DE4001086A1 - Medical treatment catheter widening constricted vessels - has two expandable balloons spaced in axial direction with heat conductive piece between them - Google Patents

Abstract

The catheter removes or widens construcconstrictions in vessels conveying body fluids. Two separated balloons pretreat the time of the constriction such that a sufficient denaturisation follows that the subsequent local chemical, enzymatic, angiotropic or other treatment achieves release and removal of the stenosis or calcification. . A heat conductive piece (22) is mounted in the catheter (1) between the balloons (14,15). An optical fibre (23) transmits external laser light to irradiate the conductive piece (22), the latter, or at least its inner surface (24) being of laser light absorbing material. The latter, or at least the outer surface (25) of the heating body (22), is resistant to the treatment medium or at least for a foreseen treatment time. USE - Clearing fatty or calcified stenosis in artery.

Description

The present invention relates to treatment Catheter to remove or widen constrictions in Vessels carrying body fluid according to the generic term of claim 1.

A treatment catheter of this type is known from EP-PS 00 80 436 known. When using this known treatment catheter has been found that the bottleneck treatment, preferential of limestone or fat-rich stenoses in arteries, with suitable treatment media unsatisfactory in some cases is because the treatment medium the tissue is insufficient dissolves.

On the other hand, it is from the publication "Laser Balloon Angioplasty: "An Optical and Thermal Analysis" by A.J. What and Wai-Fung Cheong from the Biomedical Engineering Program, The University of Texas at Austin, Austin, Texas 78 712, Pages 68 to 95, known a vasoconstriction with a Extend or eliminate treatment catheters. For this is a treatment catheter with a single expandable Balloon provided. In the balloon area there is a diffuse radiation Laser source provided through the balloon wall the constriction heats up. The balloon is expanded  with a laser light not absorbing and not scattering the fluid. The first step in the treatment is the surface the narrow point is heated to approx. 200 ° and only after switching off the laser light source further heats the Ge weave through heat conduction. The fluid also heats up and supports the transfer of heat to deeper tissue layers. This causes the tissue to be denatured and stretched fixed.

Due to the direct influence of the laser light on the Tissue gives a very high, mostly undesirable upper surface temperature, which can lead to scab formation or even ver carbonization of the treated tissue. Besides, is does not guarantee that the entire surface even is reasonably evenly heated. This depends on it together that the tissue does not have the laser light at all Places absorbed equally strongly, especially if pathological Changes to the tissue are present.

With the present invention, the task should be solved den, a treatment catheter of the type mentioned to be designed in such a way that an effective pre-treatment the tissue of the constriction, preferably an adequate one Denaturation takes place at the subsequent local chemical, enzymatic, angiotropic or other Treatment of the bottleneck material and its effective dissolution and disposal guaranteed.

According to the invention, this object is achieved by the in the mark of the specified features solved.

When using the treatment catheter according to the invention the tissue is not directly through the laser light, but only indirectly via the heat sink and the treatment  medium or pretreatment medium evenly heated. Here the user is free to choose the fluid as this is not irradiated by laser light. The laser energy is rather in the heat-conducting body on or on the catheter absorbed.

With the treatment catheter according to the invention that becomes treating constriction material, especially stenosis next through the heat treatment, for example under Ver use a saline solution, usually denatured. There by tearing the cells of the treated tissue or the Stenosis and can be caused by the subsequent chemical, enzymatic or angiotropic treatment faster and more fully resolved. Alternatively, you can also the treatment medium for pretreatment before used for denaturing by heating. In this case, there is no separate pretreatment of the Constriction or the constriction material.

Even if the fabric is effectively pretreated This pretreatment does not have to be narrow leads to a denaturation of the bottleneck material in the Meaning a restructuring of its protein molecules to lead. Even tissue pretreatments that only lead to one surface "softening", especially in the sense of a Loosening of the cell structure of the treatment material depending on the consistency of the bottlenecks materials should be sufficient. Further advantageous details the invention are defined in the dependent claims and are below based on the Aus illustrated in the drawing management examples described in more detail. Show it:

Fig. 1, the end portion of a treatment catheter according to the invention from the side in section;

Fig. 2 a cross section according to the section II of FIG. 1,

Fig. 3 is a view of a modified treatment Kathe ters from the front,

FIGS. 4 and 5 each have a treatment with an axial Katherine irradiation of the laser light,

Fig. 6 is a view according to section II of FIGS. 5 and

Fig. 7 is a longitudinal section through a treatment catheter with an externally arranged optical fiber and having an axial irradiation of the laser light.

In Figs. 1 and 2 at 1 is a treatment catheter draws be, for example, having a preferably central serving as a supply channel 2 channel which opens in an opening 4 in the end 3 prede ren. The supply channel 2 is connected to the wall 5 by a plurality of rib-shaped longitudinal dividing walls 6 , 7 , 8 and 9 , which form four independent channels 10 , 11 , 12 and 13 in the treatment catheter 1 in the present exemplary embodiment.

On the treatment catheter 1 two expandable balloons 14 and 15 are applied, which are arranged at a distance from one another 16 for the treatment of a narrowing, in particular a stenosis 17 , of a vessel 18 , for example an artery. The existing in front of the area 16 balloon 14 is via an opening 19 in the wall 5 of the catheter 1 with the channel 11 and behind the area 16 before the existing balloon 15 is via an opening 20 of the wall 5 of the catheter 1 with the channel 13 connected. Due to the pressure of a medium present in the channels 11 and 13 , for example gas, water or a saline solution, the balloons 14 , 15 are expanded to such an extent that they abut against the inside of the vessel wall 21 on both sides of the constriction 17 .

Between the balloons 14 , 15 on the wall 5 of the loading treatment catheter 1, a heat-conducting body 22 in the form of a block, a ring or - as shown - a cylinder is arranged. In the channel 10 , an optical fiber 23 is seen before, in which 23 laser light can be radiated at the outer end of this optical fiber, not shown. The optical fiber 23 ends in the catheter 1 in the area 16 . Its end region 23.1 is guided in such a way that laser light radiated in from outside can be radiated from the inside against the heat-conducting body 22 . So that the heat-conducting body 22 can be heated with high efficiency by the laser light, the heat-conducting body 22 or at least the inner surface 24 of the same consists of a material that corresponds to the wavelength of the laser light used, for example a CO ₂ laser or a neodymium yttrium Aluminum garnet laser (Nd: YAG laser) well absorbed. At the same time, the material of the heat-conducting body 22 is selected such that it or at least one material applied separately on the outer surface 25 is resistant to the heating medium and / or treatment medium to be used or at least resistant to the intended treatment time of, for example, up to a few minutes is. Stainless steel, nickel, copper, tantalum or a suitable, highly heat-conductive ceramic, such as silicon carbide or the like, is preferably used as a suitable material.

Preferably, the material used for the treatment catheter 1 is one that absorbs the laser light as little or as little as possible and is expediently not scattered.

The wall 5 of the catheter 1 has an opening 26 in the channel 10 between the balloons 14 and 15 and an opening 27 in the channel 12 . As a result, the treatment area can be filled with the desired treatment medium, in particular treatment liquid, treated and the material to be treated can then be suctioned off.

If necessary, two or more optical fibers can be provided in one or more channels. If necessary, it may be appropriate to arrange one or more optical fibers, possibly additionally, on the outside of the treatment catheter 1 , preferably in at least one longitudinal groove 28 ( FIG. 3).

According to an advantageous embodiment of the invention, the heat-conducting body 22 can be arranged in the middle or approximately in the middle between the two balloons 14 , 15 . Furthermore, both openings 26 , 27 can also be provided in the wall 5 of the catheter 1 between the heat-conducting body 22 and the balloon 15 provided in front of the treatment area 16 .

According to an advantageous embodiment of the invention, the optical fibers 23 or, if necessary, one of the optical fibers 23 and the heat-conducting body 22 can be designed and arranged in such a way that the optical fiber (s) 23 axially, ie in the direction of the longitudinal axis 29 (see FIG. 5) of the treatment irradiates catheter 1 in the heat-conducting body 22 . For this purpose, the heat-conducting body is shown in FIGS. 4 to 6 provided with a 22 in the lumen or in one of the channels 10 to 13 protruding portion 30. This section 30 has on the optical fiber 23 facing end face 31 from a cutout 32 in the form of an axial, ie in the direction of the longitudinal axis 29 of the treatment catheter 1 blind hole. The radiating end region 23.1 of the optical fiber 23 projects into this blind hole. The end region 23.1 can be fastened in the recess 32, for example by gluing. A plurality of optical fibers 23 can be seen per recess 32 . There may also be a plurality of cutouts 32 , into each of which at least one optical fiber 23 projects.

Fig. 7 shows a further embodiment of the invention, in which the heat-conducting body 22 with a portion 33 on the outer diameter of the catheter 1 is so far beyond that the face 31 facing the light guide 23 can be provided with a blind hole-like, axial recess 32 , into which the end region 23.1 of the optical fiber (s) 23 protrude. Here, the optical fiber 23 can lie in an outer longitudinal groove 28 , as shown in Fig. 3. This embodiment form of the catheter according to the invention can have a supply channel 2 .

In all of the exemplary embodiments in FIGS. 1 to 7, the heat-conducting body 22 can be provided on its surface with ribs or with other means that enlarge its surface.

Claims (14)

1. Treatment catheter for the removal or expansion of constrictions in vessels carrying body fluid, with two expandable balloons arranged in the axial direction at a distance from one another, of which the first balloon seals the area of the treatment on the back side in the expanded state and the second balloon in the expanded direction stood the area of treatment sealed on the front side, the degree of expansion of the two balloons being adjustable from the outside, as well as with at least one opening in the wall of the catheter between the two balloons and with longitudinal dividers provided in the interior of the catheter, through which the interior of the catheter in is divided into three or more channels, through which media for expanding the balloons on the one hand and, on the other hand, the area between the balloons can be filled and / or rinsed with treatment medium via one or more opening (s) in the outer catheter wall,
that in the area ( 16 ) between the balloons ( 14 , 15 ) a heat-conducting body ( 22 ) is attached to or on the catheter ( 1 ), that in or on the catheter ( 1 ) at least one optical fiber ( 23 ) is provided, from the end area thereof ( 23.1 ) an externally irradiated laser light can radiate against the heat-conducting body ( 22 ),
that the heat-conducting body ( 22 ) or at least its inner surface ( 24 ) consists of a laser light absorbing material and that this material or at least the outer surface ( 25 ) of the heat-conducting body ( 22 ) is resistant to the treatment medium or at least over an intended treatment period is resistant. 2. Treatment catheter according to claim 1, characterized in that the heat-conducting body ( 22 ) is annular. 3. Treatment catheter according to claim 2, characterized in that the heat-conducting body ( 22 ) is cylindrical. 4. Treatment catheter according to one of claims 1 to 3, characterized in that at least one optical fiber ( 23 ) in a channel ( 10 ) of the catheter ( 1 ) is provided that the laser light through the wall ( 5 ) of the catheter ( 1 ) the heat-conducting body ( 22 ) can radiate, and that the wall ( 5 ) of the catheter ( 1 ) consists of a material which does not or hardly absorbs the laser light. 5. Treatment catheter according to one of claims 1 to 4, characterized in that the heat-conducting body ( 22 ) projects with at least one section ( 30 ) into at least one channel ( 10 , 11 , 12 , 13 ), and that the optical fiber (s) ( 23 ) is or are directed axially, ie in the direction of the longitudinal axis ( 29 ) of the catheter ( 1 ), against the heat conducting body ( 22 ). 6. Treatment catheter according to one of claims 1 to 5, characterized in that the heat-conducting body ( 22 ) in the direction of the optical fiber ( 23 ) has at least one recess ( 32 ) in the form of a blind hole, and in that the radiating end region ( 23.1 ) has at least one Optical fiber ( 23 ) is or are inserted into the recess (s) ( 32 ). 7. Treatment catheter according to claim 5 or 6, characterized in that at least one recess ( 32 ) extends in the axial direction. 8. Treatment catheter according to one of claims 1 to 7, characterized in that at least one optical fiber ( 23 ) is arranged on the outside of the catheter ( 1 ). 9. treatment catheter according to claim 8, characterized in that the catheter ( 1 ) has at least one longitudinal groove outside ( 28 ) in which the or one of the optical fiber (s) ( 23 ) is attached. 10. Treatment catheter according to claim 8 or 9, characterized in that the heat-conducting body ( 22 ) with a section ( 33 ) at least partially overhangs the outside diameter of the treatment catheter ( 1 ) and in this section ( 33 ) at least one axially extending recess ( 32 ) is provided in the form of a blind hole into which at least one optical fiber ( 23 ) projects with its radiating end region ( 23.1 ). 11. Treatment catheter according to one of claims 1 to 10, characterized in that each balloon ( 14 or 15 ) via a separate channel ( 11 or 13 ) via an associated opening ( 19 or 20 ) in the wall ( 5 ) of the Catheter ( 1 ) can be supplied with pressure medium from the outside and that the area ( 16 ) between the two balloons ( 14 or 15 ) has an opening ( 26 or 27 ) in the wall ( 5 ), each with a separate channel ( 10 or 12 ) is connected. 12. Treatment catheter according to one of claims 1 to 11, characterized in that the heat-conducting body ( 22 ) is arranged in the middle or almost in the middle between the two balloons ( 14 and 15 ). 13. Treatment catheter according to one of claims 1 to 12, characterized in that the area ( 16 ) between the balloons ( 14 , 15 ) provided (s) (s) ( 26 or 27 ) in the wall ( 5 ) of the Catheter ( 1 ) is or are provided between the heat-conducting body ( 22 ) and the balloon ( 15 ) provided in front of the treatment area. 14. Treatment catheter according to one of claims 1 to 13, characterized in that the catheter ( 1 ) has a supply channel ( 2 ) which is open at both ends.