surfaced curvilinear wall. The reservoir may thus be sized
and shaped as a parabola, or may be hemispherical or
semi-hemispherical in cross-section. The reservoir outlet is
defined at a center point on the bottom of the reservoir wall, may
be partially or fully recessed within the bottom of the reservoir
wall, and is also defined in the base tangentially with respect to
the bottom of the reservoir wall. The access port also has an
outlet passageway defined within the base and extending in
communication with the reservoir outlet and an external opening
defined in the exterior of the base.
Inventors: |
Smith; David A.; (Ellerslie,
GA) ; Fowler; Michael; (Fayetteville, GA) |
Correspondence
Address: |
NEEDLE & ROSENBERG, P.C.
SUITE 1000
999 PEACHTREE STREET
ATLANTA
GA
30309-3915
US
|
Family ID: |
26812073 |
Appl. No.: |
11/317284 |
Filed: |
December 23, 2005 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
10114343 |
Apr 2, 2002 |
6997914 |
|
|
11317284 |
Dec 23, 2005 |
|
|
|
60281184 |
Apr 2, 2001 |
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Current U.S.
Class: |
604/288.02 |
Current CPC
Class: |
A61M 39/0208
20130101 |
Class at
Publication: |
604/288.02 |
International
Class: |
A61M 31/00 20060101
A61M031/00; A61M 37/00 20060101 A61M037/00 |
Claims
1. An implantable access port for use in transferring a fluid
transdermally between an external fluid storage or dispensing
device and a site within a patient's body, said access port
comprising: a base; a bowl-shaped reservoir defined within the base
by a smooth surfaced wall; a septum secured to the base and
enclosing the reservoir within the base; and a reservoir outlet
defined centrally within the reservoir.
2. The access port of claim 1, the reservoir being defined by a
single continuous wall.
3. The access port of claim 2, the reservoir being defined by a
curvilinear wall.
4. The access port of claim 1, wherein the reservoir is formed as a
parabola.
5. The access port of claim 4, the reservoir outlet being defined
at the focus of the parabola formed by the reservoir.
6. The access port of claim 1, the reservoir being hemispherical in
shape.
7. The access port of claim 1, the reservoir being
semi-hemispherical in shape.
8. The access port of claim 1, the reservoir outlet being at least
partially recessed within the reservoir wall.
9. The access port of claim 1, the reservoir outlet being fully
recessed within the reservoir wall.
10. The access port of claim 1, the reservoir outlet being defined
at the center of the reservoir wall.
11. The access port of claim 1, the reservoir outlet being defined
at a bottom portion of the reservoir wall spaced furthest from an
open-face formed by the reservoir wall within the base.
12. The access port of claim 11, the reservoir outlet being defined
at the center of the reservoir wall.
13. The access port of claim 11, the reservoir outlet being defined
in the base tangentially with respect to the bottom portion of the
reservoir wall.
14. The access port of claim 1, the reservoir outlet being defined
in the base tangentially with respect to a bottom portion of the
reservoir wall.
15. The access port of claim 1, further comprising an outlet
passageway defined within the base, the outlet passageway being in
communication with an external opening defined in the exterior of
the base and the reservoir outlet.
16. The access port of claim 15, the external base opening being
constructed and arranged to be placed in sealed fluid communication
with a catheter.
17. The access port of claim 1, wherein the base of the access port
is comprised of a biocompatible material.
18. The access port of claim 1, wherein the septum of the access
port is comprised of an elastomeric material.
19. An implantable access port for use in transferring a fluid
transdermally between an external fluid storage or dispensing
device and a site within a patient's body, said access port
comprising: a base; a bowl-shaped reservoir defined within the base
by a single continuous smooth-surfaced wall; and a reservoir outlet
defined within the reservoir wall.
20. The access port of claim 19, further comprising a septum
secured to the base and enclosing the reservoir within the
base.
21. The access port of claim 19, the reservoir outlet being defined
at a bottom portion of the reservoir wall spaced furthest from an
open-face formed by the reservoir wall within the base.
22. The access port of claim 21, the reservoir outlet being defined
at the bottom center of the reservoir wall.
23. The access port of claim 21, the reservoir outlet being defined
in the base of the access port tangentially with respect to the
bottom of the reservoir wall.
24. The access port of claim 19, wherein the reservoir wall defines
a parabola.
25. The access port of claim 24, the reservoir outlet being defined
at the focus of the parabola.
26. The access port of claim 19, wherein the reservoir wall
comprises a curvilinear wall.
27. The access port of claim 19, the reservoir being hemispherical
in shape.
28. The access port of claim 19, the reservoir being
semi-hemispherical in shape.
29. An implantable access port for use in transferring a fluid
transdermally between an external fluid storage or dispensing
device and a site within a patient's body, said access port
comprising: a base; a reservoir defined within the base, the
reservoir having an open face, an opposed bottom, and a center
point on the bottom; and a reservoir outlet opening defined in the
bottom of the reservoir.
30. The access port of claim 29, further comprising a septum
secured to the base and enclosing the open face of the reservoir on
the base.
31. The access port of claim 29, the reservoir outlet being defined
in the center of the reservoir bottom.
32. The access port of claim 29, wherein the reservoir outlet is
defined in the base tangentially with respect to the bottom of the
reservoir.
33. The access port of claim 29, wherein the reservoir is
bowl-shaped.
34. The access port of claim 33, wherein the reservoir is defined
by a continuous wall.
35. The access port of claim 34, wherein the reservoir wall further
comprises a smooth surfaced wall.
36. The access port of claim 35, wherein the reservoir wall further
comprises a curvilinear wall.
Description
[0001] This application is a continuation of, and claims priority
to and the benefit of, U.S. patent application Ser. No. 10/114,343,
entitled "Implantable Access Port," filed on Apr. 2, 2002, which is
incorporated in its entirety in this document by reference.
FIELD OF THE INVENTION
[0002] The invention relates in general to medical devices. More
particularly, the invention relates to an implantable access port
for use in accessing either the vasculature or a selected treatment
site within the body of a patient.
BACKGROUND OF THE INVENTION
[0003] The use of implantable access ports in the art of drug
therapy is well known, in which an access port is implanted beneath
the subcutaneous layers of a patient's skin. The known access ports
are constructed to provide for repeated access to the vascular
system of a patient, or a selected treatment site within the
patient's body. The use of these devices reduces the trauma
otherwise associated with multiple punctures of the skin, or the
inconvenience of an externalized catheter for patient treatment
purposes. For example, implantable access ports are used to
facilitate frequent blood sampling, or to provide for the delivery
of medications, nutritions, blood products, and imaging solutions
into the patient's blood stream, or to a desired treatment site
within the patient. Access to the implanted device/port is
typically accomplished by percutaneous needle insertion through the
patient's skin into the access port through a penetrable septum or
other similar structure by using a non-coring hypodermic
needle.
[0004] Implantable access ports are supplied as sterile devices,
are provided for single patient use only, and are available in a
variety of port materials, including polysoufone, acetal plastic
and titanium Available catheter materials include polyurethane and
silicone. Suture holes are typically formed in the access port as a
part of the base portion thereof and are used to facilitate the
anchorage of the access port to the patient's underlying fascia,
for example muscle. Implantable access ports are available in
single, dual, and low profile models, and are available with
attachable, or attached catheters.
[0005] A major problem with implanted vascular access systems, and
in particular access ports, is the occlusion of the system by
coagulated blood or other material between uses. As known,
occlusion occurrences can lead to patient complications such as
systemic infection, pocket infection, extravasation of medications,
and port failure, all of which may lead to an explant of the
device. Further, most patients that receive implantable access
ports are either immune compromised, or are in danger of becoming
immune compromised. These complications can therefore have a
serious effect on the patient. As known, there are clinical steps
that can be taken to prevent this occurrence, such as flushing and
infusion of the access port with a saline solution. The growth of
such occlusive substances, however, occurs through time and appears
to occur at a much higher rate in access ports with edges and gaps
present in the flow path.
[0006] For example, one well known type of access port has a
cylindrical reservoir formed within the base of the access port, an
example of which is disclosed in U.S. Pat. No. 5,041,098 to
Loiterman et al. Although access ports with cylindrical reservoirs
have proven to be quite successful and gained wide acceptance and
usage as described above, problems do exist with this type of
construction. Namely, there are angular corners or junctions formed
where the respective side walls of the reservoir join the bottom
and top walls, respectively, forming the reservoir, and the outlet
passageway is typically defined with the side wall of the reservoir
such that it is spaced from (above) the bottom wall or surface of
the reservoir. So defined, the outlet/outlet passageway forms a
small ledge or catch pocket in the reservoir which may lead to the
occlusion of blood or other substances passed into or drawn from
out of the access port.
[0007] Additionally, access ports with cylindrical reservoirs
typically enclose a large amount of space which results in a large
volume of fluid that must flow into the access port during use, and
which fluid remains in the port thereafter. This extra fluid also
reduces the efficiency of flushing protocols by requiring larger
flows of fluid over extended times to completely flush the
reservoir after use. This is further compounded by the positioning
of the outlet passageway at a central location within the reservoir
side wall such that a gap exists between the bottom of the
reservoir and the entrance to the outlet passageway.
[0008] What is needed, therefore, is an implantable access device
with an improved reservoir configuration which will further reduce
the occurrence of occlusion by improving upon the technology of
reservoir designs. Moreover, there is a need for such an improved
reservoir design coupled with a more efficient means of draining
fluids and other materials from the reservoir of the access port
during and after the usage of the port.
SUMMARY OF THE INVENTION
[0009] The present invention is an implantable access device for
allowing repeated access to, and for use in transferring a fluid
transdermally between an external fluid storage or dispensing
device and a site, space, device, or other object, fluid, tissue or
region within the body of a patient, and which access port
overcomes some of the design deficiencies of the known access
ports.
[0010] In a first embodiment the access port comprises a base, a
bowl-shaped reservoir defined within the base by a smooth surfaced
wall, a septum secured to the base and enclosing the reservoir
therein, and a reservoir outlet defined centrally within the
reservoir. The reservoir is defined by a continuous wall, which may
further comprise a curvilinear wall. So fashioned, the reservoir
may be formed as a parabola with the reservoir outlet defined at
the focus of the parabola/reservoir. The reservoir, as desired, may
also be hemispherical or semi-hemispherical in shape.
[0011] The reservoir outlet is at least partially recessed within
the reservoir wall, and may be fully recessed in the reservoir wall
and access port base. The reservoir outlet is preferably defined in
the bottom of the reservoir wall and at the center thereof, the
bottom of the reservoir wall being that portion of the reservoir
spaced furthest from an open-face formed by the reservoir/reservoir
wall within the base. The access port also includes an outlet
passageway defined within the base, the outlet passageway being in
communication with the reservoir outlet and extending to, and in
communication with an external opening defined in the exterior of
the base. The external base opening is further constructed and
arranged to be placed in sealed fluid communication with a catheter
of known construction, as desired.
[0012] In a second embodiment, the access port of the invention
comprises a base, a bowl-shaped reservoir defined within the base
by a continuous smooth-surfaced wall, and a reservoir outlet
defined within the reservoir wall. This embodiment of the access
port also includes a septum secured to the base and enclosing the
reservoir within the base. The reservoir outlet is defined within
the base in the bottom portion of the reservoir wall and is
preferably at the bottom center of the reservoir wall.
[0013] In yet another embodiment, the access port comprises a base,
a reservoir defined within the base, the reservoir having an open
face and an opposed bottom, and a reservoir outlet opening defined
in the bottom of the reservoir. Once again, the access port may
also include a septum secured to the base and enclosing the open
face of the reservoir on the base. The reservoir outlet is defined
within the base at the center of the reservoir bottom, and is also
defined in the base tangentially with respect to the bottom of the
reservoir. If desired, the reservoir of the access port may be
bowl-shaped, as described above, and thus may be formed by a smooth
surfaced wall, which wall may also be a curvilinear wall.
[0014] In each of the embodiments of the invention, the reservoir
may thus be formed to have a parabolic, hemispherical, or
semi-hemispherical shape in cross-section. With the reservoir
outlet formed in or at the center of the bowl-shaped reservoir, the
smooth flow of material from the reservoir into the outlet and out
of the access port is enhanced. Moreover, by positioning the
reservoir outlet within the center of the reservoir, essentially
the bottom of the continuous reservoir wall, there is no unusable
flow space in which the buildup of occluding substances, for
example drugs, aspirated blood, and the like, can occur.
[0015] Additionally, the design of the reservoir outlet and the
reservoir shape and size assure for a more effective reservoir
cleansing when the port is flushed with a solution, for example an
aqueous saline solution, between uses. The implantable access
device of this invention can be thus used for the introduction of
therapeutic agents, for the infusion of withdrawal of fluids, or
for the introduction of sensing, sampling, or treatment devices to
another implanted device, or to body regions within the
patient.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016] FIG. 1 is a top plan view of a known type of implantable
access device having a cylindrical reservoir.
[0017] FIG. 2 is a side cross-sectional view along line 2-2 of FIG.
1.
[0018] FIG. 3 is side elevational view of a first embodiment of the
implantable access device of this invention having a bowl-shaped
reservoir provided as a part thereof.
[0019] FIG. 4 is an elevational view, in cross section, of the
access port of FIG. 3.
[0020] FIG. 5 is a front, side perspective view of the access port
of FIG. 3.
[0021] FIG. 6 is a perspective view, in cross section, of the
access port of FIG. 3.
[0022] FIG. 7 is a perspective view of a second embodiment of the
implantable access device of this invention having a bowl-shaped
reservoir.
[0023] FIG. 8 is top plan view of the implantable access device of
FIG. 7 FIG. 9 is side cross-sectional view along line 9-9 of FIG.
8.
DETAILED DESCRIPTION
[0024] Referring now in detail to the drawings, in which like
reference numerals indicate like parts or elements throughout the
several views, a known type of an implantable access port 5 is
illustrated in FIGS. 1 and 2. The known access port is comprised of
a base 7 having a radially spaced series of suture holes 8 defined
within the base. So provided, the access port may be sewn to the
fascia of a patient by passing appropriate sutures through the
suture holes to fasten the access port to the underlying muscle
and/or tissues of the patient.
[0025] As best shown in FIGS. 1 and 2, the access port 5 here
features a cylindrical reservoir 9 formed within and as a part of,
the base. An outlet passageway 10 extends radially away from the
side wall of the reservoir to an opening 11 defined within the
exterior side wall of the base, the outlet passageway being in
fluid communication with the reservoir and the exterior opening.
Absent in FIGS. 1 and 2 is a penetrable septum of a type known in
the art, which septum would be affixed to the open face of the base
by a suitable retainer ring (not illustrated).
[0026] As shown in FIG. 2, there are a number of angular corners or
junctions formed where the respective side walls of the reservoir
join the bottom and top walls or surfaces, respectively, forming
the cylindrical reservoir. The outlet passageway 10 extends from an
opening defined in the side wall of the reservoir such that both
the outlet opening and the outlet passageway are spaced from
(above) the bottom of the reservoir. So defined, the outlet opening
forms a small ledge or catch pocket in the reservoir, which may in
turn lead to the occlusion of blood or other substances,
respectively, in the reservoir as these fluids are passed into or
drawn from out of the access port.
[0027] Also, cylindrical reservoirs of the type shown in FIGS. 1
and 2 typically enclose a large amount of space, which results in a
large volume of fluid that must flow into the access port during
use, and which fluid remains in the port thereafter. This extra
fluid reduces the efficiency of flushing protocols by requiring
larger flows of fluid over extended times to completely flush the
reservoir after use. As described, this is further compounded by
the positioning of the outlet step, i.e., the outlet opening and
the outlet passageway 10, at a central location within the
upstanding reservoir side wall, such that a gap exists between the
bottom of the reservoir and the entrance to the outlet
passageway.
[0028] A first embodiment of the implantable access port of this
invention is illustrated in FIGS. 3 through 6. An implantable
access port 25 is illustrated having a base 27 provided with a
series of radially spaced suture holes 28, in known fashion. Here,
however, in contrast to the known types of access ports, the access
port 25 is formed to have a bowl-shaped reservoir 29, as best seen
in FIGS. 4 and 6. The bowl-shaped reservoir is defined by a single
smooth-surfaced wall which defines an open top of the reservoir,
and a focus or center point at the "bottom" or center of the
reservoir. The wall of the reservoir thus comprises a continuous
curvilinear side wall.
[0029] The bowl-shaped reservoir, in all of the embodiments of the
present invention, may thus be parabolic in shape, as well as
hemispherical or semi-hemispherical when viewed in cross-section.
The bowl-shaped formation of the reservoir in the base of the
access port in such a manner thus allows for the reservoir to be
made with the walls and the floor of the reservoir as one unit,
i.e., one continuous wall, without otherwise forming any corners or
edges associated with the reservoir at which a buildup of occluding
particles could occur.
[0030] Still referring to FIGS. 4 and 6, a reservoir outlet 30 is
defined within the base of the access port at the center or focus
of the bottom of the reservoir. The bottom of the reservoir, as
such, is that portion which is opposed to the open face of the
reservoir defined in the base. The bottom of the reservoir thus
comprises the center or the focus of the reservoir, as that term is
understood by those skilled in the art. An outlet passageway 31 is
also defined within the base and extends in communication with the
reservoir outlet 30 and an external opening 32 defined in the
exterior side wall of the access port base.
[0031] The placement of the reservoir outlet at the focus or center
of the bowl-shaped reservoir enhances the smooth flow of material,
i.e., fluids, to include medications and blood, into and out of the
reservoir. The reservoir outlet 30 is shown in FIGS. 4 and 6 to be
partially recessed, i.e., partially defined or formed within the
floor of the reservoir, and is positioned directly in the center of
the reservoir so that the outlet, which may also be thought of as a
reservoir stem, acts like a drain to remove fluid and particles
from the reservoir. Also, and a shown, the reservoir outlet is
defined within the base of the access port so that the reservoir
outlet is preferably tangential with respect to the reservoir wall,
and particularly with respect to the bottom portion thereof.
[0032] The bowl-shaped reservoir thus encloses the minimal amount
of space required to allow a hypodermic needle (not illustrated) to
access the reservoir through the septum (not illustrated) of the
access port. The septum will comprise a penetrable septum of those
types well known in the art, and will be secured to the base over
the open face of the reservoir by a suitable retainer ring 34 which
will be threadably affixed to the base of the access port. The
bowl-shaped reservoir of this access port, with its improved
reservoir design, thus reduces the likelihood of occlusion
occurrences and failures within the access port, and is believed to
minimize the likelihood of the above-described patient
complications.
[0033] Accordingly, as taught herein, the volume of the bowl-shaped
reservoir is greatly reduced with respect to access ports having
cylindrical access ports, which thus enhances the efficiency of
flushing protocols used with the port. For example, it is
anticipated that the volume of the bowl-shaped reservoir 29, 129 in
FIGS. 3-9, respectively, may be around 0.3 cc's whereas the
cylindrical reservoir 9 of the access port 5 (FIGS. 1-2) known in
the art may have a volume of approximately 0.6 to 1.0 cc's.
[0034] A second embodiment of the implantable access port of this
invention is illustrated in FIGS. 7 through 9. The implantable
access port 125 of FIGS. 7-9 includes a base 127 having a radially
spaced series of suture holes 128 defined therein, as known. The
suture holes may be filled with a penetrable material, for example
an elastomeric material, for otherwise filling the openings within
the base in order to limit tissue in-growth into the suture holes
or openings.
[0035] Still referring to FIGS. 7-9, the access port 125 has a
bowl-shaped reservoir 129 defined within and as a part of the base
of the access port. As with the reservoir 29 of FIGS. 3-6, the
bowl-shaped reservoir 129 is once again defined by a continuous
smooth-surfaced wall, for example a curvilinear wall, which defines
an open top of the reservoir and an opposed bottom having a focus
or center point thereat, the bottom or bottom portion of the
reservoir once again being that portion of the reservoir opposed to
and spaced farthest from the open top or face thereof. The
reservoir may thus be parabolic, hemispherical, or
semi-hemispherical in shape (cross-section). So fashioned, the
reservoir does not provide any corners or associated edges at which
a buildup of occluding particles or substances could occur.
[0036] A reservoir outlet 130 is defined within the base at the
bottom of the bowl-shaped reservoir, and more particularly at the
center thereof, and is in communication with an elongate outlet
passageway 131 defined within the base and extending in
communication with the reservoir outlet to an external opening 132
defined within the exterior side wall of the base. As illustrated,
the outlet opening may best be thought of as an outlet stem
extending from the center or focus of the bowl-shaped reservoir.
Unlike the outlet opening defined in the embodiment of the access
port illustrated in FIGS. 3-6, which is partially recessed within
the bottom surface of the reservoir wall (FIG. 4), here the
reservoir outlet 130 is fully recessed in the base with respect to
the bottom, center of the reservoir, as best shown in FIGS. 8 and 9
for forming a more discrete reservoir drain.
[0037] Referring to FIG. 9, the access port 125 is provided with a
penetrable septum 133 of known construction, the septum being
secured on the base of the access port by a retainer ring 134
threadably affixed to the base. The manner of fabrication, and
materials used in the construction of the implantable access ports
25 and 125 of this invention, respectively, are as described in
U.S. Pat. Nos. 4,673,394, and 5,951,512, each of which is assigned
to Horizon Medical Products, Inc. of Manchester, Ga., and each of
which is fully incorporated herein by this reference.
[0038] As such, the penetrable septums of the preferred embodiments
of this invention are comprised of a self-resealing polymer, which
is preferably an elastomer, such as silicon rubber or a latex, and
which is adapted to permit access using a hypodermic needle (not
illustrated) into the reservoir formed within the respective access
ports. The respective bases 27, and 127, and the retainer rings 34,
134, are each preferably comprised of a biocompatible material,
such as electropolished stainless steel, or other surgical grades
of steel, to also include a biocompatible hard material such as
titanium. Additionally, the access port, with the exception of the
septum, can be manufactured of a suitable plastic material intended
for implantation within a human body, and approved for use
therefor. Also, the base of the access port, in association with
the external opening defined in the side wall of the base, for all
embodiments of the inventive access port, are provided with a
catheter mount of known construction, which for example, may
comprise the locking type of catheter mount illustrated in the '394
patent to Fenton et al., the teaching of which has been
incorporated herein by reference.
[0039] The bowl-shaped reservoir allows for an entirely smooth
geometry in the reservoir in that the reservoir wall does not have
any corners or edges that may catch materials or substances which
might otherwise settle on or occlude at least a portion of the
reservoir or reservoir outlet. The placement of the respective
outlets 30, 130, at the bottom or center of the reservoir,
preferably tangentially with respect thereto as illustrated in FIG.
9, and either partially or fully recessed in the base with respect
to the reservoir bottom, further prevents the formation of any
"dead space" which would otherwise allow the buildup of particles
which may lead to occlusion of the access port. The bowl-shaped
reservoir of this access port, therefore, with its improved
reservoir design, reduces the likelihood of these types of
occlusion occurrences and failures, and is believed to minimize the
likelihood of the above-described patient complications.
[0040] Although several embodiments of the invention have been
disclosed in the foregoing specification, it is understood by those
skilled in the art that many modifications and other embodiments of
the invention will come to mind to which the invention pertains,
having the benefit of the teaching presented in the foregoing
description and associated drawings. It is thus understood that the
invention is not limited to the specific embodiments disclosed
hereinabove, and that many modifications and other embodiments are
intended to be included within the scope of the invention.
Moreover, although specific terms are employed herein, they are
used only in a generic and descriptive sense, and not for the
purposes of limiting the described invention.
* * * * *