IE20040535U1 - A guide wire for use with a catheter - Google Patents
A guide wire for use with a catheter Download PDFInfo
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- IE20040535U1 IE20040535U1 IE2004/0535A IE20040535A IE20040535U1 IE 20040535 U1 IE20040535 U1 IE 20040535U1 IE 2004/0535 A IE2004/0535 A IE 2004/0535A IE 20040535 A IE20040535 A IE 20040535A IE 20040535 U1 IE20040535 U1 IE 20040535U1
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- guide wire
- distal portion
- central
- distal
- minor
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- 238000005452 bending Methods 0.000 claims abstract description 35
- 239000000463 material Substances 0.000 claims description 34
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- 238000000034 method Methods 0.000 claims description 12
- 229920003023 plastic Polymers 0.000 claims description 8
- 239000004033 plastic Substances 0.000 claims description 8
- 239000010935 stainless steel Substances 0.000 claims description 8
- 229910001220 stainless steel Inorganic materials 0.000 claims description 8
- 239000000203 mixture Substances 0.000 claims description 6
- 229910001260 Pt alloy Inorganic materials 0.000 claims description 4
- BASFCYQUMIYNBI-UHFFFAOYSA-N platinum Chemical compound [Pt] BASFCYQUMIYNBI-UHFFFAOYSA-N 0.000 claims description 4
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- 238000005476 soldering Methods 0.000 claims description 3
- PCHJSUWPFVWCPO-UHFFFAOYSA-N gold Chemical compound [Au] PCHJSUWPFVWCPO-UHFFFAOYSA-N 0.000 claims description 2
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- 229910052737 gold Inorganic materials 0.000 claims description 2
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- 229910052697 platinum Inorganic materials 0.000 claims description 2
- GUVRBAGPIYLISA-UHFFFAOYSA-N tantalum Chemical compound [Ta] GUVRBAGPIYLISA-UHFFFAOYSA-N 0.000 claims description 2
- 229910052715 tantalum Inorganic materials 0.000 claims description 2
- 230000002792 vascular Effects 0.000 abstract description 22
- 210000004204 Blood Vessels Anatomy 0.000 description 9
- 229910000679 solder Inorganic materials 0.000 description 4
- 210000000748 cardiovascular system Anatomy 0.000 description 3
- 238000007493 shaping process Methods 0.000 description 3
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- UIMGJWSPQNXYNK-UHFFFAOYSA-N azane;titanium Chemical class N.[Ti] UIMGJWSPQNXYNK-UHFFFAOYSA-N 0.000 description 1
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Abstract
ABSTRACT A guide wire (1) for use with a catheter for accessing a remote site in the venal or other system of the body of a human or animal subject comprises a core wire (2) extending from a proximal end (5) to a distal end (6). The core wire (2) terminates at the distal end (6) in a distal portion (16) which is of rectangular transverse cross- section defining a pair of opposite major surfaces ( 18,19) and minor surfaces (20,21). The distal portion (16) also defines a central major plane (24) which lies between the major surfaces (18,19) and bisects the minor surfaces (20,2l) and a central minor plane (25) which lies between the minor surfaces (20, 21) and bisects the major surfaces (18,19). An alignment portion (27) for aligning the distal end (6) with a branched vessel of the Vascular system is formed in the distal portion (16) by bending the distal portion (16) in the central major plane (24) to form a curved portion (28) from which the alignment portion (27) extends, the curved portion 28 and the alignment portion (27) lying in the central minor plane (24). By bending the distal portion (16) in its central major plane, the column strength of the guide wire (1) is such as to minimise the danger of buckling of the distal portion in the central minor plane (25).
Description
“A guide wire for use with a catheter”
The present invention relates to a guide wire for use in a surgical or other procedure
for accessing a remote site in the body of a human or animal subject, and in
particular though not limited to a guide wire for use with a catheter. The invention
also relates to a method for forming a guide wire, and the invention also relates to a
catheter and the guide wire in combination, and to the guide wire for accessing a
remote site in the body of a human or animal subject.
Guide wires for locating a distal end of a catheter in a remote site in the body of a
human or animal subject are known. Such guide wires are commonly used for
guiding a catheter along narrow blood vessels to a site in the cardiovascular system
of the subject for enabling cardiovascular procedures to be carried out. Typically,
the guide wire is introduced through a cannula into a suitable blood vessel in the
thigh or arm of the subject and is passed through the blood vessels to the desired
site in the cardiovascular system. Once the guide wire has reached the desired site,
the catheter is then advanced over the guide wire to the site. Guide wires are also
extensively used to guide a catheter to other sites in the vascular system, and also
to sites in the renal system, as well as to other sites in human and animal subjects
through other systems.
Due to the relatively narrow diameter of the blood vessels through which the guide
wire has to pass, and in particular, due to the tortuous nature of the blood vessels of
the vascular and other systems, and the number of branching blood vessels through
which the guide wire must pass, it is essential that the guide wire be of a
construction which facilitates easy alignment of the guide wire with a desired one of
branching blood vessels as the guide wire is being advanced through the vascular or
other system, so that further urging of the guide wire results in the guide wire
entering the desired branched vessel, and passing therethrough.
Various attempts have been made to provide a guide wire which can readily easily
be aligned with and urged into a branching blooc vessel. For example, U.S. Patent
OPEN TO PUBHC ENSPECTEUN
Specification No. 5,365,942 of Shank discloses a guide wire which comprises a core
wire, the distal portion of which is flattened for facilitating manual bending of the
distal portion of the guide wire by a surgeon or paramedic prior to entry of the guide
wire into the body of the subject. This allows the distal portion to be bent for
offsetting the distal tip of the guide wire, so that as the guide wire is being advanced
through, for example, the vascular system, by rotating the guide wire the offset distal
tip can be aligned with a branching blood vessel into and through which the guide
wire is to be passed. Thus, further urging of the guide wire into the vascular system
causes the guide wire to enter the branched vessel. In the disclosure of Shank the
flattening of the distal portion of the core wire facilitates bending of the core wire out
of the plane of the flattened portion. However, the flattening of the distal portion
tends to reduce the column strength of the core wire, and in turn the guide wire, thus
leaving the guide wire prone to buckling as it is being urged from a vessel into a
branching vessel. Such buckling after the distal end has been entered into the
branched vessel results in the distal end being withdrawn from the branched vessel
as the guide wire is further urged into the vascular system. Additionally, such
buckling can lead to kinking of the guide wire, which in general renders the guide
wire unusable.
There is therefore a need for a guide wire for use in a surgical or other procedure for
accessing a remote site in the body of a human or animal subject which overcomes
this problem.
The present invention is directed towards providing such a guide wire, and the
invention is also directed towards providing a catheter and guide wire combination,
and the invention is also directed towards providing a method for forming a guide
wire which overcomes the problems of prior art guide wires. The invention is further
directed towards a guide wire for use in accessing a remote site in the body of a
human or animal subject.
According to the invention there is provided an elongated guide wire for use in a
surgical or other procedure for accessing a remote site in the body of a human or
FE;-‘040535
animal subject, the guide wire defining a longitudinally extending central axis, and
extending axially between a distal end for accessing the remote site, and a spaced
apart proximal end, a distal portion of the guide wire adjacent the distal end thereof
being of substantially rectangular transverse cross—section defining a pair of spaced
apart major surfaces, and a pair of spaced apart minor surfaces extending between
the major surfaces, the distal portion further defining a central major plane lying
intermediate the major surfaces and bisecting the minor surfaces, and a central
minor plane lying intermediate the minor surfaces and bisecting the major surfaces,
wherein the distal portion is bent into a curved configuration in the central major
plane for forming an alignment portion lying in the central major plane and extending
from the bend at an angle greater than zero relative to the central axis for facilitating
guiding of the guide wire into a branched vessel of the subject.
In one embodiment of the invention the alignment portion extends relative to the
central axis at an angle up to 90°.
In another embodiment of the invention the alignment portion extends relative to the
central axis at an angle up to 60°.
in a further embodiment of the invention the alignment portion extends relative to the
central axis at an angle up to 45°.
In a still further embodiment of the invention the alignment portion extends relative to
the central axis at an angle up to 30°.
in one embodiment of the invention the alignment portion extends relative to the
central axis at an angle in the range of 30° to 90°.
Preferably, the distal portion of the guide wire is of a material for retaining the distal
portion in the curved configuration formed by the bend. Advantageously, the distal
portion of the guide wire is of dimensions for retaining the distal portion in the curved
configuration formed by the bend.
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In one embodiment of the invention the distal portion of the guide wire is bendable in
the central minor plane thereof for facilitating bending of the distal portion with at
least a part of the alignment portion bent out of the central major plane for facilitating
guiding of the guide wire into a branched vessel of the subject. Preferably, the distal
portion of the guide wire is bendable in the central minor plane thereof for facilitating
bending of the distal portion with the alignment portion bent out of the central major
plane for facilitating guiding of the guide wire into a branched vessel of the subject.
in one embodiment of the invention the distal portion of the guide wire is of material
for facilitating manual bending of the distal portion in the central minor plane thereof.
Advantageously, the distal portion of the guide wire is dimensioned for facilitating
manual bending of the distal portion in the central minor plane thereof.
In another embodiment of the invention the distal portion of the guide wire is of
stainless steel material.
Preferably, the major surfaces of the distal portion of the guide wire converge
towards the distal end. Advantageously, the minor surfaces of the distal portion of
the guide wire diverge towards the distal end. Alternatively, the minor surfaces of
the distal portion of the guide wire are parallel to each other.
in one embodiment of the invention a reinforcing means is provided on the distal
portion of the guide wire for minimising bending of the distal portion in the central
minor plane thereof. Preferably, the reinforcing means extending along at least a
portion of the distal portion of the guide wire from a proximal end of the distal portion.
Advantageously, the reinforcing means extends along at least a part of the alignment
portion, and ideally, the reinforcing means terminates at a location spaced apart from
the distal end of the alignment portion.
In one embodiment of the invention the reinforcing means is located to coincide
substantially with the central minor plane defined by the distal portion.
in another embodiment of the invention the reinforcing means comprises an
elongated reinforcing member extending along one of the major surfaces of the
distal portion.
In one embodiment of the invention the guide wire comprises an elongated core wire
extending from the proximal end to the distal portion.
In another embodiment of the invention the core wire terminates in the distal portion.
In a further embodiment of the invention the distal portion of the guide wire is
integrally formed with the core wire.
Preferably, the distal portion of the guide wire is formed from the core wire.
Alternatively, the distal portion of the guide wire is formed separately from the core
wire, and is secured thereto.
In one embodiment of the invention the distal portion of the guide wire terminates in
a bulbous portion at the distal end of the guide wire for facilitating guiding of the
guide wire through vessels of the subject without damaging the vessels. Preferably,
the bulbous portion is radiused. Advantageously, the bulbous portion defines the
distal end of the guide wire and defines a hemispherical distal end.
In another embodiment of the invention the guide wire comprises a sleeve extending
from the bulbous portion in a proximal direction and the core wire extends through
the sleeve.
Preferably, the sleeve extends along the core wire in the proximal direction beyond
the distal portion of the guide wire. Advantageously, the sleeve terminates at a
location intermediate the distal portion and the proximal end of the guide wire.
Ideally, one end of the sleeve is secured to the bulbous portion of the guide wire,
’E040535
and the other end of the sleeve is secured to the core wire.
In one embodiment of the invention the sleeve is secured to the guide wire by
soldering.
In another embodiment of the invention the sleeve is of transverse cross—section, the
outer periphery of which substantially coincides with the outer periphery defined by
the transverse cross-section of the bulbous portion.
In another embodiment of the invention the distal end of the sleeve is of a
radiopaque material. Preferably, the sleeve is of a radiopaque material.
In one embodiment of the invention the sleeve is selected from one or more of the
following metals:
platinum,
platinum alloy,
gold,
tantalum.
in another embodiment of the invention the sleeve comprises a helically wound coil.
Preferably, the sleeve comprises a tightly wound helical coil.
Alternatively, or additionally, the sleeve is of a plastics material.
In one embodiment of the invention the sleeve is provided in at least two
longitudinally extending sections, one of which is of plastics material, and the other
of a tightly wound helical coil.
Additionally, the invention provides a guide wire according to the invention for use in
accessing a remote site in the body of a human or animal subject.
The invention also provides in combination a catheter for use in a surgical or other
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procedure for accessing a remote site in the body of a human or animal subject and
the elongated guide wire according to the invention.
Further the invention provides in combination a catheter for use in a surgical or other
procedure for accessing a remote site in the body of a human or animal subject, and
an elongated guide wire, the guide wire defining a longitudinally extending central
axis, and extending axially between a distal end for accessing the remote site, and a
spaced apart proximal end, a distal portion of the guide wire adjacent the distal end
thereof being of substantially rectangular transverse cross-section defining a pair of
spaced apart major surfaces, and a pair of spaced apart minor surfaces extending
between the major surfaces, the distal portion further defining a central major plane
lying intermediate the major surfaces and bisecting the minor surfaces, and a central
minor plane lying intermediate the minor surfaces and bisecting the major surfaces,
wherein the distal portion is bent into a curved configuration in the central major
plane for forming an alignment portion lying in the central major plane and extending
from the bend at an angle greater than zero relative to the central axis for facilitating
guiding of the guide wire into a branched vessel of the subject.
The invention also provides a method for forming an elongated guide wire for use in
a surgical or other procedure for accessing a remote site in the body of a human or
animal subject, the method comprising the steps of:
forming the distal portion of the guide wire of substantially rectangular
transverse cross-section defining a pair of spaced apart major surfaces, and a pair of
spaced apart minor surfaces extending between the major surfaces, the distal
portion further defining a central major plane lying intermediate the major surfaces
and bisecting the minor surfaces, and a central minor plane lying intermediate the
minor surfaces and bisecting the major surfaces, and
bending the distal portion into a curved configuration in the central major
plane for forming an alignment portion lying in the central major plane and extending
from the bend at an angle greater than zero relative to the central axis for facilitating
guiding of the guide wire into a branched vessel of the subject.
lE040535
The advantages of the invention are many. The guide wire according to the
invention has good column strength, and in particular, has significantly greater
column strength than can be provided from guide wires in which the core wire
terminates in a flattened distal portion. By virtue of the fact that the distal portion is
curved in the central major plane defined by the distal portion, the column strength of
the guide wire is significantly enhanced. Accordingly, when the alignment portion of
the distal portion is urged into a branched vessel, further urging of the guide wire into
the vascular or other system causes the guide wire to be urged through the
branched vessel without any danger of buckling of the guide wire.
By providing the distal portion bent to form the curvature in the central major plane,
the bending of which is typically factory formed, in general, there should be no need
for further bending of the distal portion by a surgeon. Accordingly, the distal portion
may be provided to be of greater rectangular transverse cross-section than would
otherwise be provided. However, where desired, the distal portion may be of
rectangular transverse cross-section such as to permit bending of the distal portion
in the central minor plane defined by the distal portion, and such bending in the
central minor plane would be carried out by a surgeon or paramedic prior to the
guide wire being entered into the vascular or other system of the subject. However,
even where the transverse cross-section of the distal portion of the guide wire is
such as to facilitate subsequent bending of the distal portion in the central minor
plane defined by the distal portion, the fact that the distal portion is bent in the
central major plane defined by the distal portion provides sufficient column strength
to avoid buckling of the guide wire adjacent the distal portion.
Additionally, by providing the distal portion of the guide wire to be of rectangular
cross-section, which is suitable for manual bending in the central minor plane
defined by the distal portion, as well as the curved bend formed in the central major
plane of the distal portion, the distal portion may also be subsequently manually bent
in the central minor plane defined by the distal portion by a surgeon or paramedic
prior to entry of the guide wire into the vascular or other system of the subject for
further facilitating alignment of the alignment portion of the guide wire with a
IEO40535
branched vessel as the guide wire is being advanced through the vascular or other
system. Accordingly, the guide wire according to the invention can be provided for
facilitating the forming of the alignment portion in three dimensions.
Indeed, an advantage of providing the distal portion of transverse cross-section
suitable for facilitating subsequent bending of the distal portion in the central minor
plane defined by the distal portion is that when the distal portion is bent in both its
central major and central minor planes, the distal portion can be provided to act with
a corkscrew or helical type effect as it is being urged through the vascular or other
system of the subject.
The invention will be more clearly understood from the following description of some
preferred embodiments thereof, which are given by way of example only, with
reference to the accompanying drawings, in which:
Fig. 1 is a partly cut-away side elevational view of a guide wire according to
the invention for use with a catheter,
Fig. 2 is a partly cutaway plan view of the guide wire of Fig. 1,
Fig. 3 is an enlarged view of a portion of the guide wire of Fig. 1,
Fig. 4 is a perspective view of a portion of the guide wire of Fig. 1,
Fig. Sis a plan view of the portion of the guide wire of Fig. 4,
Fig. 6 is a side elevational view of the portion of the guide wire of Fig. 4,
Fig. 7 is an end elevational view of the portion of the guide wire of Fig. 4,
Fig. 8 is a perspective view of a portion of a guide wire according to another
embodiment of the invention,
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Fig. 9 is a plan view of the portion of the guide wire of Fig. 8,
Fig. 10 is a perspective view of a portion of a guide wire according to another
embodiment of the invention,
Fig. 11 is a perspective view similar to Fig. 4 of a portion of a guide wire
according to another embodiment of the invention,
Fig. 12 is a plan view of the portion of the guide wire of Fig. 11,
Fig. 13 is a side elevational view of the portion of the guide wire of Fig. 11,
and
Fig. 14 is an end view of the portion of the guide wire of Fig. 11.
Referring to the drawings, and initially to Figs. 1 to 7 thereof, there is illustrated a
guide wire according to the invention indicated generally by the reference numeral 1
for use with a catheter (not shown) for guiding the catheter to a remote site in the
body of a human or animal subject. The guide wire 1 according to this embodiment
of the invention is particularly suitable for accessing a remote site in the
cardiovascular system of a subject for in turn guiding the catheter (not shown) to the
remote site. Although, it will be readily apparent to those skilled in the art that the
guide wire 1 is suitable for accessing any remote site in the body of a human or
animal subject, be it in the vascular system or otherwise. For example, the guide
wire 1 is suitable for accessing a renal system, the neuro-vascular system, the
fallopian tubes and other such vessels and sites.
The guide wire 1 comprises an elongated core wire 2 which in this embodiment of
the invention is of stainless steel, and which defines a longitudinally extending
central axis 4 and extends from a proximal end 5 to a distal end 6. The distal end 6
of the core wire 2 terminates in a bulbous portion 8 of stainless steel, which forms a
’5°405
hemispherical leading end for facilitating guiding of the guide wire 1 through the
vascular system of the subject and for avoiding scarring, rupturing or othenrvise
damaging the vessels of the vascular system through which the guide wire 1 is being
advanced. A sleeve 9, in this embodiment of the invention formed by a tightly wound
helical coil of circular transverse cross-section, and of radiopaque material, namely,
platinum alloy material, extends from the bulbous portion 8 in a proximal direction,
and terminates at a location 10 on the core wire 2. The sleeve 9 is secured to the
distal end 6 of the core wire 2 by solder, and the solder forms the hemispherical
bulbous portion 8. Accordingly, the diameter of the bulbous portion 8 is substantially
similar to the outer diameter of the sleeve 9. The sleeve 9 is also secured to the
core wire 2 at the location 10 by solder.
In this embodiment of the invention, the core wire 2 is of circular transverse cross-
section, and tapers in three stages 11, 12 and 13 to a portion 15 of reduced circular
transverse cross-section. A distal portion 16 of the core wire 2 extends from the
portion 15 to the bulbous portion 8, and is of rectangular transverse cross-section
defining a pair of major surfaces 18 and 19 which are joined by a pair of minor
surfaces 20 and 21. The major surfaces 18 and 19 converge from the portion 15 to
the bulbous portion 8, while the minor surfaces 20 and 21 diverge from the portion
to the bulbous portion 8. The distal portion 16 also defines a central major plane
24 which lies intermediate the major surfaces 18 and 19 and bisects the minor
surfaces 20 and 21, see Fig. 3. A central minor plane 25 is also defined by the distal
portion 16, and lies intermediate the minor surfaces 20 and 21, and bisects the
respective major surfaces 18 and 19.
An alignment portion 27 is pre—formed in the distal portion 16 forfacilitating aligning
of the distal end 6 of the guide wire 1 with a branched blood vessel as the guide wire
1 is being urged through the vascular system of the subject. The alignment portion
27 is formed by bending the distal portion 16 in the central major plane 24 to form a
curved portion 28, from which the alignment portion 27 extends, so that the curved
portion 28 and the alignment portion 27 along with the remainder of the distal portion
all lie in the central major plane 24. In this embodiment of the invention the
IE0405
alignment portion 27 extends from the core wire 2 at an angle 6 relative to the
central axis 4 of approximately 90°, although it is envisaged that the alignment
portion 27 may extend from the core wire 2 at any desired angle 9 relative to the
central axis 4, for example, at an angle 6 of 30°, 45°, 60°, or any other desired angle.
In this embodiment of the invention, the distal portion 16 is of stainless steel and is
formed from the same piece of stainless steel from which the core wire 2 is formed.
The core wire 2 with the distal portion 16 is formed as follows. Initially, the core wire
2 is shaped to form the tapering stages 11, 12 and 13. The distal portion 16 is
initially formed to be of diameter similar to that of the portion 15. The desired
curvature is then formed in the distal portion 16 which will ultimately form the
alignment portion 27, and the curved portion 28 of the distal portion 16. After the
curvature has been formed in the distal portion 16, the distal portion 16 is then
shaped to be of rectangular transverse cross-section with the major surfaces 18 and
19 converging towards the distal end 6, and the minor surfaces 20 and 21 diverging
towards the distal end 6. After completion of the formation of the distal portion 16,
the sleeve 9 is passed over the distal portion 16 and is passed along the core wire 2
to the location 10. The sleeve 9 is then soldered to the distal end 6 of the distal
portion 16 to form the bulbous portion 8, and is soldered to the core wire 2 at the
location 10.
The formation of the curvature in the distal portion 16 may be formed by any suitable
means, for example, bending the distal portion 16 around a suitably shaped jig. The
shaping of the distal portion 16 to be of rectangular transverse cross-section may be
carried out by any suitable process, for example, by pressing in a suitable press tool
or by the use of cam rollers.
Alternatively, the distal portion 16 may be formed separately from the core wire 2,
by, for example, cutting an appropriately curved ribbon from flat stock material, and
using a laser, press tool or electrochemical etch for shaping the distal portion 16 to
be of the appropriate rectangular transverse cross-section. The so formed distal
/E0405
portion 16 would then be soldered, brazed, welded or otherwise secured to the core
wire 2.
Alternatively, offset rollers may be used to create the taper and curvature in one
single press where the distal portion 16 is formed integrally with the wire core 2.
In this embodiment of the invention the stainless steel material of the core wire 2 is
selected, and the dimensioning and shaping of the distal portion 16 is such that the
rectangular transverse cross—section of the distal portion 16 permits manual bending
of the distal portion 16 in the central minor plane 25 for providing two degrees of
curvature in the distal portion 16, namely, the curvature which forms the curved
portion 28 of the distal portion 16 in the central major plane 24, and the curvature of
the distal portion 16 in the central minor plane 25. By providing the distal portion 16
to be manually bendable in the central minor plane 25, a surgeon can manually bend
the distal portion 16 in the central minor plane 25 prior to entry of the guide wire 2
into the subject, thereby providing all or a part of the alignment portion 27 bent in
both the central major and central minor planes 24 and 25, thereby further facilitating
alignment of the distal end 6 with a branched vessel as the guide wire 1 is being
advanced through the vascular system of the subject.
While in Figs. 1 to 7 the guide wire 1 has been described with the distal portion 16
bent in the central major plane 24, so that the alignment portion 27 extends at an
angle 6 of 90° to the central axis 4, it is envisaged that a set of guide wires would be
provided, whereby the respective guide wires of the set would be provided with their
respective alignment portions 27 extending relative to the central axis 4 at different
angles 6 up to 90°. Typical values of the angles 6 would be 30°, 45°, 60° as well as
90°.
in use, depending on the vascular or other system of the subject to be accessed, a
guide wire 1 with the distal portion 16 bent in the central major plane 24 to provide
the alignment portion 27 at the desired angle 6 to the central axis 4 would be
selected. if appropriate, the distal portion 16 would be manually bent by the surgeon
/5040535
or paramedic in the central minor plane 25 in order to provide the distal portion 16,
and in turn the alignment portion 27 with curvature in the central major and the
central minor planes 24 and 25. After the distal portion 16 has been manually bent
in the central minor plane 25, if so desired, the guide wire 1 is then ready for use,
and is urged into and advanced through the vascular system of the subject in
conventional fashion. When the distal end 6 of the guide wire 1 reaches a branched
vessel into which the guide wire 1 is to be urged, the guide wire 1 is rotated by
rotating its proximal end 5 thereof for aligning the alignment portion 27 with the
branched vessel. Further urging of the guide wire 1 into the vascular system thus
urges the distal end 6 of the guide wire 1 into the branched vessel, and further
urging of the guide wire into the vascular system urges the guide wire 1 through the
branched vessel.
Referring now to Figs. 8 and 9, there is illustrated a portion of a guide wire according
to another embodiment of the invention indicated generally by the reference numeral
. The guide wire 30 is substantially similar to the guide wire 1, and similar
components are identified by the same reference numerals. The main difference
between the guide wire 30 and the guide wire 1 is that the bend forming the curved
portion 28 of the distal portion 16 of the guide wire 30 is less acute than the bend
forming the curved portion 28 of the distal portion 16 of the guide wire 1. Othen/vise,
the guide wire 30 is similar to the guide wire 1, and its use is likewise similar.
Referring now to Fig. 10, there is illustrated a portion of a guide wire according to a
further embodiment of the invention, indicated generally by the reference numeral
40. The guide wire 40 is substantially similar to the guide wire 1 and similar
components are identified by the same reference numerals. However, in this
embodiment of the invention only half the distal portion 16 of the guide wire 40 is
illustrated in Fig. 10. The distal portion 16 is bisected along the central major plane
24. The other half of the distal portion 16 is a mirror image of the illustrated portion.
In this embodiment of the invention a reinforcing means provided by a reinforcing
member in the form of an elongated reinforcing plate 41 extends along each major
surface 18 and 19 of the distal portion 16 for increasing the column strength of the
distal portion 16, and thus minimising inadvertent bending of the distal portion 16 in
the central minor plane 25. The reinforcing plates 41 extend along the major
surfaces 18 and 19 and coincide with the central minor plane 25 in the distal portion
16 prior to the curved portion 28. The reinforcing plates 41 may be formed integrally
with the distal portion 16, or may be formed separately and welded or brazed to the
distal portion 16. The advantage of providing the reinforcing plates 41 is that since
the reinforcing plates 41 lie in the central minor plane 25, they act to enhance the
rigidity of the distal portion 16 against bending or buckling in the central minor plane
as the guide wire 1 is being urged through the vascular system of the subject.
Indeed, in general, it is envisaged that the reinforcing plates 41 will be of material
and will be dimensioned for facilitating manual bending of the distal portion 16 in the
central minor plane by a surgeon or paramedic, so that the distal portion 16 could be
bent in both the central major and central minor planes 24 and 25, the bend in the
central minor plane would be typically formed adjacent the distal end 6 to provide the
alignment portion 27 with a type of corkscrew action. While typically the bending of
the distal portion 16 in the central minor plane 25 would be carried out manually prior
to use of the device by a surgeon or paramedic, it will be appreciated that bending of
the distal portion in the central minor plane 25 could be carried out during
manufacture of the guide wire.
Referring now to Figs. 11 to 14, there is illustrated a portion of a guide wire
according to a still further embodiment of the invention, indicated generally by the
reference numeral 50. The guide wire 50 is substantially similar to the guide wire 1
and similar components are identified by the same reference numerals. The main
difference between the guide wire 50 and the guide wire 1 is in the distal portion 16.
In this embodiment of the invention the distal portion 16 is substantially flat, rather
than tapering, as in the case of the guide wire 1. An initial tapering portion 51 rapidly
tapers the core wire 2 from the portion 15 to the relatively flat distal portion 16.
Othenivise, the guide wire 50 is similar to the guide wire 1.
While the core wire, the distal portion, the bulbous portion and the sleeve of the
guide wires described with reference to Figs. 1 to 14 have been described as being
of specific materials, it is envisaged that the core wire, the distal portion, the bulbous
portion and the sleeve may be of any other desired or suitable materials, and in
certain cases, it is envisaged that the core wire may be of nickel titanium alloy, or
may be of a polymer material or a plastics material. it is also envisaged that the
sleeve may be of plastics material, or portions of the sleeve may be of a plastics
material. In cases where the sleeve is provided of a plastics material it is envisaged
that the sleeve would be provided as a tubular sleeve.
It is also envisaged that instead of the sleeve being of radiopaque material, where it
is desired to have a portion of the guide wire adjacent its distal end to be
radiopaque, it is envisaged that the bulbous portion may be separately formed of a
radiopaque material, for example, platinum alloy, and brazed to the core wire 2 at
the distal end 6 thereof and to the sleeve.
Needless to say, the distal portion may be of a radiopaque material.
While the distal portion has been described as being of rectangular transverse cross-
section, the cross—section of the distal portion may not be exactly rectangular, for
example, the minor surfaces may be convex.
While the bulbous portion at the distal end of the guide wire has been described as
being formed by solder of the solderjoint joining the sleeve to the core wire, the
bulbous portion may be formed by any other material, for example, a metal used in
brazing or welding the sleeve to the core wire, or by an adhesive used in bonding the
sleeve to the core wire. Alternatively, the bulbous portion could be separately
formed and secured to the core wire and the sleeve by any suitable securing means,
such as soldering, welding, brazing, bonding by a suitable adhesive, or the like.
As already discussed, the distal portion may be formed from the material of the core
wire, or it may be formed separately of the core wire and suitably secured to the core
wire after being formed. Where the distal portion is formed separately and
subsequently secured to the core wire, the material of the distal portion may be the
same or different to the material of the core wire.
Claims (75)
1. An elongated guide wire for use in a surgical or other procedure for accessing a remote site in the body of a human or animal subject, the guide wire defining a longitudinally extending central axis, and extending axially between a distal end for accessing the remote site, and a spaced apart proximal end, a distal portion of the guide wire adjacent the distal end thereof being of substantially rectangular transverse cross-section defining a pair of spaced apart major surfaces, and a pair of spaced apart minor surfaces extending between the major surfaces, the distal portion further defining a central major plane lying intermediate the major surfaces and bisecting the minor surfaces, and a central minor plane lying intermediate the minor surfaces and bisecting the major surfaces, characterised in that the distal portion is bent into a curved configuration in the central major plane for forming an alignment portion lying in the central major plane and extending from the bend at an angle greater than zero relative to the central axis for facilitating guiding of the guide wire into a branched vessel of the subject.
2. A guide wire as claimed in Claim 1 characterised in that the alignment portion extends relative to the central axis at an angle up to 90°.
3. A guide wire as claimed in Claim 2 characterised in that the alignment portion extends relative to the central axis at an angle up to 60°.
4. A guide wire as claimed in Claim 3 characterised in that the alignment portion extends relative to the central axis at an angle up to 45°.
5. A guide wire as claimed in Claim 4 characterised in that the alignment portion extends relative to the central axis at an angle up to 30°.
6. A guide wire as claimed in Claim 1 or 2 characterised in that the alignment portion extends relative to the central axis at an angle in the range of 30° to 90°.
7. A guide wire as claimed in any preceding claim characterised in that the IEO405 distal portion of the guide wire is of a material for retaining the distal portion in the curved configuration formed by the bend.
8. A guide wire as claimed in any preceding claim characterised in that the distal portion of the guide wire is of dimensions for retaining the distal portion in the curved configuration formed by the bend.
9. A guide wire as claimed in any preceding claim characterised in that the distal portion of the guide wire is bendable in the central minor plane thereof for facilitating bending of the distal portion with at least a part of the alignment portion bent out of the central major plane for facilitating guiding of the guide wire into a branched vessel of the subject.
10. A guide wire as claimed in any preceding claim characterised in that the distal portion of the guide wire is bendable in the central minor plane thereof for facilitating bending of the distal portion with the alignment portion bent out of the central major plane for facilitating guiding of the guide wire into a branched vessel of the subject.
11. A guide wire as claimed in Claim 9 or 10 characterised in that the distal portion of the guide wire is of material for facilitating manual bending of the distal portion in the central minor plane thereof.
12. A guide wire as claimed in any of Claims 9 to 11 characterised in that the distal portion of the guide wire is dimensioned for facilitating manual bending of the distal portion in the central minor plane thereof.
13. A guide wire as claimed in any preceding claim characterised in that the distal portion of the guide wire is of stainless steel material.
14. A guide wire as claimed in any preceding claim characterised in that the major surfaces of the distal portion of the guide wire converge towards the distal ,Eo4o5 end.
15. A guide wire as claimed in any preceding claim characterised in that the minor surfaces of the distal portion of the guide wire diverge towards the distal end.
16. A guide wire as claimed in any of Claims 1 to 14 characterised in that the minor surfaces of the distal portion of the guide wire are parallel to each other.
17. A guide wire as claimed in any preceding claim characterised in that a reinforcing means is provided on the distal portion of the guide wire for minimising bending of the distal portion in the central minor plane thereof.
18. A guide wire as claimed in Claim 17 characterised in that the reinforcing means extending along at least a portion of the distal portion of the guide wire from a proximal end of the distal portion.
19. A guide wire as claimed in Claim 17 or 18 characterised in that the reinforcing means extends along at least a part of the alignment portion.
20. A guide wire as claimed in any of Claims 17 to 19 characterised in that the reinforcing means terminates at a location spaced apart from the distal end of the alignment portion.
21. A guide wire as claimed in any of Claims 17 to 20 characterised in that the reinforcing means is located to coincide substantially with the central minor plane defined by the distal portion.
22. A guide wire as claimed in any of Claims 17 to 21 characterised in that the reinforcing means comprises an elongated reinforcing member extending along one of the major surfaces of the distal portion.
23. A guide wire as claimed in any preceding claim characterised in that the 150405 guide wire comprises an elongated core wire extending from the proximal end to the distal portion.
24. A guide wire as claimed in Claim 23 characterised in that the core wire terminates in the distal portion.
25. A guide wire as claimed in Claim 24 characterised in that the distal portion of the guide wire is integrally formed with the core wire.
26. A guide wire as claimed in Claim 24 or 25 characterised in that the distal portion of the guide wire is formed from the core wire.
27. A guide wire as claimed in Claim 24 characterised in that the distal portion of the guide wire is formed separately from the core wire, and is secured thereto.
28. A guide wire as claimed in any of Claims 23 to 27 characterised in that the distal portion of the guide wire terminates in a bulbous portion at the distal end of the guide wire for facilitating guiding of the guide wire through vessels of the subject without damaging the vessels.
29. A guide wire as claimed in Claim 28 characterised in that the bulbous portion is radiused.
30. A guide wire as claimed in Claim 28 or 29 characterised in that the bulbous portion defines the distal end of the guide wire and defines a hemispherical distal end.
31. A guide wire as claimed in any of Claims 28 to 30 characterised in that the guide wire comprises a sleeve extending from the bulbous portion in a proximal direction and the core wire extends through the sleeve.
32. A guide wire as claimed in Claim 31 characterised in that the sleeve extends 150405 along the core wire in the proximal direction beyond the distal portion of the guide wire.
33. A guide wire as claimed in Claim 31 or 32 characterised in that the sleeve terminates at a location intermediate the distal portion and the proximal end of the guide wire.
34. A guide wire as claimed in any of Claims 31 to 33 characterised in that one end of the sleeve is secured to the bulbous portion of the guide wire, and the other end of the sleeve is secured to the core wire.
35. A guide wire as claimed in any of Claims 31 to 34 characterised in that the sleeve is secured to the guide wire by soldering.
36. A guide wire as claimed in any of Claims 31 to 35 characterised in that the sleeve is of transverse cross—section, the outer periphery of which substantially coincides with the outer periphery defined by the transverse cross—section of the bulbous portion.
37. A guide wire as claimed in any of Claims 30 to 35 characterised in that the distal end of the sleeve is of a radiopaque material.
38. A guide wire as claimed in any of Claims 31 to 37 characterised in that the sleeve is of a radiopaque material.
39. A guide wire as claimed in any of Claims 31 to 38 characterised in that the sleeve is selected from one or more of the following metals: platinum, platinum alloy, gold, tantalum. IE0405
40. A guide wire as claimed in any of Claims 31 to 39 characterised in that the sleeve comprises a helically wound coil.
41. A guide wire as claimed in any of Claims 31 to 40 characterised in that the sleeve comprises a tightly wound helical coil.
42. A guide wire as claimed in any of Claims 31 to 41 characterised in that the sleeve is of a plastics material.
43. A guide wire as claimed in any of Claims 31 to 42 characterised in that the sleeve is provided in at least two longitudinally extending sections, one of which is of plastics material, and the other of a tightly wound helical coil.
44. A guide wire as claimed in any preceding claim for use in accessing a remote site in the body of a human or animal subject.
45. In combination a catheter for use in a surgical or other procedure for accessing a remote site in the body of a human or animal subject, and an elongated guide wire, characterised in that the elongated guide wire is a guide wire as claimed in any preceding claim.
46. In combination a catheter for use in a surgical or other procedure for accessing a remote site in the body of a human or animal subject, and an elongated guide wire, the guide wire defining a longitudinally extending central axis, and extending axially between a distal end for accessing the remote site, and a spaced apart proximal end, a distal portion of the guide wire adjacent the distal end thereof being of substantially rectangular transverse cross-section defining a pair of spaced apart major surfaces, and a pair of spaced apart minor surfaces extending between the major surfaces, the distal portion further defining a central major plane lying intermediate the major surfaces and bisecting the minor surfaces, and a central minor plane lying intermediate the minor surfaces and bisecting the major surfaces, characterised in that the distal portion is bent into a curved configuration in the 150405 central major plane for forming an alignment portion lying in the central major plane and extending from the bend at an angle greater than zero relative to the central axis for facilitating guiding of the guide wire into a branched vessel of the subject.
47. A method for forming an elongated guide wire for use in a surgical or other procedure for accessing a remote site in the body of a human or animal subject, the method comprising the steps of: forming the distal portion of the guide wire of substantially rectangular transverse cross-section defining a pair of spaced apart major surfaces, and a pair of spaced apart minor surfaces extending between the major surfaces, the distal portion further defining a central major plane lying intermediate the major surfaces and bisecting the minor surfaces, and a central minor plane lying intermediate the minor surfaces and bisecting the major surfaces, and bending the distal portion into a curved configuration in the central major plane for forming an alignment portion lying in the central major plane and extending from the bend at an angle greater than zero relative to the central axis for facilitating guiding of the guide wire into a branched vessel of the subject.
48. A method as claimed in Claim 47 characterised in that the alignment portion extends relative to the central axis at an angle up to 90°.
49. A method as claimed in Claim 48 characterised in that the alignment portion extends relative to the central axis at an angle up to 60°.
50. A method as claimed in Claim 49 characterised in that the alignment portion extends relative to the central axis at an angle up to 45°.
51. A method as claimed in Claim 50 characterised in that the alignment portion extends relative to the central axis at an angle up to 30°.
52. A method as claimed in Claim 47 or 48 characterised in that the alignment portion extends relative to the central axis at an angle in the range of 30° to 90°. IEO~’iO5
53. A method as claimed in any of Claims 47 to 51 characterised in that the distal portion of the guide wire is formed from a material for retaining the distal portion in the curved configuration formed by the bend.
54. A method as claimed in any of Claims 47 to 52 characterised in that the distal portion of the guide wire is formed of dimensions for retaining the distal portion in the curved configuration formed by the bend.
55. A method as claimed in any of Claims 47 to 54 characterised in that the distal portion of the guide wire is bendable in the central minor plane thereof for facilitating bending of the distal portion with at least a part of the alignment portion bent out of the central major plane for facilitating guiding of the guide wire into a branched vessel of the subject.
56. A method as claimed in Claim 55 characterised in that the distal portion of the guide wire is formed from a material for facilitating manual bending of the distal portion in the central minor plane thereof.
57. A method as claimed in Claim 55 or 56 characterised in that the distal portion of the guide wire is formed of dimensions which facilitate manual bending of the distal portion in the central minor plane thereof.
58. A method as claimed in any of Claims 47 to 57 characterised in that the distal portion of the guide wire is formed from stainless steel material.
59. A method as claimed in any of Claims 47 to 58 characterised in that the distal portion of the guide wire is formed with the major surfaces thereof converging towards the distal end.
60. A method as claimed in any of Claims 47 to 59 characterised in that the distal portion of the guide wire is formed with the minor surfaces thereof diverging towards 56405 the distal end.
61. A method as claimed in any of Claims 47 to 60 characterised in that a reinforcing means is provided on the distal portion of the guide wire for minimising bending of the distal portion in the central minor plane thereof.
62. A method as claimed in Claim 61 characterised in that the reinforcing means is provided for extending along at least a portion of the distal portion of the guide wire from a proximal end of the distal portion.
63. A method as claimed in Claim 61 or 62 characterised in that the reinforcing means is provided for extending along at least a part of the alignment portion.
64. A method as claimed in any of Claims 61 to 63 characterised in that the reinforcing means is provided to terminate at a location spaced apart from the distal end of the alignment portion.
65. A method as claimed in any of Claims 61 to 64 characterised in that the reinforcing means is located to coincide substantially with the central minor plane defined by the distal portion.
66. A method as claimed in any of Claims 61 to 65 characterised in that the reinforcing means is provided by an elongated reinforcing member extending along one of the major surfaces of the distal portion.
67. A method as claimed in any of Claims 47 to 66 characterised in that the guide wire is formed with an elongated core wire extending from the proximal end to the distal portion.
68. A method as claimed in Claim 67 characterised in that the distal portion of the guide wire is integrally formed with the core wire. 150405
69. A method as claimed in Claim 67 or 68 characterised in that the distal portion of the guide wire is formed from the core wire.
70. A method as claimed in Claim 67 characterised in that the distal portion of the guide wire is formed separately from the core wire, and is secured thereto.
71. A method as claimed in any of Claims 67 to 70 characterised in that the distal portion of the guide wire is terminated in a bulbous portion at the distal end of the guide wire for facilitating guiding of the guide wire through vessels of the subject without damaging vessels.
72. A method as claimed in Claim 71 characterised in that the bulbous portion is radiused.
73. A method as claimed in Claim 71 or 72 characterised in that the bulbous portion of the guide wire defines the distal end of the guide wire and defines a spherical distal end.
74. A method as claimed in any of Claims 71 to 73 characterised in that a sleeve is provided extending from the bulbous portion in a proximal direction along the guide wire, and the core wire extends through the sleeve.
75. A method as claimed in Claim 74 characterised in that the sleeve terminates at a location intermediate the distal portion and the proximal end of the guide wire. F.F. GORMAN & CO.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
IEIRELAND07/08/2003S2003/0585 |
Publications (2)
Publication Number | Publication Date |
---|---|
IE20040535U1 true IE20040535U1 (en) | 2005-02-23 |
IES84007Y1 IES84007Y1 (en) | 2005-09-21 |
Family
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