The present finding relates to the field of catheters for angioplasty and particularly to a catheter for the treatment of stenosis located near a bifurcation of the blood vessel.
The angioplasty treatment of stenosis firstly provides the use of a balloon suitable to be inserted while deflated into the small cavity left free by the plaque and then to be blown to force the plaque and restore an inner diameter of the blood vessel similar to the nominal diameter, i.e. the diameter that the same vessel would have under a non-pathological condition.
The use of the balloons to place a stent inside the stenosis is also known. The stent is a tubular reinforcement, generally a metal web, which is fit onto the deflated balloon and is able to be plastically deformed by inflating the balloon such as to expand until the nominal diameter of the vessel. By remaining in position in its deformed configuration, the stent is thus able to support the vessel walls.
Though these techniques have been developed to treat simple lengths of blood vessels, yet the stenosis developing near a bifurcation can already be treated in a similar manner.
Generally, stents used in bifurcations are tubular structures made of a metal web. These tubular structures may be either plain or Y-shaped.
Among the current systems for the treatment of bifurcations there are some providing the use of a catheter with a distal end split in two and comprising two identical balloons.
These catheters are conceived to carry out an angioplasty treatment and to place a Y-shaped stent into the bifurcation.
A catheter of this type suffers from some substantial drawbacks. First of all because, during the very first steps of the angioplasty operation, two deflated balloons placed side-by-side are very bulky as a whole and determine a notable irregularity of the catheter section in the distal length thereof. Due to the bulk and irregularity of its section, the catheter becomes difficult to drive through the tortuous path towards the bifurcation to be treated.
Secondly, because during the angioplasty operation, two balloons placed side-by-side in the-common vessel length, before the bifurcation, entail a damaging over-dilatation of the vessel. In fact, both balloons are sized such as to have their expanded diameter equal to the nominal diameter of the vessels to be treated.
A solution to this drawback has been attempted by using a catheter having a distal end split in two, comprising two balloons and in which the length of the balloon intended for the side vessel is clearly shorter than the length of the balloon intended for the main vessel. The proximal end of the side balloon starts about at half the length of the main balloon, in order to prevent that the vessel may over-dilate in a prejudicial manner inside the length in common.
This catheter is designed, such as that described above, to be able to place a Y-shaped stent in the proximal length in common and in both distal lengths at the same time.
This type of catheter also entails a notable drawback since the overall shape of both balloons is not able to provide a correct shape of the stenosis at the bifurcation. In fact, the final shape provided to the stenosis by the catheter following the angioplasty operation, is influenced by the transition of the catheter side arm diameter at the point where the tube ends and the balloons start. This transition is placed exactly at the bifurcation point, i.e. where the need is the greatest for a regular profile of the vessel lumen in order to maintain the blood stream as undisturbed as possible.
Examples of catheters for the angioplasty treatment of bifurcations of the type described above are also provided by the international patent applications WO 03/053507 and WO 96/34580 as well as by U.S. patent application U.S. Pat. No. 6,099,497.
From what has been discussed above, the object of the present invention is to provide a catheter for the angioplasty treatment of the bifurcations which allows to overcome the drawbacks of the prior art catheters.
This object is achieved by a catheter for angioplasty according to claim 1.
Further details and the advantages of the invention will become apparent from the description given below with reference to the annexed drawings, being merely illustrative and non limiting, in which:
a and 9b illustrate practical sections similar to that from
With reference the above figures, with 1 is designated a catheter according to the invention as a whole.
Within this catheter a proximal area 2 and a bifurcated distal area comprising a first arm 3 and a second arm 5 can be identified.
The proximal area 2 is intended to remain external to the patient's body. It comprises the means required to connect the catheter to any complementary equipment, such as to connect the balloon inflating lumens to a source of pressurized fluid. The proximal area 2 further comprises the means required to control the movement of the catheter inside the blood vessels of the patient's body.
The first distal arm 3 comprises in turn a first tip 31, a first balloon 33, a first tube 36, a first guide lumen 34 and a first inflating lumen 35.
The first guide lumen 34 runs all along the tube 36, balloon 33 and tip 31 without intermediate openings. The distal end of the guide lumen 34 defines an apex port 32.
The apex port 32 and the guide lumen 34 represent a path to a guide wire. In other words, they allow the arm 3 to slide along a guide wire suitably prearranged through the patient's blood vessels to drive the catheter from the percutaneous incision to the proper site where the angioplasty operation should be carried out.
On the other hand, the first inflating lumen 35 is the inflating lumen of balloon 33 and the distal end thereof coincides with the proximal end of balloon 33 (see
The balloon 33 is shaped such that it can alternatively take either a collapsed configuration (see for example
In accordance with an embodiment, the first arm 3 comprises at least one radiopaque marker 39. In accordance with a preferred embodiment, the first arm 3 comprises two radiopaque markers 39a and 39b.
In accordance with a preferred embodiment, the wall 330 of balloon 33 is, in its collapsed configuration, folded and rolled up on itself thus forming some flaps. In accordance with a preferred embodiment, the wall 330 forms three of such flaps, though this number may change depending on practical requirements. In this configuration, the overall bulk of the transversal section of the balloon 33 is minimized.
On the other hand, in the expanded configuration, the wall 330 of balloon 33 deploys, the transversal section takes an almost circular profile and the diameter of the section takes its maximum value.
Within the first balloon 33 a distal transition area 331, a middle area 332 of constant section and a proximal transition area 333 can be identified.
The distal transition area 331 is shaped such as to join the outer diameter of the tip 31 with the outer diameter of the balloon 33.
On the other hand, the proximal transition area 333 is shaped such as to join the outer diameter of the balloon 33 with the outer diameter of the tube 36.
In accordance with a preferred embodiment, the distal transition area 331 and the proximal transition area 333 have the shape of a truncated cone, while the middle area 332 of constant section is cylindrical in shape.
In accordance with a preferred embodiment, both markers 39a and 39b are located near the ends of the middle area 332 of constant section.
The second distal arm 5 comprises in turn a second tip 51, a second balloon 53, a second tube 56, a second guide lumen 54 and a second inflating lumen 55.
The second guide lumen 54 runs all along inside the tube 36, balloon 53 and tip 51 without intermediate openings. The distal end of guide lumen 54 defines an apex port 52.
The apex port 52 and the guide lumen 54 represent a path to a guide wire. In other words, they allow the arm 5 to run along a guide wire suitably prearranged along the patient's blood vessels to drive the catheter from the percutaneous incision to the site where the angioplasty operation should be carried out.
On the other hand, the second lumen 55 is an inflating lumen of balloon 53 and the distal end thereof coincides with the proximal end of the balloon 53 (see
The balloon 53 is shaped such as to be able to alternatively take either a collapsed configuration or, following to the injection of a pressurized fluid through lumen 55, a deployed configuration.
In accordance to an embodiment, the second arm 5 comprises at least one radiopaque marker 59. In accordance with a preferred embodiment, the second arm 5 comprises two radiopaque markers 59a and 59b.
In accordance with a preferred embodiment, the wall 530 of balloons 53 is, in the collapsed configuration, folded and rolled up on itself thus forming some flaps. In accordance with a preferred embodiment the wall 530 forms two of such flaps (see
On the other hand, in the expanded configuration the wall 530 of balloon 53 deploys, the transversal section takes an almost circular profile and the section diameter takes its maximum value.
Within the second balloon 53 a distal transition section 531, a middle area 532 of constant section and a proximal transition area 533 can be identified.
The distal transition area 531 is shaped such as to join the outer diameter of the tip 51 with the outer diameter of the balloon 53.
On the other hand, the proximal transition area 533 is shaped such as to join the outer diameter of the balloon 53 with the outer diameter of the tube 56.
In accordance with a preferred embodiment, the distal transition area 531 and the proximal transition area 533 have the shape of a truncated cone, while the middle area 532 of constant section is cylindrical in shape.
In accordance with a preferred embodiment, the markers 59a and 59b are located in the centre of the middle area 532 of constant section and near the distal end thereof, respectively.
The different arrangement of markers 39a and 39b of first arm 3 and of markers 59a and 59b of the second arm 5, enables the operators to identify both arms while performing the angiography vision.
The second balloon 53, when being in the expanded configuration, is of a smaller diameter than the first balloon 33, also being in the expanded configuration.
In accordance with an embodiment, the expanded diameter of the second balloon 53 is either equal to or lower than half the expanded diameter of the first balloon 33.
In accordance with a preferred embodiment, the difference between the diameters of both balloons is such that, while being in the expanded configuration and when both balloons are encircled by an outer tubular structure such as a vessel and/or a stent, the profile of the second balloon 53 is substantially incorporated into the profile of the first balloon 33 (see
In accordance with another preferred embodiment of the catheter 1, the inflating lumens 35 and 55 are made such as to allow both balloons to be inflated with different pressures. Thanks to this solution the effect of incorporating the profile of the second balloon 53 in the profile of the first balloon 33 can be enhanced.
From what has been discussed above it should be observed how the overall profile taken by the length where both balloons are placed side-by-side, is either rounded or substantially circular.
Due to the smaller expanded diameter of balloon 53 its bulk is reduced also when being in the collapsed configuration. In fact the flaps obtainable by folding the wall 530 on itself have peripheral widths such as not overlap one another (see
Thanks to the small bulk of the second arm 5 when the balloon 53 is collapsed, the overall handiness of catheter 1 during the manoeuvres preliminary to the operation of angioplasty is clearly better than a known catheter with two conventional balloons of the same size.
Moreover, due to the small size taken by the second balloon 53 in its expanded configuration, the damaging over-dilation is avoided in the common bifurcation length, where both balloons 33 and 53 are placed side-by-side and deployed at the same time.
In accordance with an embodiment (illustrated in FIGS. 1 to 3) the proximal transition area 333 of first balloon 33 and the proximal transition area 533 of the second balloon 53 are axially arranged along their respective arms such that the proximal ends of the corresponding areas of constant section, 332 and 532 respectively, coincide.
The area of constant section 532 of the second balloon 53, distally ends before the end of the area of constant section 332 of the first balloon 33.
In accordance with another embodiment (illustrated in
In accordance with a further embodiment (represented in
In the distal direction, two balloons 33 and 53 can be shaped such as to either cause the distal ends of the areas of constant section 332 and 532 to coincide or, such as in
Due to the fact that both balloons 33 and 53 have their proximal ends substantially coincident, notable advantages can be obtained in terms of overall shape taken by both balloons at the bifurcation. In fact, the final shape provided by the catheter to the stenosis following the operation of angioplasty, is not influenced—at the bifurcation—by the transition of the diameter of arm 5 at the point where the tube 56 ends and the balloon 53 starts.
By placing this transition upstream of the bifurcation a regular profile of the vessel lumen can be ensured in order to keep the blood stream as undisturbed as possible. The bifurcation is, indeed, the point where the need is the greatest for a regular profile of the lumen.
Regardless of the various balloon lengths as described above, the second arm 5 can be made longer than the first arm 3. In fact, the tip 52 of second arm 5 can be caused to extend beyond the apex port 31 of first arm 3.
This peculiar structural characteristic, i.e. that of prearranging the second arm 5 tip longer than that of first arm 3, allows to obtain notable advantages while performing the operation.
In fact, the second arm 5 with the lower diameter balloon is intended to engage the side branch of the bifurcation. Being longer, the tip 52 of second arm 5 is the first to reach the bifurcation and engages the side branch before the tip 32 of first arm 3 reaches the bifurcation. Thus, the catheter distal section spontaneously takes the proper angular bias within the main vessel, with no risk of reaching the bifurcation with an erroneous angular bias which would force the operator to repeat the positioning.
Furthermore, due to the second tip 51 being longer, the force peak required by the operator to force the catheter inside the stenosis is focused on the second tip 51, thus favouring the insertion of the same. Only later on, when the second tip 51 is already inserted into the stenosis of the second arm, a further force peak is required to force also the first tip 31 inside the stenosis of the bifurcation first arm. Thus, both force peaks are separated and never coincide, thereby limiting the absolute value of the maximum force required.
The catheter 1 can be a part of a kit also comprising a stent 7, mounted on the distal section of the catheter itself (see
In accordance with a preferred embodiment of the kit, the stent 7 is a plain tubular structure the walls of which are made of a metal web. In other words, the stent 7 is not Y-shaped as is common to those stents used in the treatment of bifurcations.
The proximal length of the stent 7, intended to be placed inside the vessel length in common upstream of the bifurcation, is fit on both balloons 33 and 53. At the end of this length, the second arm 5 is caused to exit on one side from a mesh 70 of the stent 7. Thus, the stent distal length, intended to be placed in the first distal arm downstream of the bifurcation, is fitted only on the first balloon 33 (see
This type of solution is particularly effective because, due to the fact of being small sized, the second balloon 53 is not suitable either to accomplish a proper operation of angioplasty or to place a stent in the second distal arm of the bifurcation.
In other words, due to its small expanded diameter, the second balloon 53 is not able to deploy to the extent of forcing the plaque and restore an inner diameter similar to the nominal diameter inside the second arm of the bifurcation.
Again, due to its small expanded diameter, the second balloon 53 is not able to place a stent inside the second distal length of the bifurcation. In fact, the inflation of the second balloon 53 is not sufficient to plastically deform the stent to the extent of deploying it up to the nominal diameter of the vessel.
This solution is particularly effective as it allows an optimum treatment of the proximal length in common, the first distal length and above all the bifurcation itself.
As to the second distal length of the bifurcation, using the catheter according to the invention, an easy access of a second catheter intended only for the treatment of the second distal tract is ensured. The presence and the inflation of the second balloon 53, in fact, ensure that a cavity in the plaque will be maintained and/or formed, which will be sufficiently wide to allow the easy access of a further catheter.
An advantage of the present invention is to provide a catheter which is able to treat the stenosis without over-dilate the length in common in order to prevent any damage to the vessel walls.
Another advantage of the present invention is that it helps to provide the restored section of the vessel with a profile as even as possible at the bifurcation, in order to leave the blood stream undisturbed.
A further advantage of the present invention is to have an even section with a small bulk. Indeed, the catheter according to the invention can be easily driven along the tortuous path, which in the first steps of the operation is to be lead to the bifurcation to be treated.
To the preferred embodiments of the catheter and the kit described above, those skilled in the art, aiming at satisfying contingent and specific needs, may carry out a number of modifications, variants and replacements of elements with others functionally equivalent, without departing from the scope of the claims below.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IT04/00250 | 5/6/2004 | WO | 1/12/2007 |