AT405136B - DEVICE FOR THE INTRAVASCULAR TREATMENT OF RESTENOSES - Google Patents

Description

AT 405 136 B

The invention relates to a device for the treatment of restenoses, such as those that occur in particular after angioplasty treatment or bypass operations, with a targeted treatment of the vessels by ionizing radiation, such as, in particular, beta and / or gamma radiation from the inside of the vessel.

In particular, the invention relates to a device for the intravascular treatment of restenoses after angioplasty or bypass surgery by means of ionizing radiation, the radioactive source being able to be guided on a balloon tube part of a balloon catheter which can be filled with expanding liquid and which in turn can be arranged or arranged along a vessel to be treated in a vessel to be treated arranged guide wire is arranged, the balloon tube part of the balloon catheter having at least one balloon-like expandable extension zone at least in the region of the distal catheter end.

The treatment of vascular structures using ionizing radiation to prevent restenosis is a method that is currently being discussed very intensively and has also been investigated in a series of experiments. That radiation therapy can reduce or prevent the proliferation of rapidly growing cells has long been proven in cancer radiation therapy and is also known for non-malignant cells from animal experiments. Seeds and cylindrical radiation sources have long been used in radiation therapy for use within the body. Irradiation of blood vessels, on the one hand, requires special, targeted radiation methods to ensure optimal irradiation of that part of the blood vessel in which restenosis occurs and is to be prevented, but on the other hand, unnecessary radiation of other parts of the body, in particular the tissue that affects the Wall of the blood vessel connects, avoided or kept as small as possible. In addition, radiation therapy must ensure that the dose applied to the inner side of the blood vessel is distributed as evenly as possible over the surface in order to guarantee a sufficiently high dose at every point of the vessel that has been treated by angioplasty and is therefore at risk of restenosis, but at the same time to prevent excessive exposure to radiation in other parts of the blood vessel.

A known way of irradiating the vessel wall with appropriate doses is to use radioactive stents. The previously proposed use of radioactive stents which remain in the blood vessel has the disadvantage that the radioactivity remains in the body and this results in an unnecessarily long duration of the irradiation of the vessel wall. In addition, leaching of radioactivity and its transfer into the rest of the body is possible in principle with these open radioactive substances, so that unnecessary radiation exposure to other organs can result.

A large number of proposals for balloon catheters have become known, which can be removed from the respective vessel after the treatment has been completed. For this purpose, reference is made, for example, to the solutions according to WO 96/22121 A1, EP 688 580 A1, US 5 213 561 A and US 5 302 168 A, according to which, in one way or another, it is provided that the radioactive source is on one with Expandable liquid-fillable balloon tube part of a balloon catheter can be guided, which in turn is arranged along a guide wire that can be arranged or arranged in a vessel to be treated, the balloon tube part of the balloon catheter having at least one balloon-like expandable expansion zone at least in the region of the distal catheter end.

Further details and configurations of such balloon catheters, e.g. the arrangement of a second balloon-like expandable expansion zone or further such zones, the radiation sources then being arranged in the areas between these expansion zones, or the provision of such expansion zones which, in the expanded state, leave one - areas or sectors for the blood flow in the vessel - Essentially have a constricted cross section at several points, for example from US 5 160 321 A, US 4 824 436 A, WO 90/07352 A1 and WO 94/05365 A1.

In the previous proposals there is in any case a stronger and undesirable variation in the radiation dose, since the source is either located in the center of the blood vessel, see e.g. also US 5,199,939 A, US 5,503,613 A and EP 0 688 580 A1, and thus the radiation dose very much depends on an exact positioning in the center of the blood vessel, or it is the radiation source at the front end of a wire on the vessel wall, e.g. US 5,213,561 A, US 5,484,384 A and EP 433 011 B positioned, with which the vessel wall dose is associated with high inhomogeneity.

Especially with the previously proposed solutions using a stent, see EP 433 011 B, with surface coatings or other equipment for the expansion zone of the balloon catheter with radioactivity, see e.g. WO 96/22121 A1 or US Pat. No. 5,302,168 A or when using liquid radioactivity in the balloon, see US Pat. No. 5,199,939, of a balloon catheter, there is the not inconsiderable possibility of an undesired release of radioactivity from the respective radiation source, which transports it away with the blood and would lead to undesired radiation exposure in other organs. For longer-lived radioactive substances that can be stored in other organs, e.g. Strontium-90, may 2

AT 405 136 B even lead to very high doses.

The invention has for its object to provide a device based on the balloon catheter technology, which does not have the various disadvantages of the prior art described and which, with careful and patient-friendly insertion of the catheter in the vessel to be treated, enables positioning of the radiation source which actually ensures as uniform and homogeneous a radiation as possible of the area or areas of the vessel at risk of restenosis.

The invention thus relates to a device of the type mentioned, the essential features of which are that the above-mentioned, balloon-like expandable extension zone is followed by a tube or radiation source carrier zone extending in the direction away from the distal end, on which one or more the same radiation source (s) surrounding on all sides is arranged to emit the desired ionizing radiation.

In order to ensure that the internal surface of the blood vessel is irradiated as uniformly as possible, the new therapy device therefore has at least one radionuclide source that surrounds the outside of the balloon tube of the catheter. This, preferably multi-part, source is arranged or anchored on the catheter tube and is designed such that it can be moved and precisely positioned within the vascular structure by means of this balloon catheter or its balloon tube part. In the desired radiation position within the vessel, the balloon part of the catheter is expanded by supplying expanding fluid, as a result of which the body forming the radiation source is positioned in the center of the artery or vein equidistant from the inner surfaces of the blood vessel and achieves uniform radiation and a constant surface dose on the inner wall of the blood vessel can be. The radioactive source generally comprises a purely beta-radiating radionuclide or a beta and gamma-radiating nuclide, preferably with a low gamma emission probability. It is important to ensure that the radioactive substance is built into the radiation sources in such a way that the blood vessel and the surrounding area are protected from any contamination. The particularly preferred forms of training for this protection will be discussed in more detail below. The half-life of the radionuclide can vary from a few hours to a few tens of years, depending on the application. The radioactive radiation source is fixed on the catheter after being pushed onto it or its tube part by means of friction and by partially expanding the balloon part. The main advantages of the invention are as follows:

Due to the shaping of the radiation source on the outside of the catheter tube, uniform radiation of the wall of the blood vessel can be achieved with little spatial variation of the radiation dose, since the dose applied to the tissue in this type of geometry does not depend so much on the distance between the radiation source and the vessel wall. such as with internally arranged radioactive sources or the like.

This encompassing geometry of the radiation sources allows easy movement of the activity on the guidewire that was inserted and positioned in the vessel prior to angioplasty. This reduces the requirements for the manipulation of radioactivity by medical personnel and improves the reliability when inserting and positioning the radiation source in the body, but especially when it is extracted from the body.

The suitable, ie centered positioning of the radiation sources within the blood vessel is achieved in any case by expanding the balloon zone remote from the device on one side or, as will be explained in more detail later, by expanding such balloon zones on both sides of the radiation sources. The centering can be further improved by additional balloons or spacers between the radiation sources. In any case, a considerable improvement in the homogeneity of the irradiation of the vessel wall compared to all comparable proposals known to date, such as achieved according to US-A 5,199,939.

In the catheter therapy device according to the invention, there is no substantial shielding of the radiation emitted by the radiation source on the outside thereof. Since the radioactive source is attached to the outside of and around the catheter, there is no material between the radiation source and the inner wall of the arteries that could cause a dose reduction on the wall mentioned, except for a preferably provided sealed covering of the radioactive material and the blood in the vessel . This leads to an optimal penetration of the radiation into the wall of the blood vessel and thus guarantees that proliferating cells are irradiated not only on the inner top of the vessel, but also to a depth of 1 to 2 mm.

Preferably, as provided in claim 2, a plurality of radiation sources surrounding or enclosing the same can be arranged on the tube zone, so that the length of the radiation-active region of the catheter can be flexibly adapted to the respective length of those affected or endangered by restenosis Zone inside the vessel is made possible. 3rd

AT 405 136 B

By dividing it into several individual radiation sources, the radiation source can also be easily guided into and through the curvature of the vessel and also placed in the same at the desired site of action. So there are several tube-shaped radiation sources pushed onto the tube part of the catheter. This division into individual radiation sources can also ensure the flexibility required for the catheter to slide through the vessels and to adapt to the vessel curvatures in the irradiation position. The outer diameter of the hollow cylinder is typically 0.5 to 2.5 mm, the inner diameter can be 0.1 to 2 mm.

In the sense of their task of ensuring as uniform as possible but at the same time as direct as possible irradiation of the cells proliferating on the essentially cylindrical inner wall of the vessel by maintaining uniform equidistant distances on all sides between the radiation source and the inner wall of the vessel, an essentially hollow cylindrical shape of the individual radiation sources, as in Claim 3 described in more detail, preferred.

Within the scope of the invention, an embodiment of the novel balloon catheter according to claim 4 also has the following advantages: In the treatment status, in this embodiment, the balloon catheter is pushed onto the guide wire arranged inside the vessel to be treated and the extension zone, remote from the device, of its balloon tube part is filled with expanding liquid. The expanded extension zone is followed by an integral hose zone towards the manipulator, which is only slightly expanded. This hose zone merges into a second, expanded extension zone. Most of the radiation sources surrounding this zone are arranged on the slightly expanded hose zone.

The series of two, three or more radiation sources sitting on the tube zone is flanked on both sides by an expansion zone which is enlarged like a balloon in the expanded state, which in this way ensure that the radiation sources are held on both sides and that the positioning of the radiation sources is stable on the catheter.

However, the particular advantage of the seat of the radiation sources flanked on both sides by balloon zones is that the jammed, two expanded balloon zones in the vessel ensure that the tube zone located between them and with it the radiation sources sitting on them centered in a substantially conforming to the vessel axis Position brought and kept in this position. As a result of the concentric positioning achieved in this way, the circumferential surfaces of the individual radiation sources have essentially the same distance from the inner wall of the vessel all around within the area between the expanded expansion zones. The above-mentioned, uniform and homogeneous radiation of the vessels to be treated or of the disruptive tissue can thus be achieved.

The size or length of the restenosis zone to be treated in the blood vessel can be taken into account by choosing the length of the tube zone between two extension zones and thus the number of radiation sources threaded in series there. A plurality of expansion zones which can be expanded in the manner of a balloon can be provided for the above-described centering of the arrangement of the radiation sources in the vessel to be treated, which conforms to the requirements of the vessel.

The centering of the radiation sources in the vessel can also, as is apparent from claim 6, by a spacer or the like positioned between them. be achieved or supported. The individual centering spacer encompasses the catheter tube in the same way as the radiation sources and has radial spacer arms, the ends of which, optionally equipped with sliding shoes, possibly closed to form a sliding ring, are supported on the inner wall of the wire and can slide there when the tube catheter is inserted.

In order to ensure the blood supply to the tissue to be treated for the supply of tissue parts located beyond the actual treatment site even in the case of an expanded expansion zone during a longer irradiation period, an embodiment of this zone according to claim 7 is advantageous, which in the expanded state as a balloon zone each has a cross section constricted at several points has or have and functions or function essentially in the manner of a perfusion balloon.

Furthermore, the arrangement of securing the hollow cylinder radiation sources near the device against stripping from the catheter is favorable. It can be formed by a hook-shaped design of the catheter from the same material as the catheter and as part of the catheter, or it can consist of a metal or plastic ring which is fixedly mounted on the end of the guide wire.

As for the radiation sources that are very important for the invention and its function, those with dimensional ratios according to claim 9 have proven themselves from the point of view of practice: they enable centering in the vessel and flexibility in vessel curvatures while at the same time in vessel 4

AT 405 136 B stable radiation source, which enables the desired, uniform and homogeneous radiation of the proliferating tissue to be treated.

A problem-free insertion of the novel therapy catheter without risk of injuries to the inner walls of the vessel can advantageously be achieved by a chamfered or rounded embodiment of the circularly curved cutting edges of the outer cylinder surfaces with the annular end faces of the radiation sources.

In order to eliminate practically any possibility of contamination by material from the radiation sources, a coating or a real protective cover can be particularly advantageous.

In contrast to other previously proposed restenosis radiation devices, such a material-tight covering of the radiation source ensures that no internal contamination of the patient can occur and that other parts of the patient's body cannot be exposed to inadmissible or unnecessary radiation exposure.

The radioactive sources are thus enclosed in a dense covering, which prevents contamination of the blood and body tissue, and therefore form enclosed sources. A coating or wrapping can be done by various types of application as usual or by spraying, dipping, steaming, shrinking on a film or the like. be produced on a core body provided for the radiation emission.

According to a favorable embodiment, the radioactive substance of the radiation sources can be present in the casing as a compact body, as is evident from claim 12.

In a further embodiment variant, the active substance can also be present in the casing in divided, lumpy or finely divided expandable form, the particles e.g. can also be filled into a prefabricated envelope. The radiation-effective filling or the compact core body can be provided with the covering or can be introduced into the covering in the already active state, or it can only be activated after the covering or insertion has taken place.

A simple manufacture enables the provision of a shrink film as a covering, as provided in accordance with claim 14, with the advantage here that the radiation source itself could be expanded.

A largely unproblematic manipulation of the new device when it is used can also bring about a lubricant-promoting coating of the radiation sources.

As far as the substance emitting the ionizing radiation from the individual radiation sources themselves is concerned, beta emitters or beta emitters with low gamma emission are sufficient, since the balloon catheter is a direct approach of the emitter to the wall part of the vessel to be irradiated or that part of it occurring restenosis enables.

The use of these emitters ensures homogeneous irradiation of the potentially proliferating tissue part without the tissue behind it, which should be exposed to the lowest possible radiation exposure, being loaded more than is absolutely necessary. Because of the use of these radioactive substances, there is also no significant lead shielding of the source, e.g. according to US-A 5,213,561, required, which considerably facilitates the introduction and withdrawal of the source from the vessel. Furthermore, the patient load as a whole is minimized or reduced to zero as a result of the penetrating gamma radiation on the other parts of the body.

To avoid complications, in particular as a result of stripping the source (s) from the catheter or guidewire and their loss, it is advantageous, as provided in accordance with claim 17, for the end of the wire remote from the device to be at least thickened, with an end piece or the like. equip the or the like or the like. or forms a movement limitation for the radioactive source (s).

The invention and its advantages are explained in more detail with reference to the drawing.

They show

Fig. 1 shows the longitudinal section through a therapy device with balloon catheter according to the invention with a single extension zone in the balloon-like expanded state, the

Fig. 2 shows an embodiment with two such expansion zones, which can also be referred to as centering balloons

3 shows a further embodiment variant with three such expanded extension centering zones, FIG. 4 shows a section across the new device in the embodiment according to FIG. 3, FIG. 5 shows a diagram which shows the centering of the radiation sources in a vessel curvature, and FIGS. 6 to 8 each show longitudinal sections through radiation sources for the new therapy device in various preferred embodiments.

The balloon catheter 100 shown in FIG. 1 essentially comprises a balloon tube part 2 that can be filled with expanding liquid and has an expansion zone 21 in the region 5 that can be expanded like a balloon

AT 405 136 B of its end 101 remote from the device and a hose zone 22 which is integral with said zone 21 and extends from the mentioned end to the treatment device. A positional and blocking element, e.g. a conical ring 5 is arranged, which includes the device-near end of the balloon tube part 2 and holds. There is also a supply channel 31 for expanding liquid in the balloon tube part 2.

Following the expansion zone 21 shown here in the expanded state, several, in the specific case four, similar radiation sources 1 of a hollow cylinder shape are pushed onto the tube part 2 via its tube zone 22, each of which abuts one another with its end faces 141, 142. The radiation sources 1 fully encompass or enclose the balloon tube part 2 in its tube zone 22 and are centered in the vessel 8 in this way.

The row of the four radiation sources 1 shown here is held remotely from the device by the balloon-like expansion zone 21. Positioning element 5 ensures this close to the device.

When in action, the catheter tube 2 is pushed over a guide wire 6 arranged in the blood vessel 8, an end stop 61, which is fixedly attached to the end of the guide wire, additionally preventing any undesired stripping.

1 also shows how the radiation sources 1 in the vessel 8 are kept centered around the vessel axis Z by the balloon part 21 and thus enable the potential restenosis tissue 81 to be irradiated uniformly over its respective longitudinal extension 1.

2 shows an essentially similarly constructed therapy device 100 with a balloon catheter tube part 2 with two spaced apart expansion zones 21, 21 'in the balloon-like expanded state and a tube or radiation source carrier zone 22 extending therebetween, which in turn comprises one or more , in the case shown four, it fully enclosing, hollow cylindrical radiation sources 1 carries. The remaining reference symbols have the same meaning as in FIG. 1.

From FIG. 2 it can be seen particularly clearly how the two flanking balloon zones 21 and 21 ′ fix the radiation sources 1, which are closely adjacent to one another on the end faces, immovably and at the same time secure their center-centered position in the vessel 8. An additional centering over the length of the entire radiation source can also be achieved, as shown in FIG. 2, by spacers 9 with sliding shoes 91 or the like located on the hose zone 22, which are arranged between the radioactive cylinder sources 1.

This ensures uniform, homogeneous irradiation of the vascular parts to be treated against restenosis. The balloon catheter ensemble 100 shown here is closed with the blocking element 5 close to the device.

3 shows a further embodiment variant of the new therapy device 100, with the meanings of the reference symbols also remaining the same. It comprises - in the form shown in each case in the expanded state - three balloon-like expansion zones 21, 21 'and 21 ". They are connected in each case by the tube and radiation source carrier zones 22, 22 ′ integral with them, each of which, in the form shown, carries two radiation sources 1 with their cylinder end faces 141, 142. In the direction of the loading device, a conical ring-shaped blocking and closing element 5 closes off the catheter tube 2 formed with the extension zones 21, 21 'and 21 "and the tube zones 22 and 22'. A continuous centering of the radiation sources in the vessel is achieved by the expansion zone 21 'located in the middle between the two expanded zones 21, 21 ”.

The cross-sectional view of FIG. 4, transverse to the axis Z of the catheter 100 - corresponding to a section in a plane AA in FIG. 3 - shows the guide wire 6 extending along the axis Z, the tube part 2 of the catheter 100 surrounding it, the tube or radiation source carrier zone 22 'of the balloon tube part 2 and a view of the expanded balloon extension zone 21', which in the manner of a perfusion balloon has a cross-sectional shape with one or a plurality of bulges 211, between which surfaces 212 are left free for maintaining the blood flow .

5 shows only schematically how in a vessel curvature through the expanded extension zones 21, 21 ', 21 " etc. and by means of centering spacers 9 with sliding shoe 91, the continuously centered arrangement of the radiation sources 1 in the vessel 8 is ensured.

The hollow cylindrical radiation source 1 of FIG. 6 shown in longitudinal section - in which the outer diameter is designated by d and the longitudinal extension by h - has rounded edges 132 where the outer lateral surface intersects the end faces 141 and 142, which increases the risk of mechanical Load on the walls of the vessels passed through is reduced.

FIG. 7 shows a radiation source 1 with an active or activatable core body 105 and an all-round material-tight envelope 120 of the same. In addition, the sheath 120 may e.g. be surrounded by a slide-promoting material, which can facilitate the manipulation of the new therapy device when it is introduced into a vessel. 6

Claims (17)

ΑΤ 405 136 Β FIG. 8 shows how the radiation source 1 is constructed with a radiation-active core body 105 and a shrink tube film 120 enveloping it, thereby ensuring tightness against possible leaching of activity. Under certain circumstances, provision can be made to expand the space 111 between the cladding film 120 and the core body 105 by supplying fluid and thus to achieve an even better centering of the radioactive body within a ultimately spacer-shaped centering device in a vessel. 1. Device for the intravascular treatment of restenoses after angioplasty or bypass operations by means of ionizing radiation, the radioactive source being able to be guided on a balloon tube part (2) of a balloon catheter (100) which can be filled with expanding liquid and which itself is along a vessel to be treated is arranged or arranged guide wire (6), wherein the balloon tube part (2) of the balloon catheter (100) at least in the region of the distal catheter end (101) has at least one balloon-like expandable extension zone (21), characterized in that this Extension zone (21) expandable in the manner of a balloon connects a tube or radiation source carrier zone (22) extending in the direction away from the distal end (101), on which one or more radiation source (s) (1) surrounding the same on all sides for emitting the desired ionizing radiation is or are arranged. 2. Device according to claim 1, characterized in that on the tube zone (22) of the balloon tube part (2) a plurality of the same all-round, preferably adjacent or adjoining, independent radiation sources (1) for emitting the ionizing radiation is arranged. 3. Apparatus according to claim 1 or 2, characterized in that the individual radiation sources (1) are designed as a body with a substantially tubular or hollow cylindrical shape. 4. Device according to one of claims 1 to 3, characterized in that the balloon tube part (2) in addition to the located in the region of the distal end (101), balloon-like expandable expansion zone (21) in a known manner at least one further, arranged at a distance therefrom , has a balloon-like expandable extension zone (21 ') and that the radiation sources (1) arranged in the area of the hose zone (22) connecting the two said extension zones (21,21 *) are situated between the said extension zones (21,21'). 5. Execution according to one of claims 1 to 4, characterized in that the balloon tube part (2) in addition to the located in the region of the distal end (101), balloon-like expandable expansion zone (21) in a known manner a plurality of such, each spaced apart Widening zones (21 *, 21 ”), said widening zones being connected to one another via hose zones (22, 22 ') and in each case in the area of these hose zones (22, 22') the radiation sources (1) are arranged. 6. Device according to one of claims 1 to 5, characterized in that between individual of the radiation sources (1) dimensionally and dimensionally stable centering spacers (9) are arranged. 7. Device according to one of claims 1 to 6, characterized in that the balloon-like expandable expansion zones (21,21 ', 21 ") in the expanded state in a known manner a areas or sectors (212) for the blood flow in the vessel (8th ) leaving free - have a cross section (211) constricted at several points. 8. Device according to one of claims 1 to 7, characterized in that the balloon tube part (2) has at its proximal end a position and blocking mechanism (5) for the radiation source (s) (1). 9. Device according to one of claims 3 to 8, wherein the individual radiation sources (1) have a hollow cylindrical shape, characterized in that the ratio of their axial extension or height (h) to their transverse axis extension or diameter (d) between 5: 1 and 1: 1, preferably from 3: 1 to 2: 1. 7 AT 405 136 B 10. Device according to one of claims 3 to 9, characterized in that at least the outer edges (132) of the individual hollow cylindrical radiation sources (1) are broken or preferably rounded or chamfered. 11. The device according to one of claims 3 to 10, characterized in that the individual hollow cylindrical radiation sources (1) at least on all outer surfaces (120,141,142,15), have a material-impermeable, but permeable to low-energy radiation covering or coating (120), which either consists of an inactive material or a material that has no long-lived radionuclides after neutron activation. 12. The apparatus according to claim 11, characterized in that the individual, hollow cylindrical radiation sources (1) have a core body (105) made of a compact, radioactive material. 13. The device according to one of claims 3 to 12, characterized in that the individual hollow cylindrical radiation sources (1) with an all around from a material-opaque, but radiation-permeable sheath from an inactive and not by neutron radiation leading to long-lasting radionuclide material surrounding core body (105) several individual parts or from a lumpy, granular or powdery or expandable, radioactive material. 14. Device according to one of claims 11 to 13, characterized in that the material-tight envelope (120) of the individual radiation sources (1) is formed with an optionally expandable shrink film. 15. The device according to one of claims 11 to 14, characterized in that the covering or coating (120) of the individual radiation sources (1) is formed with a slide-promoting material. 16. The device according to one of claims 1 to 15, characterized in that the individual radiation sources (1) or their core body (105) are formed with a pure beta emitter or a beta emitter with low or low-energy gamma emission. 17. Device according to one of claims 1 to 16, characterized in that the guide wire (6) to be introduced into the vessel (8) or permanently arranged therein is provided at its distal end (101) with a stop body (61), e.g. in the form of a thickening or ball. Including 2 sheets of drawings 8