Catheter with angled ball tip for fallopian tube access and method

A catheter for fallopian tube access comprising an elongated catheter body having a proximal region, a distal end and an elongated passage extending from the proximal region to the distal end. The elongated passage terminates in a distal opening at the distal end. The catheter body has an enlarged distal body portion and the distal opening is on the distal body portion. The distal body portion has a deflecting surface in the elongated passage adjacent the distal opening for directing a member or fluid passed through the elongated passage out of the distal opening along a path having a component which extends laterally of the catheter body.

BACKGROUND OF THE INVENTION 
It is sometimes necessary or desirable to gain access to a fallopian tube 
for purposes of examination or carrying out a medical procedure. For 
example, the examination may be carried out with a flexible endoscope and 
the medical procedure may include depositing genetic material or infusing 
medication, dye or a contrast media into the fallopian tube. 
A catheter can be used to gain access to a fallopian tube. To accomplish 
this, the catheter is inserted through the cervix into the uterus and then 
manipulated to place a distal opening of the catheter in registry with an 
ostium of the fallopian tube. A flexible instrument or fluid can then be 
passed through the catheter and into the fallopian tube. 
One problem with gaining access to a fallopian tube is getting the distal 
opening of the catheter in proper registry with the ostium of the 
fallopian tube. The uterus in a normal, non-distended condition comprises 
two layers of tissue in closely adjacent confronting relationship, and the 
ostium or opening to the fallopian tube is relatively small. Consequently, 
it is difficult to work the catheter through the uterus to precisely the 
correct location and to move the confronting layers of tissue away from 
the ostium with the catheter. Once the catheter is properly positioned 
with the distal opening in registry with the ostium, it is sometimes 
difficult to pass a flexible member through the distal opening and cause 
it to properly enter the fallopian tube. This is the result of the angular 
relationship of the region of the fallopian tube near the ostium in 
relation to the uterus. 
Another problem occurs as a result of the insertion of the catheter through 
the cervix. A conventional catheter with an on-axis distal opening acts 
like a scoop which picks up mucus and debris as the catheter is passed 
through the cervix. This can hinder visualization. 
SUMMARY OF THE INVENTION 
This invention provides a catheter and method which generally overcomes the 
problems identified above and which provides other advantages. With this 
invention, gaining access to a fallopian tube is facilitated and obtaining 
proper registry between the distal opening of the catheter and the ostium 
is made easier. In addition, the catheter and method of this invention can 
more accurately direct a member out of the catheter and into the fallopian 
tube. The distal opening of the catheter of this invention also collects 
less mucus and debris than the on-axis distal opening of the prior art. 
The catheter of this invention preferably includes an elongated catheter 
body having a proximal region, a distal end and an elongated passage 
extending from the proximal region to the distal end. The elongated 
passage terminates in a distal opening at the distal end. 
In order to push tissue away from the region closely adjacent the ostium, 
the catheter body has a distal body portion which is appropriately 
enlarged. For example, the distal body portion may have a larger radial 
dimension than a radial dimension of a region of the catheter body which 
is immediately proximal to the distal body portion. The elongated passage 
extends through the distal body portion. The distal opening and the distal 
end are on the distal body portion. 
To increase the likelihood that the catheter can properly direct a member 
into the fallopian tube, the catheter has a deflecting surface in the 
elongated passage of the catheter body and adjacent the distal opening. 
The deflecting surface directs the member out of the distal opening along 
a path having a component which extends laterally of the catheter body. 
This path is more in alignment with the region of the fallopian tube 
adjacent the ostium than would be provided by a conventional catheter. 
Preferably the distal opening is radially offset from the axis of a major 
portion of the elongated passage proximally of the enlarged distal body 
portion, and the deflection surface is inclined radially to extend toward 
the distal opening. 
To facilitate the pushing of tissue away from the ostium, the distal body 
portion preferably has an outer surface which is convexly curved as viewed 
in longitudinal cross section, and more preferably, the outer surface is 
curved in both axial and radial cross sections. In a preferred 
construction, the distal body portion is generally in the form of at least 
a portion of a ball. 
In a preferred construction, the elongated passage of the catheter body has 
a major portion and a minor portion. The minor portion is in the distal 
body portion and extends laterally outwardly of the major portion. The 
minor portion is at least partially defined by the deflecting surface. The 
distal opening can advantageously face a direction which has a component 
extending laterally of the catheter body, or more specifically, the distal 
opening may lie in a plane which is inclined at an acute angle with 
respect to the axis of the major portion of the elongated passage. This 
offsetting of the distal opening provides a preferential orientation for 
leading into the fallopian tube at the desired angle. Moreover, by making 
the distal opening off-axis in this manner, it collects less mucus and 
debris as the catheter is being inserted through the cervix. 
In order that the distal opening is inclined as desired, it is preferred 
that the distal end form an included angle with a reference plane of from 
about 15.degree. to about 80.degree.. A more preferred range is from about 
50.degree. to about 60.degree., and an angle of about 55.degree. is 
considered optimum. The angular relationship is such that the deflecting 
surface deflects the member or fluid through an angle which is equal to or 
less than an included angle between the distal end and a radial reference 
plane. 
Many features of this invention are adapted for both an everting catheter 
and a non-everting catheter. The everting catheter includes a support tube 
movable longitudinally within the elongated passage of the catheter body 
and a flexible everting element coupled to the catheter body and the 
support tube. The everting element is evertable out of the distal opening 
and is engageable with the deflecting surface so that the deflecting 
surface the deflects the everting element toward the distal opening during 
eversion. 
In the case of a non-everting catheter, the member which is deflected by 
the deflecting surface may be a flexible endoscope or virtually any other 
elongated flexible instrument. In the case of an everting catheter, the 
member directly deflected by the everting surface is the everting element. 
However, any endoscope or instrument which is in or inserted or pulled 
through the everting element or any fluid passing through the everting 
element are also considered to be deflected by the deflecting surface. 
To facilitate reaching an ostium, the catheter body preferably has a distal 
portion which is curved in one direction and a deflecting surface is 
arranged to deflect a member or fluid generally in a second direction 
which is away from the first direction. The catheter body is curved in 
this fashion in the normal or unstressed condition. The distal portion 
preferably forms an included angle of about 30.degree. to about 
165.degree. with a more preferred range being from about 105.degree. to 
about 135.degree.. About 120.degree. is considered optimum. The deflecting 
surface preferably deflects the member or fluid through an angle of from 
about 15.degree. to about 85.degree. with 25.degree. to about 35.degree. 
being more preferred. About 30.degree. is considered optimum. These angles 
better adapt the catheter to reach an ostium. 
With this invention, the length of the curved distal portion can be 
controlled to facilitate reaching an ostium. To accomplish this, the 
straight line distance from the proximal end of the distal portion at the 
axis of the catheter body to the distal end of the catheter body is 
preferably from about 1.5 cm to about 2.5 cm. 
Another feature of this invention is to employ a scope lumen in the 
catheter body. The scope lumen is sized to receive an endoscope, and the 
scope lumen terminates adjacent the distal opening. An endoscope, which 
may be permanent or removable, may be provided in the scope lumen. The 
endoscope in the scope lumen is for observing a zone adjacent the distal 
opening and is primarily for the purpose of determining whether or not the 
member being passed into the fallopian tube has properly left the catheter 
and passed through the distal opening. 
According to one method feature of this invention, a catheter is inserted 
through the cervix into the uterus and is then manipulated to place the 
distal opening in registry with an ostium of a fallopian tube. A flexible 
instrument or a fluid is then passed through the elongated passage to the 
deflecting surface and the deflecting surface deflects the instrument or 
fluid generally cranially through the distal opening and into the 
fallopian tube. When an everting catheter is used, a flexible instrument 
or fluid may passed through the support tube of the everting catheter to 
the everting element and then passed within the everting element and over 
the deflecting surface. 
Another important method feature of this invention is to gain access to a 
fallopian tube of a patient utilizing an everting catheter which has the 
radially enlarged distal body portion. The enlarged distal body portion is 
used to push tissue away from the ostium, following which the everting 
element can be everted into the fallopian tube. 
The invention, together with additional features and advantages thereof may 
best be understood by reference to the following description taken in 
connection with the accompanying illustrative drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
FIG. 1 shows a catheter 11 which includes an elongated flexible catheter 
body 13 having an enlarged distal body portion 15 and a distal end 17. The 
catheter 11 has been passed through the cervix 19 and into the uterus 20 
of a patient and has been manipulated to bring the distal end 17 to an 
ostium 21 of one of the fallopian tubes 23. 
The catheter body 13 is flexible, but in its unstressed condition shown in 
FIG. 1, the catheter body 13 has a distal portion or region 25 which is 
curved in one direction. With reference to the patient, the curve opens 
generally laterally and inferiorly. 
As shown in FIG. 4, the catheter body 13 includes a primary tube 27 which 
makes up most of the length of the catheter body, a distal segment 29 and 
an inner tubular member 31. The primary tube 27 is flexible and may be 
constructed of a suitable biocompatible polymeric material such as PTFE, 
nylon or polyethylene. The primary tube 27 is preferably reinforced by an 
outer tube (not shown) proximally of the distal portion 25. The primary 
tube 27 defines a proximal region 33 (FIG. 1) of the catheter body where 
it is coupled to a conventional fitting 35 which can be used to supply an 
inflation medium to the catheter through a leg 37. 
The catheter body 13 has an elongated passage 39 which extends from the 
proximal region 33 and the fitting 37 to the distal end 17. The passage 39 
terminates in a distal opening 41 (FIG. 4) at the distal end 17. 
The catheter 11 is an everting catheter and includes a support tube 43 
movable longitudinally within the elongated passage 39 and a flexible 
everting element 45 coupled to the support tube 43 and the catheter body 
13 in any suitable manner such as by an adhesive or a thermal bond. More 
specifically, the everting element 45 is thermally bonded to the inner 
tubular member 31 which in turn is adhesively mounted on a reduced 
diameter nose section 47 of the primary tube 27 as shown in FIG. 4. The 
nose section 47 may be constructed of a biocompatible polymeric material, 
such as polyethylene. The support tube 43 extends from the location shown 
in FIG. 4 proximally completely through the elongated passage 39 and the 
fitting 35 and is coupled to a fitting 49 (FIG. 1). The fitting 49 
includes a leg 51 through which a fluid can be infused through a central 
passage 53 of the support tube 43 and a passage 55 of the everting element 
45. The fluid media for everting and inverting the everting element 45 can 
be injected through the leg 37 of the fitting 35 to an annular space 57 
between the primary tube 27 and the support tube 43 as shown in FIG. 4. 
The primary tube 27 has a blind mandrel lumen 59 into which a stiffening 
mandrel (not shown) can be inserted to straighten and stiffen the catheter 
11 for insertion through the cervix into the uterus. The mandrel is then 
withdrawn to allow the catheter body 13 to return towards is curved 
unstressed state as shown in FIG. 1. This may all be accomplished as more 
specifically described in common assignee's copending application Ser. No. 
779,356 filed on Oct. 17, 1991. 
The distal segment 29 is preferably constructed of a suitable biocompatible 
polymeric material such as hard nylon, polyethylene or polyurethane. The 
distal segment 29 is bonded or otherwise attached to a reduced diameter 
portion 61 of the primary tube 27 so that the outer periphery of the 
catheter body 11 remains at substantially the same diameter on both sides 
of the transition between the primary tube 27 and the distal segment 29. 
The distal segment 29 forms a portion of the elongated passage 39 which 
extends through the catheter body 13. 
The distal segment 29 of the catheter body 13 includes an enlarged distal 
body portion 63 and a sleeve 65 (FIG. 2). The sleeve 65 is cylindrical to 
mate with the primary tube 27, which is also preferably cylindrical. The 
distal body portion 63 is enlarged, and in the embodiment illustrated, is 
generally in the form of a portion of a ball. Consequently, the distal 
body portion 63 has a larger radial dimension than a radial dimension of 
the region of the catheter body which is immediately proximal to the 
distal body portion, i.e. the sleeve 65. The distal body portion 63 has an 
outer surface 67 which is curved convexly in longitudinal cross section 
(FIG. 2) and as viewed in radial cross section. The distal body portion 63 
is also harder and stiffer than the primary tube 27 and has an annular 
rounded surface 69 at the distal end 17 surrounding the distal opening 41 
to facilitate insertion through the uterus to the ostium 21. The wall of 
the distal body portion 63 is thicker than the wall of the sleeve 65. 
Internally, the distal body portion 63 has an axial cylindrical passage 
section 71 which is preferably coaxial with, or on a central axis 72 which 
is parallel to, the portion of the elongated passage 39 extending through 
the primary tube 27 and an inclined passage section 73 which extends from 
the passage section 71 to the distal opening 41. Thus, the elongated 
passage 39 through the catheter body 13 may be considered as having a 
major portion which extends from the fitting 35 all way through the axial 
passage section 71 and a minor portion, i.e. the inclined passage section 
73, which extends laterally outwardly of the major portion as shown by way 
of example in FIG. 2. 
The distal body portion 63 has a deflecting surface or ramp 75 which 
partially defines the inclined passage section 73 and which is inclined 
radially to extend toward the distal opening 41. The deflecting surface 75 
can direct a member or fluid out of the distal opening along a path having 
a component which extends laterally of the catheter body 13. 
With this construction, the distal opening 41 faces in a direction which 
has a component extending laterally of the catheter body 13. The distal 
opening 41 is radially offset from the axis of the major portion of the 
elongated passage 39 proximally of the enlarged distal body portion, i.e. 
the distal opening 41 is radially offset from the axis of the cylindrical 
passage section 71 as well as the portions of the passage 39 proximally of 
the axial passage section 71. The distal opening 41 also lies in a plane 
which is inclined at an acute angle with respect to the axis of the major 
portion of the elongated passage 39 and is off axis with respect to the 
major portion of the elongated passage. 
The distal opening 41 is preferably substantially circular and the inclined 
passage section 73 may be substantially cylindrical. Thus, the deflecting 
surface 75 represents only a portion of the cylindrical surface defining 
the inclined passage section 73. 
Although various constructions are possible, in this embodiment the 
deflecting surface 75 forms an angle Y of about 30.degree. with the 
central axis 72 of the axial passage section 71. The plane of the distal 
end 17 and of the distal opening 41 forms an angle X with a vertical or 
radial reference plane which is optimally about 55.degree.. In this 
embodiment the angle Y is less than the angle X. 
By comparing FIG. 1 with FIGS. 2, 4 and 5, it can be seen that the distal 
portion 25 is curved in one direction, and the deflecting surface is 
constructed and arranged to direct the member or fluid being passed 
through the elongated passage out of the distal opening 41 in a second 
direction which is away from the first direction. Specifically, the 
deflecting surface 75 directs a member or fluid generally superiorly or 
cranially. Thus, a member or fluid passing through the elongated passage 
39 is subjected to compound motion from the distal portion 25 and the 
deflecting surface 75. As viewed for example in FIGS. 1 and 2, the distal 
portion 25 curves to the right and the deflecting surface 75 causes a 
change of direction to the left. Although various constructions are 
possible, in this embodiment the distal portion 25 in its unstressed 
condition extends through or forms an included angle of about 120.degree.. 
As shown in FIG. 1, this included angle is less than 120.degree.. This is 
the result of the catheter 11 being deflected by virtue of its engagement 
with the fundus or end wall 77 of the uterus 20. 
FIG. 1A shows the catheter 11 out of the patient with the distal portion 25 
in the unstressed condition. Thus, FIG. 1A shows the distal portion 25 
forming an included angle of about 120.degree.. As shown in FIG. 1A, the 
straight line distance as measured along a straight reference line 79 from 
a proximal end 81 of the distal portion 25 at the axis 83 of the catheter 
body 13 to the distal end 17 is about 2 cm. As shown in FIG. 1A, the 
straight line 79 terminates centrally in the distal end 17, and in this 
embodiment, it terminates at the center of the distal opening 41 (FIG. 2). 
In use, the catheter 11 with the mandrel (not shown) in the mandrel lumen 
59 is inserted through the cervix 19 into the uterus 20 whereupon the 
mandrel is withdrawn and the catheter 11 is allowed to assume its 
essentially unstressed condition in which the distal portion 25 is curved 
as shown by way of example in FIG. 1. Because the distal opening 41 lies 
in an off-axis position during insertion, it collects a reduced quantity 
of mucus during the insertion process. The catheter 11 is then manipulated 
to place the distal opening 41 in registry with the ostium 21 of the 
fallopian tube 23. The enlarged distal body portion 63 separates the 
tissues adjacent the ostium 21. Next, an everting fluid is applied through 
the leg 37 of the fitting 35 to the annular space 57 to evert the everting 
element 45 as shown for example in. FIG. 5. The deflecting surface 75 
deflects the everting element 45 towards the distal opening 41 as the 
everting element is being everted. The deflection of the everting element 
45 is generally cranially and into the fallopian tube 23. In this 
position, an instrument or fluid can be passed through the central passage 
53 into the fallopian tube for examination, treatment or other medical 
purposes. Whatever is passed through the central passage 53 is also 
deflected by the deflecting surface 75 in that the deflecting surface 75 
brings about or has brought about the deflection of the everting element 
45. Of course, the everting element 45 may pull an instrument into the 
fallopian tube 23 as it is being everted, if desired. Upon completion of 
the examination or procedure, the everting element 45 can be inverted back 
to the position of FIG. 4 by reducing the pressure of the everting medium 
in the annular space 55 and withdrawing the fitting 49 and the support 
tube 43 proximally in accordance with conventional practice. 
FIGS. 6 and 7 show a catheter 11a which is identical to the catheter 11 in 
all respects not shown or described herein. Portions of the catheter 11a 
corresponding to portions of the catheter 11 are designated by 
corresponding reference numerals followed by the letter a. 
The primary difference between the catheters 11a and 11 is that the latter 
is a non-everting catheter and has a scope lumen 91 with an endoscope 93 
in the lumen 91. The endoscope 93 may be either removable from the scope 
lumen 91 or permanently affixed within the lumen 91. The scope lumen 91 
terminates distally at the juncture of the passage sections 71a and 73a 
and the scope 93 preferably extends to the distal end of the scope lumen 
91. In this position, the scope 93 can be used to observe whether or not 
the distal opening 41a is in proper registry with the ostium 17 (FIG. 4) 
as well as observe any member or fluid being supplied by the catheter 11a 
to the fallopian tube. 
Because the catheter 11a is of the non-everting type, the everting element 
45 and the nose section 47 of the embodiment of FIGS. 1-5 are eliminated 
and the primary tube 27 extends completely through the sleeve 65a of the 
distal body portion 63a. The scope lumen 91 is provided in the primary 
tube 27a, and the primary tube 27a extends to the distal end of the axial 
cylindrical passage section 71a. 
Although exemplary embodiments of the invention have been shown and 
described, many changes, modifications and substitutions may be made by 
one having ordinary skill in the art without necessarily departing from 
the spirit and scope of this invention.