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Claims  |
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We claim:
1. A balloon catheter assembly, comprising:
an expandable balloon having an opening in a proximal end portion thereof
and including a marker made of an X-ray opaque substance;
an inner tube having a distal end portion which is removably inserted in
said opening of said balloon;
an intermediate tube coaxially surrounding said inner tube with a space
therebetween;
a chuck at a distal end of said intermediate tube, said chuck comprising a
plurality of expandable and contractible holding portions; and
an outer tube surrounding said intermediate tube with a space therebetween;
said chuck being closed when pulled into said outer tube and pressed by
said distal end of said outer tube to thereby hold said proximal end
portion of said balloon, and said chuck being opened when pushed out of
said distal end of said outer tube, to thereby release said proximal end
portion of said balloon.
2. The balloon catheter assembly according to claim 1, wherein:
said intermediate tube and said outer tube have proximal ends connected to
respective check valves;
said intermediate tube extends outward from said outer tube via said check
valve connected to said outer tube; and
said inner tube extends outward from said intermediate tube via said check
valve connected to said intermediate tube, such that a body fluid is
prevented from flowing reversely when said distal portion of said catheter
is inserted in a body.
3. The balloon catheter assembly according to claim 2, further comprising
infusion ports connected to said check valves which are connected to said
intermediate tube and said outer tube, respectively.
4. The balloon catheter assembly according to claim 1, characterized in
that said inner tube has a proximal end connected to a balloon expanding
infusion port.
5. The balloon catheter assembly according to claim 1, wherein said inner
tube, said intermediate tube and said outer tube are molded from a resin
selected from the group consisting of polyethylene, polypropylene,
ethylene-vinylacetate copolymer, polyester, polyvinylchloride,
polyurethane, fluoric resin and polyamide.
6. The balloon catheter assembly according to claim 1, further comprising a
balloon expanding filler made of material which assumes a liquid state
when said filler is infused into said balloon and a gelled state at a
predetermined time after said filler has been infused into said balloon.
7. The balloon catheter assembly according to claim 6, wherein said filler
is mixed with an X-ray opaque substance.
8. The balloon catheter assembly according to claim 1, wherein said balloon
is molded from at least one material selected from the group consisting of
silicone rubber, polyurethane and latex.
9. The balloon catheter assembly according to claim 1, wherein said balloon
has a circular middle portion which is thick such that said balloon takes
a bottle-gourd shape when expanded.
10. The balloon catheter assembly according to claim 8, wherein said
balloon includes a mesh molded from at least one material selected from
the group consisting of nylon, polyethylene terephthalate and
polyurethane, said mesh being buried therein so as to restrict the
expansion degree of said balloon.
11. A balloon catheter assembly comprising:
an expandable balloon having an opening in a proximal end portion, said
proximal end portion having an outer peripheral surface;
an inner tube having a distal portion removably inserted in said opening of
said balloon;
a chuck at said distal portion of said inner tube, said chuck surrounding
said distal portion of said inner tube, and said chuck having a plurality
of holding portions extending radially outwardly at distal ends thereof;
and
an outer tube coaxially surrounding said inner tube with a space
therebetween, said outer tube having a distal end, said chuck being
adapted to be closed when said inner tube is pulled in said outer tube by
pushing said holding portions inwardly by said distal end of said outer
tube to hold said proximal portion of said balloon on said outer
peripheral surface thereof, and adapted to release said proximal portion
of said balloon when projected from said distal end of said outer tube to
be disengaged therefrom.
12. The balloon catheter assembly according to claim 11, wherein:
said outer tube has a proximal end connected to a check valve; and
said inner tube extends outward from said outer tube through said check
valve, such that a body fluid is prevented from flowing reversely when
said distal portion of said catheter is inserted in a body.
13. The balloon catheter assembly according to claim 11 further comprising
an infusion portion connected to said outer tube.
14. The balloon catheter assembly according to claim 11 ,wherein said inner
tube has a proximal end connected to an infusion port for injecting into
said balloon a filler for expanding said balloon.
15. The balloon catheter assembly according to claim 11, wherein said inner
tube and said are molded from a resin selected from the group consisting
of polyethylene, polypropylene, ethylene-vinyl acetate copolymer,
polyester, polyvinylchloride, fluoric resin and polyamide.
16. The balloon catheter assembly according to claim 11, further comprising
a balloon expanding filler made of material which assumes a liquid state
when said filler is infused into said balloon and a gelled state at a
predetermined time after said filler has been fused into said balloon.
17. The balloon catheter assembly according to claim 11, wherein said
filler is mixed with an X-ray opaque substance.
18. The Balloon catheter assembly according to claim 11, wherein said
balloon is molded from at least one material selected from the group
consisting of silicone rubber, polyurethane and latex.
19. The balloon catheter assembly according to claim 11, wherein said
balloon has a circular middle portion which is thick such that said
balloon takes a bottle-gourd shape when expanded.
20. The balloon catheter assembly according to claim 18, wherein said
circular middle portion of said balloon includes a mesh molded from at
least one material selected from the group consisting of nylon,
polyethylene terephthalate and polyurethane, said mesh being buried
therein so as to restrict the expansion degree of said balloon.
21. The balloon catheter assembly according to claim 18 wherein said
balloon includes a marker made of X-ray opaque substance.
22. The balloon catheter assembly, comprising:
a balloon;
a balloon catheter including a multi-tube unit comprising an inner tube, an
outer tube coaxial with said inner tube, and a chuck for selectively
holding and releasing said balloon, said multi-tube unit having a distal
end portion communicating with said balloon, said outer tube having a
distal end at which said chuck is selectively opened and closed; and
a guide sheath comprising a tube body having such an inner diameter that
said guide sheath admits said balloon catheter so as to introduce said
balloon to a required dwelling portion.
23. The balloon catheter assembly according to claim 22, wherein said guide
sheath has a proximal end connected to a check valve.
24. The balloon catheter assembly according to claim 23, further comprising
an infusion port connected to said check valve.
25. The balloon catheter assembly according to claim 22, wherein said guide
sheath is made of material mixed with an X-ray opaque substance.
26. The balloon catheter assembly according to claim 1, wherein said
balloon includes a mesh molded from at least one material selected from
the group consisting of nylon, polyethylene terephthalate and
polyurethane, said mesh being buried therein so as to restrict the
expansion degree of said balloon.
27. A balloon catheter assembly, comprising:
an expandable balloon having an opening in a proximal end portion thereof;
an inner tube having a distal end portion which is removably inserted in
said opening of said balloon;
an intermediate tube coaxially surrounding said inner tube with a space
therebetween;
a chuck at a distal end of said intermediate tube, said chuck comprising a
plurality of expandable and contractible holding portions; and
an outer tube surrounding said intermediate tube with a space therebetween;
said chuck being closed when pulled into said outer tube and pressed by
said distal end of said outer tube to thereby hold said proximal end
portion of said balloon, and said chuck being opened when pushed out of
said distal end of said outer tube, to thereby releases said proximal end
portion of said balloon; and wherein
said intermediate tube and said outer tube have proximal ends connected to
respective check valves;
said intermediate tube extends outward from said outer tube via said check
valve connected to said outer tube; and
said inner tube extends outward from said intermediate tube via said check
valve connected to said intermediate tube, such that a body fluid is
prevented from flowing reversely when said distal portion of said catheter
is inserted in a body.
28. The balloon catheter assembly according to claim 27, further comprising
infusion ports connected to said check valves which are connected to said
intermediate tube and said outer tube, respectively.
29. A balloon catheter assembly, comprising:
an expandable balloon having an opening in a proximal end portion thereof;
an inner tube having a distal end portion which is removably inserted in
said opening of said balloon;
an intermediate tube coaxially surrounding said inner tube with a space
therebetween;
a chuck at a distal end of said intermediate tube, said chuck comprising a
plurality of expandable and contractible holding portions; and
an outer tube surrounding said intermediate tube with a space therebetween;
said chuck being closed when pulled into said outer tube and pressed by
said distal end of said outer tube to thereby hold said proximal end
portion of said balloon, and said chuck being opened when pushed out of
said distal end of said outer tube, to thereby release said proximal end
portion of said balloon; and
wherein said balloon has a circular middle portion which is thick such that
said balloon takes a bottle-gourd shape when expanded.
30. A balloon catheter assembly, comprising:
an expandable balloon having an opening in a proximal end portion thereof;
an inner tube having a distal end portion which is removably inserted in
said opening of said balloon;
an intermediate tube coaxially surrounding said inner tube with a space
therebetween;
a chuck at a distal end of said intermediate tube, said chuck comprising a
plurality of expandable and contractible holding portions; and
an outer tube surrounding said intermediate tube with a space therebetween;
said chuck being closed when pulled into said outer tube and pressed by
said distal end of said outer tube to thereby hold said proximal end
portion of said balloon, and said chuck being opened when pushed out of
said distal end of said outer tube, to thereby release said proximal end
portion of said balloon;
said balloon being molded from at least one material selected from the
group consisting of silicone rubber, polyurethane and latex; and
said balloon including a mesh molded from at least one material selected
from the group consisting of nylon, polyethelene terephthalate and
polyurethane, said mesh being buried therein so as to restrict the
expansion degree of said balloon. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to a balloon catheter assembly comprising a
detachable occluding balloon for occluding a path of a body fluid such as
a blood vessel, and to a guide sheath for guiding the introduction of the
catheter.
An occluding balloon is used for mainly occluding a blood vessel such as an
artery when, for example, a percutaneous surgery of congenital cardiopathy
due to patent duct arteriosus is carried out.
The PCT Patent Publication Sho 57-500720, for example, discloses a balloon
catheter having an occluding balloon in which the balloon is separable at
a required portion. However, this balloon catheter has the following
problems:
Since the balloon has a complicated structure, it cannot be rendered small.
Further after the balloon has been expanded by accident, it cannot be
contracted again.
Still further, it is feared that since the balloon is fitted only to the
distal portion of the catheter, it may fall off by accident during its
operation.
A similar balloon catheter is disclosed in the Japanese unexamined patent
application publication Sho 59-34269. Since the balloon is also only
fitted to a cannula, it may fall off by accident. If the connecting
strength of the fitting portion is enhanced, the balloon can be prevented
from falling off. However, it becomes difficult to separate the balloon
from the catheter; the balloon gives an excess stress to the blood vessel
to be occluded; and such a bulky structure of the balloon may cause the
breakage thereof.
The balloon can be threadably connected to the catheter by means of screw.
When the balloon is to be separated from the distal portion of the
catheter assembly, however, the torque is not easily transmitted to the
connecting portion of the balloon with the result that this may cause such
trouble that the balloon would not be easily separated from the catheter,
and the balloon would be twisted to be broken as well.
As a method of introducing an occluding balloon to a dwelling portion of
blood vessel, such as a peripheral blood vessel e.g. a cerebral blood
vessel, the balloon is slightly expanded in advance to be carried by a
blood stream. However, this method is not suitable for sending an
occluding balloon to a vascular portion where a blood flow is rather weak.
This method is not applicable to the transmission of the balloon to the
vicinity of a heart.
The method of transmitting an occluding balloon in a blood vessel while
exposing the balloon as disclosed in the PCT Patent Publication Sho
57-500720, will not only lead to the breakage of the balloon but makes it
difficult to easily and accurately transmit the balloon to the required
dwelling portion.
This invention provides a balloon catheter assembly in which a balloon does
not easily fall off during the transmitting operation thereby ensuring the
introduction of the balloon to the required portion to be occluded, and,
even if the balloon is expanded by accident, it can be contracted to the
original size if a filler has not yet been gelled.
This invention further provides a balloon catheter assembly in which an
operator can easily observe how a balloon occludes the required portion.
The invention still further provides a balloon catheter which is simple in
structure and in which a balloon can be rendered small and can not be
easily broken.
SUMMARY OF THE INVENTION
This invention is fundamentally characterized by comprising an expandable
balloon having an opening at a proximal portion thereof, an inner tube
having a distal portion detachably fitted in the opening of the balloon, a
chuck surrounding a distal portion of the inner tube and fixed to an outer
peripheral surface the inner tube, the chuck having a plurality of holding
pieces whose distal ends extend outwardly and radially, and an outer tube
coaxially surrounding the inner tube leaving a space therebetween, wherein
the holding portions are adapted to be pressed inwardly by a distal end of
the outer tube to hold the proximal portion of the balloon when the inner
tube is pulled into the outer tube, and the holding portions are
automatically opened and expanded to release the proximal portion of the
balloon when the chuck is pushed out of the distal end of the outer tube.
With the catheter assembly having the fundamental structure as described
above, a check valve may be provided at the proximal end of the outer tube
such that the inner tube is extended out through the check valve thereby
preventing a body fluid such as blood from flowing reversely when the
distal portion of the catheter is inserted into a body.
Further, an infusion port may be connected to the check valve provided at
the outer tube, and another infusion port for a balloon expanding filler
may be connected to the proximal end of the outer tube.
Still further, the unexpanded balloon may be properly accommodated in the
distal portion of the outer tube.
This invention is characterized by having a further fundamental structure
comprising an expandable balloon having an opening at a proximal portion
thereof, an inner tube having a distal portion detachably inserted in the
opening of the balloon, an intermediate tube coaxially surrounding the
inner tube leaving a space therebetween and provided at a distal portion
thereof with a chuck having a plurality of openable holding pieces, and an
outer tube coaxially surrounding the intermediate tube leaving a space
therebetween, wherein the chuck is pulled in the outer tube, and the chuck
releases the proximal portion of the balloon when the chuck is pushed out
of the distal end of the outer tube.
With the catheter assembly having the second fundamental structure, the
intermediate and outer tubes may have connectors connected to respective
check valves provided at the proximal ends of the intermediate and outer
tubes such that the intermediate tube is extended outwardly through the
check valve of the outer tube and the inner tube is extended outwardly
through the check valve of the intermediate tube thereby preventing a body
fluid such as blood from flowing reversely.
Further, infusion ports may be connected to the check valves at the inner
and outer tubes, and another infusion port for a balloon expanding filler
may be connected to the proximal end of the inner tube.
Still further, the unexpanded balloon may be suitably installed in the
distal end of the outer tube.
More further, a circular thick portion is formed at the middle circular
portion of the balloon such that the balloon takes a bottle-gourd shape
when it is expanded.
This invention further provides a balloon catheter assembly which comprises
a balloon catheter in which a balloon communicates with the distal end of
a multi-tube unit comprising an inner tube and an outer tube slidably and
coaxially mounted thereon, and a chuck which selectively opens and closes
at the distal end of the outer tube selectively to hold and release the
balloon, a guide sheath which has a tube body having such an inner
diameter that the guide sheath permits the balloon catheter to be guided
and which guides the balloon to a required dwelling portion, and a guide
sheath which guides the balloon to a required dwelling portion.
It is preferred that a check valve be connected to the proximal end of the
guide sheath and an infusion port in series.
It is also preferred that the guide sheath is made of material mixed with
X-ray opaque substance.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is an enlarged cross-sectional view of the distal portion of a
occluding balloon catheter according to this invention;
FIG. 2 is a perspective view of an intermediate tube of the catheter in
FIG. 1;
FIG. 3 is a cross-sectional view of the same embodiment as that in FIG. 1,
with the balloon expanded;
FIG. 4 is a plan view of an embodiment of the overall occluding balloon
catheter assembly according to this invention;
FIG. 5 is a plan view of an embodiment of the guide sheath;
FIGS. 6 and 7 are cross-sectional views of other embodiments of the
occluding balloon catheter assembly according to this invention;
FIG. 8 is a perspective view of the inner tube of the catheter in FIG. 7;
FIG. 9 is a cross-sectional view of the same embodiment as that in FIG. 7,
with the balloon expanded;
FIG. 10 is a cross-sectional view of another embodiment of the occluding
balloon catheter; and
FIGS. 11 to 13 are cross-sectional views of modifications of the balloon.
DETAILED DESCRIPTION
This invention will be explained with reference to embodiments shown in the
drawings.
FIG. 1 shows the distal portion of the occluding balloon catheter according
to this invention. As seen from this figure, a main catheter 1 is formed
with a triple-tube unit comprising an outer tube 2, an intermediate tube 3
and an inner tube 4 arranged coaxially with each other. The inner tube 4
has a slightly thinner distal portion 4a and is inserted in an opening 5b
formed in the center of the proximal portion 5a of a balloon 5 so as to
communicate with the interior of the balloon 5.
The intermediate tube 3 surrounding the inner tube 4 at a spacing is formed
at its distal end with a chuck portion 6 having a plurality of holding
portions 6a which selectively opens and closes. As shown in FIG. 2, the
holding portions 6a forming the chuck portion 6 are four in number and are
integral with the intermediate tube 3. They normally open most widely at
their distal ends, and the inner diameter defined by their distal ends is
much larger than the outer diameter of the proximal portion 5a of the
balloon when they are opened. On the distal end of each of the holding
portions 6a is formed a hook 6b projecting inwardly of the chuck 6. The
hooks 6b bite into the outer peripheral wall of the proximal portion 5a of
the balloon 5 to hold the same, at the time of engagement as shown in FIG.
1.
The outer tube 2 surrounding the intermediate pipe at a spacing from the
outer periphery of the outer tube 2 has at its distal end an inner
diameter much smaller than the diameter defined by the distal end of the
chuck 6 formed on the intermediate tube 3 when the chuck is expanded such
that the movement of the intermediate tube 3 into and out of the outer
tube 2 causes the chuck 6 to be pushed inwardly by the intermediate tube 3
and to be released therefrom, respectively, whereby the chuck 6 freely
closes or opens.
When a filler is introduced into the balloon 5 through the inner tube 4,
the balloon 5 is expanded as shown in FIG. 3. The material of the balloon
5 may be mixed with X-ray opaque substance such as platinum, gold or the
like which constitutes a marker.
The total structure of this occluding catheter assembly will be explained.
As shown in FIG. 4, the proximal ends of the intermediate tube 3 and the
outer tube 2 are connected to check valves 8a and 8b, respectively, via
connectors 7a and 7b. However, the connectors 7a and 7b are not always
necessary, but the proximal ends of the intermediate tube 3 and the outer
tube 2 may be directly connected to the respective check valves 8a and 8b.
Further, the intermediate tube 3 is led out from the outer tube 2 through
the check valve 8b connected to the outer tube 2, and likewise the inner
tube 4 is led out from the intermediate tube 3 through the check valve 8a
connected to the intermediate tube 3, thereby preventing a body fluid such
as blood from flowing reversely.
As shown in FIG. 4, the check valves 8a and 8b are connected to infusion
ports 10a and 10b comprising two-way valves, three way valves or the like,
respectively, via connecting tubes 9a and 9b. Physiological salt solution,
for example, is infused continuously of intermittently in the tubes 3 and
4 through the infusion ports 10a and 10b, so that blood or other body
fluid which would otherwise enter the outer tube 2 and the intermediate
tube 3 during the operation of the catheter, is excluded. This process is
intended to prevent blood or the like entering the catheter from being
coagulated so as to operate the catheter normally.
An infusion port 10c (preferably, a two-way valve or a three-way valve) is
connected to the proximal end of the inner tube 4 via a connector 7c so as
to infuse a balloon expanding filler.
In general, the inner tube 4, the intermediate tube 3 and the outer tube 2
are made of such thermoplastic resin as polyethylene, polyolefin,
ethylene-vinylacetate copolymer, polyester, polyvinylchloride,
polyurethane, fluoric resin and nylon.
The material of the balloon 5 can be selected form elastic material such as
silicone rubber, polyurethane and latex. A mesh made of nylon,
polyethelene terephthalate, polyurethane or the like is embedded in the
thick portion of the balloon 5 such that the balloon 5 is not expanded
beyond a required size.
A guide sheath 11 comprises a tube body having an inner diameter permitting
the catheter 1 as well as the balloon 5 to be inserted into the sheath 11.
As shown in FIG. 5, a connector 12 accommodating a check valve is
preferably connected to the proximal end of the guide sheath 11. An
infusion port 13 for infusing physiological salt solution into the guide
sheath 11 connected to the connector 12 via a tube 14. This arrangement
hinders the reverse flow of blood or the like when the guide sheath 11 is
inserted in the body and excludes the blood or the like which has entered
the guide sheath 11 by means of physiological salt solution or the like.
Like the catheter 1, the guide sheath 11 is generally made of thermoplastic
resin such as polyolefin, ethylene-vinylacetate copolymer, polyester,
polyvinylchloride, polyurethane, fluoric resin or nylon.
There will be explained the process how to dwell the balloon in a blood
vessel by using the balloon catheter assembly.
First, a guide wire (not shown) is moved to a balloon dwelling portion by
the similar method of angiography. The guide wire may be further advanced
beyond the dwelling portion. Secondly, the guide sheath 11 set with a
dilator (not shown) is inserted into the blood vessel along the guide wire
until it reaches the balloon dwelling portion. The dilator is required
when the guide sheath 11 begins to be inserted into the blood vessel, but
it may be removed when the guide sheath 11 is moved to the balloon
dwelling portion. Thirdly, the guide wire is removed when the guide sheath
11 has been moved to the balloon dwelling portion.
Thereafter, the catheter 1 is introduced to the dwelling portion through
the guide sheath 11 with the balloon 5 held at the distal end of the
catheter 1 as shown in FIG. 1. During the introduction of the catheter 1,
the balloon 5 does not fall off because its distal portion 5a is firmly
held by the chuck 6 formed on the distal end of the intermediate tube 3.
After the balloon 5 has been positioned in the dwelling portion as
described above, the balloon expanding filler is introduced in the balloon
5 through the infusion port 10c at the proximal end of the inner tube 4 to
expand the balloon 5 to a required size as shown in FIG. 3. The filler is
made of gelable liquid such silicone RTV (Silicone Rubber KE12 RTV --a
trade name of Shin-etsu Kagaku Kogyo Kabushiki Kaisha), cross-linked type
modified polyvinyl alcohol or the like (with which X-ray opaque substance
such as tungsten, bismuth oxide, barium sulfate or the like may be mixed).
When the filler is mixed with the X-ray opaque substance, the catheter
assembly can be used in X-ray fluoroscopy.
After the filler has been cured in the balloon 5, the outer tube 2 is
retracted towards the proximal ends of the intermediate tube 3 and the
inner tube 4, whereby the check 6 opens automatically and is disengaged
from the proximal portion 5a of the balloon 5. Then, the distal end of the
inner tube 4 is released from the proximal portion 5a of the balloon 5 by
pulling the inner tube 4 towards it proximal end with the balloon 5 left
in the required dwelling portion. If necessary, physiological salt
solution is continuously or intermittently infused into the catheter
through the infusion ports 10a and 10b.
In the above embodiment, the outer tube 2 has the same diameter over its
entire length. As shown in FIG. 6, however, the distal portion 2a may be
expanded to have such a large inner diameter that the portion 2a admits
the unexpanded balloon 5 with the proximal portion 5a of the balloon 5
held by the chuck 6 formed on the intermediate tube 3. This structure is
preferably used to hinder the balloon 5 from being damaged while the
balloon 5 is being moved to the dwelling portion.
In FIG. 7 is shown another embodiment of the distal portion of the
occluding balloon catheter according to this invention. As clearly
understood from this figure, a catheter 21 has a double-tube unit
comprising an outer tube 22 and an inner tube 23 coaxial therewith. The
distal portion 23a of the inner tube 23 is formed slightly thinner than
its remaining part and is inserted in an central opening 24b formed in the
center of the proximal portion 24a of a balloon 24 so as to communicate
with its interior.
On the distal end of the inner tube 23 is formed a chuck 25 comprising
three holding pieces 25a arranged equidistantly in the circumferential
direction so as to surround the distal portion 23a of the inner tube 23.
As shown in FIG. 8, the holding portions 25a or normally opened most
widely at their distal ends in such a manner that they can hold the outer
peripheral surface of the proximal portion 24a of the balloon 24.
The distal end of each of the holding pieces 25a is formed with an inwardly
projecting hook 25b. The hooks 25b bite in the outer peripheral surface of
the proximal portion 24a of the balloon 24 to hold the same when the
balloon 24 is connected to the catheter 21 as shown in FIG. 7.
The distal portion of the outer tube 22, which surrounds the inner tube 23
at a spacing from its outer peripheral surface, has an inner diameter much
smaller than the diameter of the distal end of the chuck 25 formed on the
inner tube 23 when the chuck 25 is opened. The movement of the inner tube
23 into and out of the outer tube 22 causes the chuck 25 to be pushed
inwardly by the outer tube 22 and released therefrom, respectively,
whereby the chuck 25 freely closes or opens.
The structure, functions and usage of this embodiment other than those as
described above are the same as those of the embodiment shown in FIG. 1.
As shown in FIG. 9, after the balloon 24 has been expanded to a required
size, the outer tube 22 is moved towards the proximal end of the inner
tube 23 to open the chuck 25a, and then the inner tube 23 is also pulled
towards it proximal end, whereby the distal portion 23a of the inner tube
23 is released from the proximal portion 24 of the balloon 24 with only
the balloon 24 left in the required dwelling portion.
This embodiment can be modified as shown in FIG. 10, in which the distal
portion 22a may be expanded to have such a large diameter than the portion
22a admits the unexpanded balloon 24 with the proximal portion 24a of the
balloon 24 held by the chuck 25 formed on the inner tube 22. This
structure is preferably used to hinder the balloon 24 from being damaged
while the balloon 24 is being moved to the dwelling portion.
The shape of the balloon is not limited to that of the balloon 24 of the
second embodiment, but, as shown in FIG. 11, the distal portion 24c of the
balloon 24 may be made solid, and a belt-type marker 24d made of X-ray
opaque substance as described above may be fixed to or embedded in the
outer peripheral surface of the portion 24c. Further, as shown in FIG. 12,
the intermediate portion of the part, to be expanded, of the balloon 24
may be formed with a thick portion 24e so as to take a bottle-gourd shape
when the balloon 24 is expanded as shown in FIG. 13. It is preferred that
the opening 24b of the balloon 24 should be closed except when the inner
tube is inserted in a blood vessel or the like such that the filler in the
balloon is prevented from being discharged from the opening 24b.
The balloon catheter assembly according to this invention has such a
structure that the catheter comprises a double-tube unit or a triple-tube
unit in which the inner tube or the outer tube of the structures is
provided at the distal end thereof with a freely openable and closable
chuck thereby to hold or release the balloon. Therefore, the catheter
assembly according to this invention provides the following technical
features:
The balloon does not fall out during the operation of the catheter assembly
and it becomes easy to collect the balloon again.
Further, when the balloon is expanded by accident, it can be contracted if
the filler has not yet been gelled therein.
Still further, the breakage of the balloon can be prevented by installing
the balloon in the outer tube.
In addition, the simple structure of the balloon enables the whole catheter
assembly to be small-sized.
INDUSTRIAL APPLICABILITY
The balloon catheter assembly according to this invention is useful to
occlude a blood vessel such as a patient's artery during percutaneous
surgery.
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Description |
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