WO2004052215A1 - Device for implanting occlusion means - Google Patents

Abstract

The invention relates to a device for implanting occlusion means (2) using a guide wire (7), whose distal end (6) comprises a tapering transition section (8) with a predetermined breaking point (15), said section being surrounded by a helical compression spring (9). The helical compression spring (9) is pretensioned and supported at its proximal end (10) at least indirectly on the guide wire (7), to sever the predetermined breaking point (15) and at its distal end (11) at least indirectly on the occlusion means (5). The helical compression spring (9) comprises at least one first longitudinal section (16), in which the distance (A1) between two neighbouring coils is greater than in a second longitudinal section (17), to improve the access of blood to the predetermined breaking point (15). The predetermined breaking point (15) is preferably electrolytically corrodable or consists of a biodegradable material.

Description

 Device for implanting occlusion agents

The invention relates to a device for implanting occlusion agents according to the features in the preamble of claim 1.

The treatment of intracranial aneurysms by neuroradiological forms of therapy is state of the art. A catheter is inserted subcutaneously from the groin into the vascular system and the aneurysm is probed. The aneurysm can be filled by applying embolization materials. This removes the hemodynamic pressure from the vessel wall in order to avoid the risk of an aneurysm rupture and associated brain bleeding.

Platinum micro coils are preferably used as occlusion agents for embolization in neuroradiology. A particular problem in the context of these so-called micro-spirals is the separation of the occlusion means from the carrier system after their placement. Are known both electrolytic (EP 726 745 B1) and mechanical (DE 93 20 840 111) separation processes. In mechanical separation processes, certain coupling elements are required, which are relatively complex to manufacture on the one hand and on the other hand where premature, unwanted decoupling of the occlusion agent can easily occur, which leads to incorrect positioning and, in the worst case, to brain embolism. A possibly sharp-edged coupling element, which can lead to injuries at the implantation site, can also remain at the distal end of the carrier system. Another disadvantage with mechanical detachment systems is that relative movements, for example rotary movements, are required to detach the occlusion agent. There is a risk that the occlusion agent will shift. Furthermore, such systems in the detachment segment are relatively stiff, so that handling can lead to vascular wall injuries and probing of the aneurysm through the highly tortuous brain vessels is not possible.

In the electrolytic detachment process, a stainless steel section of, for example, a Teflon-coated guide wire is separated distally from the occlusion agent by electrolysis. Electrolysis results from the application of a positive direct current between 0.5 mA and 2 mA. The negatively charged electrode is connected with a needle and grounded to the patient. The electrolytic separation takes place within a period of about 10 seconds and a few minutes, the actual separation being indicated by a sudden increase in the voltage to 3.5 to 7.0 volts. In practice, however, it has been shown that fluctuations occur in the detachment time and that the voltage does not necessarily increase suddenly, so that the disconnection cannot be reliably recognized by the surgeon in some cases. This may be due to the fact that the stainless steel section has been severed corrosively, but there is still an electrically conductive connection and therefore there is no discernible change in resistance that causes the voltage to rise. As a result, direct current is unnecessary is applied for a long time without the surgeon being shown that the occlusion agent has already been removed. Another problem is that even with the electrolytic detachment at the predetermined breaking point at the distal end of the guide wire, sharp-edged projections remain, which can also lead to injury to the vessel wall.

EP 726 745 B1 discloses a device for implanting occlusion coils with a guide wire, which has a single, discrete, electrolytically separable sacrificial member, which is provided at the distal end of a core wire. The distal end of the core wire tapers and is surrounded for stabilization by a helical spring which is permanently connected to the core wire at its proximal end and is supported on the occlusion means at its distal end. Although it is possible for blood to access the electrolytically separable sacrificial member through the turns of the helical spring, it is considered disadvantageous that the access of blood is impeded by the usually tightly wound turns of the helical compression spring.

Proceeding from this, the object of the invention is to provide a device for implanting occlusion means, in which the access of blood to the predetermined breaking point is improved through a helical compression spring surrounding the transition section.

This object is achieved by a device with the features of claim 1.

The radial plane spanned by the predetermined breaking point lies in the first longitudinal section of the helical compression spring. With this configuration, unimpeded access of blood to the predetermined breaking point is possible without the blood exchange being restricted by long distances. The first length section and the predetermined breaking point are arranged at the distal end of the transition section. This area is appropriate if the transition section tapers to a point, so that the region, which is particularly electrolytically corrodible Predetermined breaking point has a small diameter. Electrolytic weakening with subsequent spring force separation is particularly quick in this area.

According to the invention, it is provided that the helical compression spring is not designed uniformly over its entire length, but has at least one first length section in which the distance between two adjacent turns is greater than in a second length section. By increasing the distance between two adjacent turns in this first length section, the access of body fluid, i.e. from blood to the predetermined breaking point, so that the exchange of blood at the predetermined breaking point, which is necessary in particular for the electrolytic separation, is ensured.

The predetermined breaking point can be designed to be electrolytically corrodible according to the features of patent claim 2.

Furthermore, according to the features of claim 3, it is also possible to produce the predetermined breaking point from a biodegradable material. The synthetically produced polymers based on glycol (PGA) and lactic acid (PLA) are particularly suitable as biodegradable materials. Other biodegradable polymers are poly (epsilon-caprolactone), poly (beta-hydroxybutyrate), poly (p-dioxanone), polyanhydrides, polyester urethane and polyorthoesters. Poly-L-lactide (PLLA), polyglycolide, poly-D, L-cactide (PDLLA) can also be used as a biodegradable material.

The predetermined breaking point can also be designed in such a way that the transition section, with the incorporation of a biodegradable material, is attached to the proximal end of the occlusion agent in a positive or non-positive manner, the biodegradable material functioning as a kind of adhesive that erodes when it comes into contact with blood and releases the transition section. If the spring force emanating from the helical compression spring overcomes the forces prevailing in the predetermined breaking point, the occlusion agent is separated from the transition section. In the case of electrolytically corrodible predetermined breaking points, the occlusion agent is separated by a combination of two mechanisms: first, the predetermined breaking point is weakened by electrolytic corrosion, whereupon the occlusive agent is torn off from the distal end of the transition section by supplying mechanical energy, namely the spring force emanating from the helical compression spring, and then is pushed away. Pushing away also has the advantage that the helical compression spring extends through the relief and preferably projects beyond the distal end of the transition section, so that the predetermined breaking point lies protected inside the helical compression spring. Due to this push effect, the usually very sharp predetermined breaking point does not pose a danger to the immediately adjacent vessel walls and can be removed safely from the implantation space by withdrawing the guide wire.

Although the advantages of the device according to the invention particularly come into play when the predetermined breaking point is weakened by blood entry, it is of course also possible to provide alternative predetermined breaking points which can be separated without the entry of blood. Among other things, this can be glued predetermined breaking points, e.g. can be solved by supplying thermal energy. Known detachment methods by supplying electricity, laser radiation or vibrations are also possible. Likewise, positively or non-positively designed predetermined breaking points are conceivable, which can be activated, for example, by activating so-called memory alloys, e.g. Nitinol, can be solved. It is also conceivable that non-positive connections are provided in which, for example, a biocompatible polymer clamps the distal end of the transition section, the polymer releasing this end with the application of energy so that the occlusion agent can be separated under the influence of the spring force.

Another advantage of the invention is that by pushing the occlusion agent away from the predetermined breaking point, the occlusion agent is abruptly separated, so that in the event of an electrolytic weakening, the predetermined breaking point place the electrolytic separation as a significant voltage fluctuation registered by the surgeon, so that he has certainty about the completion of the separation process.

In the embodiment of claim 4, a first longitudinal section and the predetermined breaking point are arranged offset to one another in the axial direction. This configuration can be advantageous if a plurality of first length sections are provided alternating with second length sections, so that a certain blood exchange can take place through the inside of the helical compression spring, blood entering and exiting through the first length sections with a larger winding spacing.

This configuration is particularly important when the turns in the second length section are wound very tightly, that is to say the axial distance between the turns is very small or even approaches zero, so that the passage of blood in this length section is largely ruled out. The features of patent claim 5 relate to such a configuration, the device having one or more second longitudinal sections in which the turns are placed on a block, that is to say they abut one another. Due to the lack of spring travel, these windings cannot exert any spring force, so that in this configuration the windings effective for the spring force lie exclusively in the first longitudinal section.

The distance between two adjacent turns in the sense of the invention relates exclusively to spring arrangements not bent or bent about their longitudinal axis, but to helical compression springs in their unloaded, elongated configuration. The distal end of the helical compression spring is preferably designed such that the spring force can be applied to the occlusion means as axially as possible. In the case of a flat radial contact surface of the occlusion means, this can be achieved by reducing the slope on the outgoing turn of the helical compression spring, so that the spring axis is at right angles on the contact surface. This final Section of the helical compression spring is not to be understood as a second longitudinal section in the sense of the invention, but merely as a functionally dependent support area in which the winding spacing can be reduced depending on the configuration of the connection body. Longitudinal sections in the sense of the invention lie between these end regions, which may be adapted to the connecting bodies.

The distance between two adjacent turns is measured according to the distance measured within the surface line of the helical compression spring. The surface line of the helical compression spring used in the context of the invention can be continuous or discontinuous in its course, that is to say also have jumps, in particular when transitioning from a first length section to a second length section. Helical compression springs with a continuous surface line can be, for example, conical, double-conical or barrel-shaped helical compression springs, which may have a cylindrical intermediate part. In particular, due to the different functionality of the individual length sections, the outside diameter of the helical compression spring in the first length section can at least partially deviate from the outside diameter of the second length section, that is to say it can be larger or smaller on a part or have a completely different course (claim 6).

The outer diameter of the helical compression spring is preferably in the order of 0.1 mm to 2 mm (claim 7).

The helical compression springs can have an inconsistent wire diameter which both changes continuously over the entire longitudinal extent of the helical compression spring and also fluctuates as a function of the length sections, as is the subject of patent claim 8. In the case of inconsistent wire diameters, different distances between adjacent turns can also result from the wire diameter itself, while the pitch or the pitch of the helical compression spring remains the same. According to the features of claim 9, the helical compression spring is made of a non-circular wire. The wire can have, for example, an oval or also angular cross section. In particular, the cross section can be rectangular, with a flattened wire, particularly in the confined space, depending on the configuration, being able to exert higher spring forces than a round wire.

An advantageous diameter range for the wire, in particular the round wire, of the helical compression spring is between 10 μm and 0.5 mm (claim 10).

A particularly economical to produce helical compression spring is seen in the features of claim 11, according to which the first longitudinal section is formed by strain hardening of a metallic helical compression spring. The helical compression spring according to the invention can be formed, for example, from a cylindrical helical compression spring of constant winding spacing or with a constant pitch, a first length section being elongated beyond the material-specific yield point, so that work hardening takes place.

In addition to this particularly economical production of suitable helical compression springs, it is also possible within the scope of the invention that the first longitudinal section of the helical compression spring consists of a different material than the second longitudinal section (claim 12). It is conceivable that the helical compression spring consists at least partially, that is to say in a first or second length section, of a non-electrolytically corrodible metal (claim 13).

However, it is also possible to provide the material from which the helical compression spring is made with an electrically insulating coating, regardless of whether the material itself is electrolytically corrodible or not (claim 14). In addition to metallic materials, at least partial areas or longitudinal sections of the helical compression spring can consist of an electrically non-conductive polymer (claim 15)

In order to control the positioning of the implant and the distal end of the guide wire, the helical compression spring can at least partially be designed to be X-ray visible (claim 16). For example, by using X-ray visible materials for the helical compression spring or suitable particles are embedded in the material of the helical compression spring or are part of an electrically insulating coating.

The invention is explained in more detail below on the basis of exemplary embodiments shown schematically in the drawings. Show it:

Figure 1 shows an aneurysm bag in cross section, in which an occlusion agent is inserted through a catheter;

FIG. 2 shows a greatly enlarged illustration of the distal end of an endovascular guidewire to which an occlusion device is attached;

Figure 3 shows another embodiment of the device according to the invention as shown in Figure 2;

Figure 4 is a cylindrical helical compression spring with inconsistent wire diameter;

Figure 5 shows a double-cone helical compression spring with inconsistent

Wire diameter and

Figure 6 shows a partial section of a further embodiment of a helical compression spring with a non-circular wire cross-section.

FIG. 1 shows a device 1 for implanting occlusion means 2. The device 1 is guided in a catheter 3, which in this embodiment is introduced into the aneurysm 4. The occlusion means 2 is a wire helix 5 which is introduced into the aneurysm 4 through the catheter 3. The occlusion means 2 or the wire helix 5 is fastened with its proximal end to a guide wire which is pushed through the catheter 3.

FIG. 2 shows the distal end 6 of the guide wire 7 in a greatly enlarged illustration. The guide wire can be surrounded with an insulating coating for electrical insulation or can be provided with a shrink tube. The distal end 6 has a tapered, conically configured transition section 8, which is surrounded at its distal end by a helical compression spring 9. The proximal end 10 of the helical compression spring 9 is firmly connected to the transition section 8, for example welded. The distal end 11 of the helical compression spring 9 bears against the proximal end 12 of the occlusion means or the wire helix 5, the proximal end 12 being provided with an end cap 13 attached to the wire helix 5 to avoid vascular lesions after detachment from the guide wire 7. The distal end 14 of the transition section 8 has a very small cross section. This distal end 14 of the transition section 8 functions as a predetermined breaking point 15. The predetermined breaking point 15 can, for example, be designed to be electrolytically corrodible or consist of a biodegradable material.

The radial plane of the predetermined breaking point 15, denoted by R, is located in a first length section 16 of the helical compression spring 9. This first distal length section 16 adjoins a proximal second length section 17 of the helical compression spring. The first length section 16 and the second length section 17 differ by the different distances A1, A2 of two adjacent turns of the respective length sections 16, 17. The distance A1 in the first length section 16, that is to say the clear width, in the direction of the surface line (not shown) the helical compression spring 9 is measured, is several times larger than the distance A2 in the second length section 17. This makes access from blood to the predetermined breaking point 15, which is particularly important in the case of electrolytically corrodible predetermined breaking points or in the case of predetermined breaking points made of biodegradable materials. After the weakening of the predetermined breaking point 15, the helical compression spring 9 arranged under tension between the guide wire 7 and the proximal end 12 of the occlusion means 2 pushes the occlusion means 2 away, so that the predetermined breaking point 15 lies completely inside the helical compression spring 9 and injuries to the vessel walls are avoided.

The embodiment in FIG. 3 differs from the embodiment shown in FIG. 2 in that a further first length section 18 is provided on the helical compression spring 19 used. In this embodiment, which is identical in its other components, first length sections 16, 18 and second length sections 17, 20 alternate, so that the access of blood into the interior of the helical compression spring 19 is further improved. For example, it is conceivable that the blood flow in the first length section 18 enters the interior of the helical compression spring 19, penetrates the annular space in the region of the second length section 17 and can thus flow to the predetermined breaking point 15 in the axial direction and exits again radially between the turns of the first length section 16 ,

FIG. 4 shows an embodiment of a cylindrical helical compression spring 21 with an inconsistent wire diameter. The wire diameter D is smaller in the first length sections 22 than in the central area of the helical compression spring 21, this area forming the second length section 23. Because of the larger wire diameter D, the distance A2 between two adjacent turns in the second length section 22 is smaller than in the first length sections 22.

The embodiment in FIG. 5 shows a barrel-shaped helical compression spring 24 with an inconsistent wire diameter. The wire diameter D increases from the ends of the helical compression spring 24 to the center. in the In contrast to the helical compression spring 21 shown in FIG. 4, however, the first longitudinal section 25 is not in the region of the ends of the helical compression spring 24, but in the central region, whereas the second longitudinal sections 26 are arranged at the ends. With a helical compression spring 24 configured in this way, the outer diameter AD1, AD2 is different in each radial plane, in particular it is larger in the first length sections 25 than in the second length sections 26.

The embodiment in FIG. 6 shows a helical compression spring 27 made of flat wire. The helical compression spring 27 has a first length section 28 and a second length section 29. In the second length section 29, the distance A2 between two adjacent turns is smaller than the distance A1 between two adjacent turns of the first length section. The longitudinal sections 28, 29 are made of different materials. The wire cross section is out of round. In the second length section 29 the wire cross section is square, in the first length section 28 the wire cross section is rectangular and larger than in the second length section 29. Because of the different materials and different geometries, the spring properties of the individual length sections 28, 29 are different. In particular, the windings effective for the spring force lie in the first longitudinal section 28.

REFERENCE NUMBERS

1 - device

2 - occlusion device 3 - catheter

4 - Aneurysm

5 - wire helix v. 2

6 - distal end of 7

7 - guidewire v. 1

8 - transition section from 7

9 - helical compression spring

10 - proximal end of 9

11 - distal end of 9

12 - proximal end of 2, 5 13 - end cap at 5 14 - distal end of 8th

15 - predetermined breaking point v. 1

16 - first longitudinal section from 9

17 - second length section from 9

18 - first longitudinal section from 19 19 - helical compression spring

20 - second section of v. 19

21 - helical compression spring

22 - first longitudinal section from 21

23 - second section of v. 21

24 - helical compression spring

25 - first longitudinal section from 24

26 - second length section from 24

27 - helical compression spring

28 - first longitudinal section from 27

29 - second length section from 27 A1 - Distance between adjacent turns in the first length section

A2 - Distance between adjacent turns in the second length section

AD1 - outer diameter of 25

AD2 - outer diameter of 26

D - wire diameter

R - radial plane of 15

Claims

claims

1. Device for implanting occlusion means, the occlusion means (2, 5) at the distal end (6) of an endovascular guidewire

(7) which has at its distal end (6) a tapered transition section (8) surrounded by a helical compression spring (9, 19, 21, 24, 27) with a predetermined breaking point (15), the helical compression spring (9, 19, 21, 24, 27) for separating the predetermined breaking point (15) with its proximal end (10) at least indirectly on the guide wire (7) and its distal end (11) at least indirectly on the occlusion means (2, 5) under pretension characterized in that the helical compression spring (9, 19, 21, 24, 27) has at least one first longitudinal section (16, 18, 22, 25, 28) in which the distance (A1, A2) between two adjacent turns is greater than in a second length section (17, 20, 23, 26, 29), the radial plane (R) of the predetermined breaking point (15) being in the first length section (16) of the helical compression spring (9) and the first length section (16) and the Predetermined breaking point (15) at the distal end (14) of the transition section

(8) are arranged.

2. Device according to claim 1, characterized in that the predetermined breaking point (15) is electrolytically corrodible.

3. Device according to claim 1, characterized in that the predetermined breaking point (15) consists of a biodegradable material.

4. Device according to one of claims 1 to 3, characterized in that a first longitudinal section (18) and the predetermined breaking point (15) are arranged offset to one another in the axial direction.

5. Device according to one of claims 1 to 4, characterized in that the windings effective for the spring force lie in the first longitudinal section (16, 18, 22, 25, 28).

6. Device according to one of claims 1 to 5, characterized in that the outer diameter (AD1) of the helical compression spring (24) in the first length section (25) at least partially deviates from the outer diameter (AD2) of the second length section (26).

7. Device according to one of claims 1 to 6, characterized in that the outer diameter (AD1, AD2) of the helical compression spring (9, 19, 21, 24, 27) is between 0.1 mm and 2 mm.

8. Device according to one of claims 1 to 7, characterized in that the wire diameter (D) of the helical compression spring (24) in the first length section (25) is larger than in the second length section (26).

9. Device according to one of claims 1 to 8, characterized in that the helical compression spring (27) is made at least in sections from a non-circular wire.

Device according to one of claims 1 to 9, characterized in that the wire of the helical compression spring (9, 19, 21, 24, 27) has a diameter between 10 µm and 0.5 mm.

11.Device according to one of claims 1 to 10, characterized in that the first longitudinal section (16, 18, 22, 25) is formed by strain hardening of a metallic helical compression spring (9, 19, 21, 24).

12. Device according to one of claims 1 to 11, characterized in that the first length section (28) of the helical compression spring (27) consists of a different material than the second length section (29).

13. Device according to one of claims 1 to 12, characterized in that the helical compression spring consists at least partially of a non-electrolytically corrodible metal.

14. Device according to one of claims 1 to 13, characterized in that the helical compression spring is provided with an electrically insulating coating.

15. Device according to one of claims 1 to 14, characterized in that the helical compression spring consists at least partially of an electrically non-conductive polymer.

16. Device according to one of claims 1 to 15, characterized in that the helical compression spring is at least partially X-ray visible.