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Claims  |
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I claim:
1. A catheter with distal end structure for forming a lumen to encompass
and ride along a guide wire comprising in combination:
a substantially cylindrical catheter body with an outer wall about a first
lumen with the outer wall gradually changing in shape along the catheter
body length toward the distal end from an entrance groove shaped as a path
for guiding the wire inwardly into the cylindrical body along the catheter
length to form initially a crescent shaped catheter body configuration
partly surrounding the wire and which thereafter changes into a closed
cylinder wall surrounding a second guide lumen for encompassing the guide
wire.
2. The catheter distal end structure of claim 1 wherein the outer wall of
the catheter body over the length in which the catheter changes gradually
and smoothly from a single lumen configuration to a two lumen
configuration is substantially cylindrical in shape forming with the
accompanying guide wire an extension of the cylindrical catheter body.
3. The catheter distal end structure of claim 1 wherein the path of the
wire through the groove and crescent shaped configuration into the second
quide lumen is substantially parallel with the catheter body.
4. The catheter distal end structure of claim 1 wherein the catheter body
consists of a plastic material having a substantially constant axial
stiffness throughout the distal end structure length corresponding
substantially to that of the cylindrical catheter body, for permitting the
catheter to be inserted into or withdrawn from body vessels of small
dimension from a position outside the body.
5. The catheter structure of claim 1 wherein the catheter body along the
length of the change from one to two lumens thereby presenting the initial
lumen in a crescent shape is reinforced to prevent the generally
cylindrical catheter body from distorting in shape in response to internal
fluid pressures used for dilatation.
6. The catheter of claim 1 having a distal end portion formed with a
substantially cylindrical outer wall along a predetermined length to which
a balloon dilatation structure is affixed at two spaced positions along
the cylindrical outer wall for dilation by means of fluid under pressure
in the initial lumen.
7. The catheter of claim 6 wherein the dilatation balloon structure when
dilated under fluid pressure has a cylindrical configuration tapering
gradually down to the catheter body at two ends.
8. The catheter of claim 1 with a body consisting of plastic having a
characteristic of axial stiffness and a shear characteristic permitting
the catheter body to readily bend around curves.
9. A substantially cylindrical catheter body structure adapted to receive,
direct, and envelop a substantially parallel disposed guide wire along a
portion of the catheter's length thereby forming an internal catheter
guide wire lumen by changes of shape of the cylindrical catheter body
gradually over said length from a guide wire entry groove indented on the
catheter outer surface into the internal lumen encompassing the guide
wire.
10. The catheter structure of claim 9 wherein the catheter body shape
configuration about the lumen is constructed to preserve a substantially
constant longitudinal stiffness along the catheter body.
11. A therapeutic medical instrument for insertion into the body for
treatment at an internal body site, comprising in combination:
guide wire means for insertion into the body to a treatment site for
guiding therapeutic means thereover into the treatment site;
treatment means for insertion into the treatment site having a proximal end
for employment outside the body including treatment lumen structure
providing a communication path from outside the body to the treatment
site, guide wire lumen structure within said treatment means for movement
of the instrument along the guide wire to a treatment site, and a distal
end instrument for movement inside the body to a treatment site;
treatment means structure for inserting the guide wire means into the guide
wire lumen confined to a short length low friction coupling region near
the distal end of the treatment means at a linear portion having a
substantially cylindrical body of substantially constant diameter, whereat
the treatment lumen configuration changes in shape gradually along said
coupling region to receive the guide wire and fully encompass the guide
wire, and
wherein the coupling region structure in the instrument for introducing the
guide wire into the guide wire lumen without substantial change of
direction of the guide wire from a parallel position alongside the
treatment means body providing a smooth progressive transition from
cylindrical shape, to indented cylindrical shape provides a groove for
guiding the guide wire, to substantially cresent shape for partly
surrounding the wire, to the guide lumen.
12. A catheter for use with a companion guide wire having means for
retention of the guide wire substantially within the catheter outer
perimeter for insertion into a body vessel of restricted size, comprising
in combination, a catheter body having a longitudinal groove internally
indented in the outer periphery along a portion of the catheter length
adapted to nest a guide wire therein and structure gradually changing the
groove into a lumen within the catheter body for retaining the guide wire
to thus produce a reduced outer perimeter for the catheter and guide wire.
13. A catheter as defined in claim 12 having a guide wire nested in said
groove thereby producing a substantially cylindrical outer perimeter of
the combined catheter body and guide wire.
14. A combination of a guide wire and catheter adapted for insertion into a
body vessel comprising in combination, a catheter body having a
longitudinal groove along a predetermined length of the catheter near its
distal end to be inserted into a body vessel of restricted size, said
groove having a shape for receiving nested therein alongside the catheter
body a substantially parallel guide wire, said groove changing into a
lumen within the catheter for thereby receiving and surrounding the guide
wire thereby to reduce an outer peripheral dimension of the catheter
body-guide wire combination residing within the vessel.
15. The method of inserting a guide wire into the distal end of a catheter
so that the catheter may ride along the guide wire with low friction
comprising the steps of:
producing a hollow cylindrical catheter with a circumferential wall
surrounding a lumen,
gradually changing the circumferential wall configuration to provide
structure for inserting the guide wire to structurally change the
circumferential wall along its length into a second lumen formed within
the catheter with the initial cylindrical hollow catheter circumferential
wall changing along its length to form (a) an entrance groove for guiding
the wire into a crescent shaped wall section partly surrounding the wire
and (b) transition structure closing the cresent to produce a guiding
lumen about the wire, and
inserting a guide wire disposed substantially parallel with the catheter
into the groove to follow the transition structure and enter the guiding
lumen without departing substantially from the parallel disposition of the
guide wire and catheter.
16. The method of introducing a guide wire into a substantially cylindrical
catheter body near its distal end while maintaining the diameter of the
cylindrical catheter body substantially constant along its length to a
position disposed around a guiding wire in a distal end region having a
dilatation balloon structure positioned circumferentially about the
catheter body perimeter, comprising the steps of:
indenting the cylindrical catheter body to provide a shaped groove along
the length of the body for entry of the guiding wire, changing the groove
in shape along said length into a lumen surrounding the guide wire without
a substantial change in diameter of the catheter body, and
inserting a guide wire disposed substantially parallel to the catheter body
gradually into the dilatation catheter body along its length to dispose
the guide wire substantially concentrically within the balloon without
substantially changing the diameter of the catheter body.
17. The method of claim 16 further comprising the step of changing an
internal dilation lument shape initially disposed within the cylindrical
catheter body from substantially circular to a non-round shape to
accommodate the groove for insertion of the guide wire.
18. The method of transforming a distal end of a substantially cylindrical
catheter body having an internal lumen to produce an additional internal
guide wire lumen therein by the steps of retaining the cylindrical body
outer peripheral dimension substantially constant along its length and
changing the shape of said cylindrical body and internal lumen along tbe
length of the body to form an indented guide groove on the catheter body
outer surface thereby changing the shape of the internal lumen and
changing the cylindrical body shape over the length of the catheter body
from the groove into said internal guide wire lumen.
19. The method of creating in a substantially cylindrical plastic catheter
body, having internal lumen means, a structure for encompassing and riding
over a guide wire comprising the steps of modifying the outer peripheral
shape of the catheter body while substantially retaining its cylindrical
configuration into an indented groove for gradually enveloping the guide
wire along a predetermined length of the catheter body to produce a
further internal lumen within the cylindrical body to fully surround the
guide wire.
20. The method of claim 19 including the step of tapering the lumen means
and the cylindrical body gradually along a distal end length of the
catheter body beyond said predetermined length.
21. The method of claim 19 including the steps of affixing a dilatation
balloon structure over a length of the cylindrical body behind said
predetermined length having a substantially constant diameter and
producing aperture means to communicate with said lumen means for dilation
of the balloon structure.
22. The method of inserting into and withdrawing from a treatment site a
catheter consisting of a plastic material comprising a dilatation balloon
assembly having a dilating lumen and structure for riding concentrically
about a guide wire along a portion of its length at a distal end position
of the catheter, comprising the steps of: inserting into the treatment
site a guide wire, positioning a distal end portion of the catheter
substantially parallel to the guide wire, merging the external
substantially parallel guide wire into a groove in an outer catheter
surface portion near the distal end gradually changing into an internal
lumen positioned within the catheter along a predetermined portion of the
catheter surrounding the guide wire without substantially bending the
guide wire, forming a catheter body over its length having a similar axial
stiffness and catheter peripheral shape so that the catheter movement
forces are substantially axially balanced along the body of the catheter
throughout its length, and imposing both insertion and withdrawal forces
at a proximal end of the catheter in a direction along the length of the
catheter for inserting and withdrawing the catheter from the treatment
site.
23. The method of claim 22 further comprising the step of grooving the
outer periphery of the catheter along a portion of its length to conform
with and receive nested therein said guided wire with the catheter body
substantially constant in diameter over a merge area between the groove
and internal lumen.
24. The method of decreasing the overall volume required for the
combination of a catheter body and a parallel guide wire for insertion
into a restricted size body tubing such as a cardiovascular vessel for
treatment comprising the steps of providing a longitudinal groove along a
portion of the length of the catheter body conformed with the guide wire
dimensions changing the groove gradually into a lumen within the catheter
body surrounding the guide wire, and feeding the guide wire and catheter
into the body with the guide wire resting in the lumen. |
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Description |
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TECHNICAL FIELD
This invention relates to instruments and methods of therapeutic treatment
of the body at internal body sites and more particularly it relates to
dilatation catheters movable along coronary blood vessels upon a guide
wire to position an uninflated balloon at a site for treating stenosis by
subsequent inflation of the balloon, or the like.
BACKGOUND ART
The art balloon dilatation catheters for treatment of stenosis in coronary
blood vessels is well developed. Representative U.S. patented art includes
the following briefly discussed catheters:
G. T. Schejeldahl, et al., U.S. Pat. No. 4,413,989 Nov. 8, 1983 was
concerned with long treatment periods in a balloon catheter inserted over
a guide wire and thus provides for dilation without interruption of the
blood supply with a lumen for bypassing blood.
A. Kuhl, U.S. Pat. No. 4,439,186 provides for pulsating pressure for
expansion and contraction of the balloon to permit blood flow past the
balloon.
J. J. Leary, U.S. Pat. No. 4,545,390 is concerned with steering the balloon
and thus provides a steerable end to the guide wire upon which the balloon
rides.
M. J. Horzewski, et al., U.S. Pat. No. 4,748,982 June 7, 1988 provides a
balloon dilatation catheter with a short distal end portion moving along a
guide wire with the feature of decreasing stiffness of the catheter body
from the proximal extremity to the distal extremity in order to overcome
difficulties in pushing prior catheters to a treatment site.
T. Bonzel, U.S. Pat. No. 4,762,129, Aug. 9, 1988 provides a stiffener wire
in a separate balloon dilating lumen positioned parallel to the guide wire
except at the distal end to aid in pushing the balloon to the treatment
site.
There still reamin many unsolved problems in the art of treatment of a site
within the body with instrumentation located in part outside the body. In
the dilatation catheter art, for example, there are problems of pushing
catheters into position at the treatmenmt site through restricted body
vessels. Any unbalance of thrust forces or bends or kinks in te catheter
can interfere with insertion or withdrawal. Critical is the friction
encountered in moving a catheter along a guide wire. While considerable
friction is removed by inserting the guide wire only at a distal end
region of the catheter, the adds criticality by introducing a tendency to
tilt or veer in the presence of slightly off axis thrust forces or
unbalances of size, strength or axial stiffness of the catheter body. This
is particularly evident at entrance point of the wire into the catheter
body, where it is common to bend or distort the path of the guide wire,
thereby adding unwanted friction and guiding problems. An example of this
is given by the sharp bending zone in the guidewire set forth in the
Horzewski patent.
Furthermore with dilatation balloon structure affixed to the catheter body
and subjected to dilating by means of injecting fluid at high pressure,
there are sealing and inflation problems. Thus, because of the high
inflation pressures, any attempt to seal on a non-cylindrical surface
produces a tendency to either produce leakage by tearing away the sealing
joint or an uneven inflation of the balloon structure causing weak points
or misshaping. Shaping is critical for passage into stenosis areas, and
leakage or pressure limitations critical to the treatment and safety of
the patient.
Another problems area is the abrupt transition of a catheter tubing body or
lumen at transition areas for entry of a guide wire or mounting of a
balloon. This can for example tend to cause damage to vesel sidewalls or
as heretofore discussed by causing the short distal end rider type of
catheter geneally preferable to reduce friction on insertion between the
catheter and the guide wire or its connection tubing to bend, veer, buckle
or bind on the guide wire in response to pushing or pulling axial forces
exerted along the catheter axis to insert or withdraw the catheter.
The distal end profile of a balloon is critical particularly if it needs to
be forced through a stenosis. The flexibility of the balloon for dilation
is inconsistent with the initial need for penetration of restricted
passageways to position the balloon at a treatment site for dilation. As a
matter of fact any abrupt transition from one material to another or from
one shape to another as it occurs if two separate lumens--one for
inflation of the balloon and one for guidance of the wire--cause an abrupt
joint between the lumens such as in the catheter suggested by Bonzel,
supra, such abrupt changes provide problems of insertion, positioning and
reliability.
Particularly for coronary blood vessel treatment, small diameters, known as
low profile, for insertion into branch vessels and flexibility to bend
around sharp corners is critical. Thus balloons attached to stiff tubings
or those unadapted to bend around a vessel curve are of limited use as
well as those requiring significant room resulting in greater diameters of
the catheter body for mounting elements affixing the balloon structure
upon the catheter.
Very critical to coronary vessel treatment is the quick interchange of
dilatators of different size. Thus a smaller diameter dilatator balloon
may be used for penetration of the stenosis and enlargement enough to
accommodate a larger diameter balloon necessary to restore a reasonably
normal working diameter in the vessel.
It is therefore a particular object of this invention to provide an
improved dilatation catheter particularly adapted for angioplasty and
treatment of coronary vessels that resolves the foregoing problems in the
prior art.
A more general object is to provide improved instrumentation and treatment
methods for therapeutic treatment at sites within the body from the
outside.
Other objects, features and advantages of the invention will be found
throughout the following description, and in the accompanying drawings and
claims.
DISCLOSURE OF THE INVENTION
This invention provides therapeutic instrumentation and treatment methods
for treatment inside the body of the type that is passed over a guide wire
of positioning at the treatment site. A specific example is an inflatable
dilatation catheter specially adapted for arteriosclerotic vessel
treatment of stenosis or angioplasty. The catheter is of the type riding
on a guide wire only at a short distal end portion. Novel features of this
catheter include the transition of the catheter tubing, typically plastic
having a cylindrical thin skin-like wall surrounding a single inflation
lumen for dilating and accompanying balloon to accommodate a second guide
wire lumen at a predetermined length of the catheter body near the distal
end.
Thus the configuration of a conventional cylindrical catheter tubing with
outer plastic wall defining a single internal lumen changes gradually
while passing through successive configurations at the more distal
(balloon) end. Thus the generally substantially cylindrical outer wall,
becomes grooved to guide a substantially parallel guide wire alongside
toward the interior of the catheter without any substantial bending of the
wire. The catheter groove then progressively leads into a crescent shaped
wall-lumina configuration which partially encompasses the guide wire
before becoming cylindrical to surround the guide wire as a toroid. In
parallel to this grooving and encompassing process, the inner lumen of the
catheter changes its shape as well from round towards more of a C-shaped
configuration. This unique and novel feature contributes significantly to
smaller total diameter of dilatation catheters despite the same mechanical
strength for pushing the catheter forward, compared to conventional
arrangement with two parallel cylindrical lumens. The distal end lumen and
body structure finally tapers into a low profile solid nose adapted for
working its way through stenosis before the balloon affixed to the
cylindrical length of the catheter body is placed at the stenosis. The
wall of the inflating-deflating tube is apertured at the site of the
balloon to connect the balloon via the inflating-deflating lumen within
the catheter body to the outside of the human body for operation of the
balloon by fluid injection under pressure. This provides a short low
friction rider of limited length and of small diameter substantially
cylindrical. This cylindrical diameter extends along the entire length of
the distal catheter body that it can be introduced into smaller vessels in
the coronary system for treatment.
The novel structure permits construction at the entry position of the guide
wire into the catheter body at a position having a common shape and
consistent still axial strength with the rest of the catheter body to
facilitate feeding into a treatment site. A lateral modulus of elasticity
sufficient to permit bending about sharp curves is provided within the
plastic catheter body devoid of stiffener wires. The bending is enhanced
around curves by the novel form of the inflating lumen as a C-shaped
lumen, which bends readily as the catheter is inserted. It also readily
permits withdrawal and replacement of small diameter catheters in small
passagesways with progressively increasing balloon sizes when needed.
When a catheter and a guide wire are inserted into an arterial vessel of
sufficient size over an introducer sheet, the diameter of the dilatation
catheter plus that of a guide wire lying outside the catheter is not
critical to the possibility to introduce the system into the human body.
But there are conditions where severely diseased and narrowed vessels make
the size of the introducer sheet critical to the success of insertion. In
those cases, the overall diameter of the dilation catheter and the guide
wire together can be decreased if a groove is present along the entire
catheter structure forwards of the outside of the body. By this means the
guide wire is situatied within the circumferential groove in the dilation
catheter enabling small size introducer sheets.
BRIEF DESCRIPTION OF THE DRAWINGS
Like reference characters are used to identify similar features throughout
the drawings, wherein:
FIG. 1 is a sketch of a distal end portion of a dilatation catheter of this
invention showing a low friction saddle rider portion of the catheter
merging into and surrounding a substantially parallel guide wire upon
which the catheter distal end rides;
FIG. 2 is a broken away fragmental sketch of the dilatation catheter
functioning at a treatment site inside a body vessel at a stenosis
treatment site; and
FIGS. 3 to 10 are respective cross sectioned portions of the catheter at
corresponding positions 3--3, etc. shown on FIG. 1.
THE PREFERRED EMBODIMENT
In the present invention , the catheter can be given special and critical
properties by means of treatment of plastic materials from which the
catheter is formed. For example, silicones, polyethylenes, polyurethanes,
polyvinylchlorides and like synthetic plastic materials are readily formed
into desired shapes by injection molding techniques, and may be after
treated by thermal molding.
The distal rider end of the catheter afforded by a preferred embodiment of
this invention also is molded from a suitable plastic material to have a
gradual transformation along the axial length from an initial
substantially round cylindric shape to a modified shape of the dilatation
fluid lumen without abrupt changes from a generally cylindrical
configuration of constant diameter for penetration of a guide wire into a
gradually created second guide wire lumen formed inside the catheter body.
The catheter body comprises an outer body skin defining an internal
cylindrical dilation fluid lumen which is gradually conformed along a
predetermined portion of the length into a riding saddle over the guide
wire.
Along this length, which permits the guide wire to remain along its length
with a substantially parallel axis with the catheter body, the catheter
body wall gradually progresses from a groove into a crescent shaped wall
and internal lumen which at least partly surrounds the guide wire. The
crescent closes toroidally about the guide wire to form a guide wire lumen
which gradually extends toward the axis of the catheter body as the
dilating lumen and outer configuration tapers into a terminal nose of
solid plastic material. The generally cylindrical body shape is maintained
at a constant diameter, with a cylindrical outer region positioned between
the entry point of the guide wire and the nose for attachment of a
circumferential dilatation balloon. Communication between the balloon and
dilation fluid in the dilation lumen results from apertures in the body
wall.
Throughout the transition portion of the length catheter axial stiffness is
maintained constant to facilitate entry and withdrawal of the catheter.
Lateral bending elasticity is provided by the material and shaping of the
lumen without substantially departing from the initial cylindric shape in
order to facilitate bending in conformation with body vessels.
The balloon or balloon mounting vicinity of the catheter may be radiation
tempered. The C-shaped lumen may be reinforced by shaping or adding
reinforcement means internal to the lumen at any points of critical stress
under pressure caused by non-round lumen shaping. The tempered portions of
the catheter can be treated to give a lateral bending modulus for
similarly bending around curves without significant effect to the axial
pushing stiffness required for positioning and withdrawing the catheter
over a substantially parallel guide wire. Preferably the balloon at the
distal end terminates near a solid plastic nose section tapered to provide
less friction in penetrating a stenosis area for example to position the
balloon for dilatation. Also preferably the balloon exterior perimeter
tapers at both ends and has no disruptions.
By having a common circumferential plastic body about the dilatation lumen
cavity smoothly an progressively changing along the catheter length into
an interior guide wire lumen without abutments or steps in the catheter
diameter, many problems of exerting distortion forces on the catheter or
balloon surface for reaching treatment sites are eliminated. This all
results in a more reliable, low friction, easy to insert balloon dilation
catheter with a smaller diameter catheter in the region of the balloon
than known in the prior art.
As may be seen in FIGS. 1 and 2, the catheter of this invention is ideally
suited for treament of cardiac disease such as stenosis 32 of arterial
vessel wall 31. The catheter 20 is inserted into the cardiovascular system
typified by vessel 31 over a previously inserted guide wire 21 which runs
parallel outside the catheter until it reaches a distal end region 23 for
guiding the catheter to carry instrumentation such as a dilatation balloon
located near its distal end to a treatment site 32.
This catheter is of the type that as it nears the distal end 23, the guide
wire 21 is gradually more and more encompassed and thus little friction
between the guide wire and catheter is present to impede insertion or
withdrawal of the catheter from a position outside the body. The catheter
at region 2--2 of this embodiment is generally of cylindrical shape having
an internal inflation lumen 42 for fluid under pressure to expand a
dilatation balloon in the distal end region 22. The catheter body is
formed of a plastic material 26 having enough axial stiffness to push the
distal end 23 over the guide wire 21 and through small or stenosis
restricted cardiovascular blood vessels into a treatment site without
buckling or restricting the lumen 42 diameter, as aforesaid.
The catheter throughout the distal end regions 4--4 to 10--10, as shown in
cross section in corresponding FIG. 4 through 10, undergoes smoothly
progressing changes of shape of the wall 26 and lumen 42. The distal
terminal end at FIG. 10 is of solid plastic which tapers to a penetration
shape, which helps to advance the balloon more easily over an already
positioned guide wire through high degree narrowings so that the balloon
section of FIG. 9 may be placed into position for dilatation as shown in
FIG. 2 within the blood vessel 31 at stenosis site 32. The guide wire
facilitates withdrawal of the catheter 20 along the guide wire 21 and
allows its replacement with one having a larger diameter head end portion
allowing a greater degree of dilatation. Because of the easy insertion of
the guide wire into the novel guiding lanes and of the limited length of
guidance of the wire in the balloon possible with this invention, initial
treatment with a smaller balloon can readily be followed by a subsequent
treatment with a larger balloon without the need for extensive guiding of
the new catheter over a guide wire of more than double the length of the
catheter.
The smoothly changing shape of the catheter along its axial length at the
balloon site critical to this invention allows for an exchange of
catheters without significant friction thus facilitating easy and fast
pull back and advance of subsequent catheter structure over a guide wire.
This can be visualized as related to the cross sections of FIGS. 3 to 10.
Thus the catheter plastic body wall 26 becomes more deeply grooved at 40
for guiding the guide wire toward its final position, in this embodiment
coaxial with the balloon as shown in FIG. 10. Thus guide wire 21 enters
the catheter body axially from left to right (FIG. 1) through a groove, a
crescent shaped semi-enveloping configuration, FIGS. 5 and 6, and then
completely surrounded as in FIGS. 7 through 10. Thus the catheter is
transformed from a single lumen catheter into two lumens, adding one for
the guide wire, all without changing substantially the outer cylindrical
body configuration or its diameter. Furthermore, the guide wire gradually
enters its new guiding lumen through several changes of guidance within a
groove, and thus incurs no kinking or sharp bending as mandatory for low
friction removal or advance of the catheter over the guide wire.
Also the lumen shape changes gradually within the catheter 20 as seen
through the progression of FIGS. 3 to 9, for this embodiment. Note that
the balloon 90 has an outer skin 91 which is distendable in the presence
of fluid in the inflating lumen 42 under increased pressure into an
expanded diameter 90 shown in phantom view. This balloon is affixed to the
outer cylindrical catheter surface at each end. That is critical in that
high internal pressures are minimized and equalized about the joint,
resulting in more reliability and operation at greater safety margins.
The small diameter of the catheter 20, especially at zone 23, permits good
lateral flexibility to bend around curves in the cardiovascular vessels.
At the tip 100, a special material with some pliability is preferred for
use in penetration of a stenosis region and this may be achieved by
thermal or radiation treatment.
The smooth progressive change of shape of the catheter body 26 and its
internal inflating lumen 25 to convert the single lumen catheter to one
having an additional internal guide wire lumen 45 without substantially
changing the direction of travel of the guide wire and the constant outer
catheter diameter throughout is typified by the sequence in the FIGS. 3 to
10. Thus the catheter body 26 of FIG. 3 becomes grooved at FIG. 4, with
the body 26 and internal lumen 42 becoming crescent shaped at FIGS. 4 and
5. The internal lument 415 is formed at FIG. 7 so that the balloon 90 may
be glued or otherwise affixed to the outer cylindrical periphery of the
catheter body 26 at 91 in FIGS. 2 and 8. The aperture 95 in the catheter
body 26 of FIG. 9 permits balloon 90 to be dilated from fluid in lumen 42
to the inflated balloon condition 90. The lumen 42 is tapered toward the
nose 100 shown in FIG. 10 to provide a low profile solid penetrating probe
end. During this entire transition, the catheter maintains its cylindrical
shape and diameter.
Accordingly it is seen heretofore and in the appended claims that this
invention has advanced the state of the art with those novel features
defined in the claims for examplifying the nature and spirit of the
invention.
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