WO2009087076A1

WO2009087076A1 - Catheter device for percutaneous interventions

Info

Publication number: WO2009087076A1
Application number: PCT/EP2009/000010
Authority: WO
Inventors: Michael Friebe; Gabriele Krombach
Original assignee: Tomovation Gmbh
Priority date: 2008-01-04
Filing date: 2009-01-05
Publication date: 2009-07-16
Also published as: DE102008019304A1

Abstract

A catheter device (1) for percutaneous interventions is illustrated and described, in particular for injections, biopsies or the like, having an outer catheter (2) and a tool for the intervention, in particular an injection needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4) of the catheter device, wherein the tool is taken up in the outer catheter (2) in a delivery state and in the delivery state the tool tip of the tool is recessed in the outer catheter (2) or aligned with the proximal end of the outer catheter (2), wherein the tool can be moved relative to the outer catheter (2) such that at least in an engagement position the tool tip protrudes past the proximal end of the outer catheter (2), wherein a stop (5) is provided for limiting the intervention depth of the tool during intervention, wherein the stop (5) has a plurality of spring legs (6) arranged in the delivery state inside the outer catheter (2) as stop means, wherein the spring legs (6) extend out and open outwards when the tool is extended, wherein the spring legs (6) protrude in a radial direction via the outer catheter (2) in the extended engagement position and wherein each spring leg (6) has at its proximal end at least one stop face (7) for bearing against body tissue in the engagement position. It is provided according to the invention that the stop face (7) bulges outwards.

Description

Catheter device for percutaneous procedures

The invention relates to a catheter device according to the common preamble of claims 1, 7, 9, 14, 16, 19, 25, 26 and 28.

Advances in molecular biology and genetic engineering in recent years have led to the development of a variety of therapeutic agents, such as angiogenesis in the ischemic myocardium, or omnipotent stem cell differentiation and myocyte differentiation into myocardial scars. Clinical studies in patients showed that therapeutic tissue concentrations of such

Substances could only be obtained after direct injection into the tissue. In this case, an injection of such substances can be carried out readily in open heart surgery. However, such operations are always associated with a considerable effort and a corresponding risk. In this context, the percutaneous injection by means of a catheter device appears simpler. The problem here is, however, that in a percutaneous injection on the catheter, a corresponding needle must be provided and the introduction of the catheter into the body, for example, on a bar or a crook to the heart the demonstration by the arteries must not lead to injury to the vessels , Another problem with percutaneous injection is that it may inadvertently pierce the heart tissue as it is injected. The unwanted piercing of the heart tissue carries the risk of the heart bag filling up with blood and subsequent compression of the heart with possible death.

Similar problems arise, for example, in percutaneous tissue removal, in which a biopsy forceps is brought by means of a catheter to the donor site.

From WO 2007/131516 Al a catheter device of the aforementioned type is known, wherein the stop is formed by banana shell-shaped spring legs and wherein the inner contour of the spring leg to the outer contour of an injection needle as

Tool is adapted. As a result, the spring legs in the supply state can be very close to the injection needle, so that there is a very space-saving design of the known catheter device, which simplifies the introduction of the known catheter device into small arteries to a considerable extent. When the injection needle is extended, the spring legs spring out, whereby the umbrella-shaped stop thus formed projects in the radial direction

CONFIRMÄΠON COPY Has extension that is larger by a multiple than the outer diameter of the outer catheter. As a result, in the engaged state, a comparatively large stop surface is provided by the unfolded spring legs, which are intended to preclude the unwanted damaging or puncturing of the body tissue during the procedure.

From WO 99/49773 A2, a catheter device with an outer catheter and an inner needle leading to an injection needle is known. On the inner catheter, a plurality of spring legs are fastened, which form a stop for limiting the depth of engagement when inserting the injection needle into a tissue after extension from the outer catheter. The spring wires are made of nitinol wire and are loop-shaped. The spring wires are folded in the direction of delivery toward the outside of the front end of the inner catheter out and against the outer catheter from the inside. Folding the spring wires allows the wires to be pushed through the outer catheter together with the inner catheter in the delivery state, with the spring wires folding back and expanding radially once they have been advanced over the outer edge of the outer catheter towards the tissue. A disadvantage of the known catheter device is that it can come to a puncture or damage to the tissue during advancement of the injection needle in spite of the measures provided for the engagement depth limitation spring wires. The resistance of the spring legs to contact with tissue often goes unnoticed by a physician. In addition, it is disadvantageous that in this known catheter device, the feeding of the catheter device into the body via small arteries is difficult.

From US 4,222,380 A a catheter device is known, wherein two wire elements are provided in the engaged state, forming a claw. The wire elements are resilient and surround a Iηjektionsnadel. The wire elements are claws intended to hold the tissue during injection or to draw it towards the needle.

Moreover, from US 2004/0199141 Al a catheter device is known, the two

Having tines, which are provided in the engaged state for anchoring the catheter device with a body tissue.

Object of the present invention is to provide a further developed catheter device of the type mentioned above, which ensures an effective depth of engagement limitation and can be introduced into the body in a simple manner. The above object is achieved in a first embodiment of the invention in that the stop surface is curved outwards, wherein, preferably, the stop surface is provided in the region of the central longitudinal axis of the spring leg, and more preferably, on the inside in the feed state facing the tool of the spring leg. In contrast to the well-known from WO 2007/131516 Al catheter device with banana shell-shaped spring legs, which are curved in the engaged state on the side against the tissue inward, in the spring legs of the catheter device according to the invention an outer curvature of the spring legs wanted to edgeless system of Ensuring spring legs in the engaged state against a tissue. In the case of banana-shell-shaped spring legs, it is possible, in the engaged state during movement of the catheter device, to result in injury to the tissue through the longitudinal edges of the spring legs resting against the tissue. In the case of the catheter device according to the invention, the spring leg is convexly curved in order to be able to reliably exclude damage. The invention also allows that spring legs are provided with differently curved stop surfaces.

The spring legs may abut against the tool in the feed state with the stop surfaces, preferably over the entire surface. This results in a space-saving construction of the catheter device according to the invention, which considerably simplifies insertion into small arteries and body openings. During extension of the tool, the spring legs can then spring open or bend outward with the proximal ends, as described in WO 2007/131516 A1. The spring legs may consist of a shape memory material, in particular of nitinol or Teflon, which ensures the automatic rebound during extension of the tool from the outer catheter.

In a preferred embodiment of the invention, the spring leg may have a flat oval-shaped cross-section at its proximal end. In particular, the spring leg may be non-circular, which allows an enlargement of the stop surface.

To provide a large stop surface available, the cross-sectional width of the spring leg at its proximal end at least a quarter to a third of the cross-sectional width, preferably at least half the cross-sectional width of the tool correspond. In particular, the cross-sectional width of the spring leg corresponds approximately to

Diameter of the tool or is even larger. Indicates the spring leg on his proximal end has a circular cross-section, so the specified cross-sectional width corresponds to the diameter of the spring leg at its proximal end. If the spring leg has a flat, oval-shaped cross-section, the specified cross-sectional width refers to the distance between the main vertices of the cross-sectional profile.

In order to exclude a puncture or damage to the tissue during surgery with great certainty, the stop surface may preferably extend uninterrupted across the width of the spring leg in a direction transverse to the central longitudinal axis of the spring leg, namely from a longitudinal edge of the spring leg over its central longitudinal axis up to the other longitudinal edge. Preferably, the spring leg is the entire surface with a flat side to rest against the tissue. In principle, however, recesses may also be provided in the abutment surface, or the abutment surface may have a net-like structure.

As with the catheter device known from WO 2007/131516 Al can be provided for extending the tool from the outer catheter within the outer catheter movable relative to the outer catheter inner catheter, the spring legs may preferably abut against the inner catheter in the feed state. The fact that the spring legs bear against the inner catheter in a gap-free manner in the feed state makes it possible to reduce the size of the catheter device according to the invention, which simplifies insertion into small orifices and arteries. For the same reason, the cross-sectional contour of the spring legs on the outer side of the spring leg to the inner contour of the outer catheter be adapted so that in the insertion state, the spring legs with the outer sides directly and preferably over the entire surface against the inner circumferential surface of the outer catheter. The result is a very compact construction of the catheter device according to the invention with a small diameter of the outer catheter.

In an alternative embodiment of the catheter device according to the invention is for

Solution of the object mentioned above provided that at least two spring legs are provided with different lengths, wherein the stopper is designed such that spring legs of different lengths on extension of the tool spring out one after the other. In this embodiment of the invention, a double stop is provided. First, the longer spring legs spring out, then the shorter ones. The longer spring legs then extend in the engaged state in the proximal direction on the proximal end of the outer catheter as the shorter spring legs, so that form two spaced abutment areas. The longer spring legs meet when extending the tool first on the tissue, which leads to a certain predetermined contact resistance during further advancement of the tool relative to the outer catheter. The higher resistance is effected by the already opposite the tissue longer spring leg. If the tool and thus the spring legs are extended even further, the longer spring legs spring back and then the shorter spring legs subsequently hit the tissue, which leads to a renewed increase in resistance against further advancement of the tool. This resistance increase is perceived by the attending physician in a simple manner, so that inadvertent advancement of the tool too far can be precluded.

The spring legs of different lengths can be arranged alternately next to each other. This results in a space-saving construction of the catheter device, whereby the pressure force acting on the tissue in the engaged state via the spring legs can be evenly distributed.

In a further alternative embodiment of the catheter device according to the invention is provided to solve the aforementioned problem that at least two Fe- thighs have different sized stop surfaces and / or that at least two spring legs have differently contoured stop surfaces.

The resistance of the fabric against penetration of the spring legs into the fabric in the engaged state is dependent, inter alia, on the size of the stop surfaces and their shape. Are in the direction of engagement in the spaced-apart stop areas provided, each forming a stop, can be adjusted by spring leg with different sized stop surfaces and / or differently contoured stop surfaces of the resistance, the tissue the various stop areas in a further feed of the tool in the direction opposes the tissue. This helps the doctor to easily recognize when the procedure is performed

Tool tip has reached a certain predetermined distance from the tissue.

For example, spring legs can be provided with different lengths, wherein the longer spring leg has a larger stop surface than the shorter spring leg. When extending the tool, the longer spring legs spring first and form a first stop area with a larger stop surface. Once the longer Spring legs come to rest against the tissue, this leads to a relatively large resistance to further advancement of the tool. This resistance is clearly perceived by the doctor. In the further extension of the tool then spring also the shorter spring legs and form a second stop area with smaller stop surfaces. When the second abutment region comes into contact with the tissue, this results in a comparatively lower resistance, whereby the attending physician can recognize the different resistances and from this can better estimate the relative position of the tool to the tissue. Due to the larger stop surface of the first spring-out spring leg damage to body tissue is reliably prevented. If the doctor feels that the first stop area has already come into contact with the tissue, it can correspondingly reduce the feed force with which the tool is advanced further. At this reduced feed force is then also ensured that there is no tissue damage when the second stop area abuts the tissue with the smaller stop surfaces.

In the feed state adjacent spring legs of different lengths may have a complementary contour to allow a space-saving arrangement of the spring legs around the tool in the area between the tool and the outer catheter. In this context, it can be provided that the longer spring leg is L-shaped and the shorter spring leg bears against the front side against the shorter leg portion of the longer L-shaped spring leg. This also allows a very space-saving arrangement of the spring legs in the outer catheter and thus a largely complete utilization of the space between the tool and the outer catheter for the arrangement of the spring legs. Preferably, the spring legs are in contact with the inner side in the feed state against the outer lateral surface of the tool and with the outer side against the inner lateral surface of the outer catheter. If the spring legs are formed like a banana shell, the inner contour of the spring legs can correspond to the outer contour of the tool at least in the region of the tool tip, wherein the spring leg can rest against the tool in a gap-free manner in the feed state, preferably over the entire inner surface of the spring leg. This contributes to a very space-saving construction of the catheter device according to the invention.

Moreover, in a further alternative embodiment of the invention for solving the above object may be provided that the spring leg has an elongated central leg portion and at its proximal end a stop surface having the head portion, wherein the width of the spring leg in the region middle leg portion in the direction of the head portion preferably decreases steadily. In the transition region between the middle leg portion and the head portion then a cross-sectional taper is provided. Due to the larger head portion, a correspondingly large stop surface can be made available, wherein the rigidity of the spring leg is reduced by the cross-sectional taper.

In order to simplify the rebound or bending of the spring legs during the extension of the tool and to reduce stresses in the spring legs, each spring leg may have at least one discharge opening. The discharge opening may be slit or circular. Moreover, a cross-sectional taper or notch of the spring leg can be provided, which facilitates the rebound or bending.

Moreover, in the engaged state, the spring leg may have a head section angled or bent relative to an elongated middle leg section, the head section having the stop surface and rebounding out of the outer catheter after the projection of a predetermined head length into the angled or bent position when the spring leg is extended with (further) increasing extension of the spring leg of the angle between the longitudinal axis of the central leg portion and the longitudinal axis of the outer catheter steadily increases with constant bending or bending of the head portion. As a result, the spring leg has at its proximal end a head region which, upon extension from the outer catheter, springs into a predetermined angular position after reaching a predetermined extension length, which does not change any further as the spring leg moves out of the outer catheter. As a result, a stop for the tissue is formed shortly after the extension of the spring leg, wherein, preferably, the angle between the head portion and the middle leg portion after rebounding of the head portion more than 60 °, preferably about 90 ° may be. Due to the different bending of the head section and the leg section relative to the central longitudinal axis of the outer catheter, it can already be ensured, after a slight extension of the spring leg, that the stop surfaces can preferably come to bear against the tissue over the whole area.

Thus, damage to the tissue can be prevented.

Moreover, the wall thickness of the spring legs can be diluted in the region of the proximal end to form a bending point. It is also possible that the spring leg is notched. In the previously described embodiments of the catheter device according to the invention, the abutment surface may preferably be provided on the inside of the spring leg which bears against the tool in the feed state. In principle, it is also possible that the stop surface is provided with respect to the feed state of the spring leg at an end face of the spring leg. For example, the spring leg may have a substantially circular cross section, wherein the stop surface is formed by an end face at the proximal end of the spring leg. The stop surface is then formed substantially flat. Also, the end face may be curved outwardly to exclude a violation of the tissue upon contact of the stop surface with the tissue. Moreover, the spring leg may have a rounded tip at its proximal end.

In order to fix the catheter device in the tissue or to prevent lateral slippage of the catheter device after application of the stop against the tissue, the spring leg can have a circular or oval-shaped cross section at its proximal end, wherein the stop surface is formed by a chamfer on the end face becomes. The spring legs then form at their proximal ends tines, which act against the tissue. Preferably, the stop surface is still large enough to prevent injury to the tissue through the edges of the abutment surfaces.

After rebounding, the spring legs can form a umbrella-shaped stop, wherein the stop surfaces can be arranged uniformly and substantially circularly around the outer catheter around. The arrangement of the spring legs in the engaged state then substantially corresponds to the arrangement of the spring legs in the known from WO 2007/131516 Al catheter device. In another embodiment, the spring legs may form a multi-tooth-like abutment after rebound, wherein abutment surfaces may be provided on both sides of the outer catheter. Further preferably, the same number of spring legs on both sides of the outer catheter is provided in order to achieve a secure abutment of the stop against the tissue in the engaged state. For the same purpose, the stop surfaces may be arranged evenly spaced apart in the engaged state.

A further embodiment of the catheter device according to the invention provides a

Pulling cable connection for adjusting the opening width of the spring legs in the engaged state before. By the traction cable can be preferably change the opening width of the spring legs after rebound within predetermined limits and thus the penetration depth of the Control tool in the tissue. It is understood that the spring legs are connected via eyelets or the like to the pull rope. In this context, the outer catheter can have at least one working channel for the tool and the spring legs, on the one hand, and at least one cable channel for the pull cable connection, on the other hand. In addition to the hauling cable connection for adjusting the width of the opening of the spring legs, alternatively or additionally, a further hauling cable connection can be provided for bending the proximal end of the outer catheter. It is understood that the outer catheter can have two cable channels in this case. The leadership tool and spring legs in the working channel on the one hand and the traction cable in a cable channel on the other hand reduces the friction when transferring the catheter device from the feed state to the engaged state and ensures that the tool can be moved relative to the outer catheter in a simple manner. The subdivision of the outer catheter into work spaces or channels leads to a reduction in the friction, which is the result of relative movements between the outer catheter and the tool or the spring legs on the one hand and the traction cable on the other hand.

The outer catheter is preferably made of a solid material having a plurality of channels. This construction contributes to a high torsional rigidity of the catheter device according to the invention. In principle, however, it is also possible to provide a plurality of inner catheters in which the tool and the spring legs as well as the traction cable (s) are guided.

The inner catheters are then placed inside the tubular outer catheter.

In order to further facilitate an engagement with the catheter device according to the invention, at least one spring leg may have at its proximal end an active or passive marker for visualization by means of MRI or CT imaging. Preferably, all spring legs are marked, wherein the marker can be provided immediately adjacent to the stop surface or in the region of the stop surface.

In particular, there are a variety of ways to design and further develop the catheter device according to the invention, reference being made on the one hand to the dependent claims and on the other hand to the following description of the invention with reference to the drawings. In the drawing show

1 is a frontal plan view of the proximal end of a catheter device of the type according to the invention in the feed state, FIG. 2 shows a perspective view of the catheter device shown in FIG. 1 in the engaged state, FIG.

3 shows a developed view of an inner catheter with a plurality of spring legs at its proximal end in a further embodiment of a catheter device according to the invention,

4 shows a schematic representation of a catheter device according to the invention with the inner catheter shown in FIG. 3 in the engaged state, FIG.

5 is a development view of an inner catheter with a plurality of

Spring legs at its proximal end in a further embodiment of a catheter device according to the invention,

6 is a schematic representation of another embodiment of a catheter device according to the invention in the engaged state,

7 shows the proximal end of a further embodiment of a catheter device according to the invention with two spring legs in the engaged state in a cross-sectional view,

FIG. 8 shows the catheter device illustrated in FIG. 7 with an end view of the proximal end of the catheter device in the delivery state, FIG.

9 shows a frontal plan view of the proximal end of a catheter device in the engaged state in a further embodiment of the invention,

10 is a frontal plan view of the proximal end of an outer catheter with a Zugseilkanal and a working channel,

11 is a frontal plan view of the proximal end of an outer catheter with two Zugseilkanälen and a working channel,

12 is a frontal plan view of the proximal end of a catheter device of the invention erf mitndungsgemäßen type with two spring legs with oval cross-section, a Zugseilkanal and a tool and 13 is a frontal plan view of the proximal end of another embodiment of a catheter device according to the invention with two spring legs of circular cross-section, a Zugseilkanal and a tool.

1 and 2 show a catheter device 1 for percutaneous interventions, in particular for injections, with an outer catheter 2 and a tool for the procedure, wherein the tool is an injection needle 3. The injection needle 3 is provided at the proximal end 4 of the catheter device 1. In a delivery state not shown in detail, the injection needle 3 is received in the outer catheter 2 and the tip of the injection needle 3 sunk in the outer catheter 2 or aligned with the proximal end of the outer catheter 2. The injection needle 3 is movable relative to the outer catheter 2 or extendable from the outer catheter 2 such that at least the tip of the injection needle 3 projects beyond the proximal end of the outer catheter 2 in an engaged state.

Incidentally, a stopper 5 is provided for limiting the depth of engagement of the injection needle 3 during the procedure, the stop 5 having a plurality of spring legs 6 arranged in the delivery state within the outer catheter 2 as a stop means, wherein the

Spring legs 6 when expanding the injection needle 3 rebound and open to the outside, the spring legs 6 in the illustrated in Fig. 2 extended engagement state in the radial direction beyond the outer catheter 2 and wherein each spring leg 6 at its proximal end at least one stop surface 7 for conditioning against a body tissue in the engaged state. Depending on how far the spring legs 6 are extended, they overflow in the radial direction via the outer catheter 2. The permissible depth of engagement is reached when the spring legs 6 rest with their stop surfaces 7 against the tissue.

Thus, it comes in the engaged state to any damage to the tissue through the abutment surfaces 7 of the spring legs 6, which are curved on the in the feed state of the injection needle 3 facing inside of the spring leg 6 provided abutment surfaces 7 to the outside. When the injection needle 3 is extended, the spring legs 6 open outwards, so that the inner side of the spring legs 6 comes into abutment against the tissue during further advancement of the injection needle 7 and an engagement depth limitation of the injection needle 3 is effected. For extending the injection needle 3 from the outer catheter 2, an inner catheter 8 is provided, which is movable relative to the outer catheter 2. In this case, the injection needle 3 is attached to the proximal end of the inner catheter 8. Preferably, the injection needle 3 can be inserted with its rear distal end into the inner catheter 8. At the proximal

End of the inner catheter 8, the spring legs 6 are provided. The spring legs 6 are fixedly connected to the inner catheter 8 and may possibly also be obtainable by multiple incision of the inner catheter 8 at its proximal end.

As is further apparent from FIG. 1, the spring legs 6 each have a flat oval-shaped cross section at their proximal ends. In this case, the cross-sectional width bi, which is determined by the distance between the two main apexes on the cross-sectional contour of a spring leg 6, approximately the outer diameter D of the injection needle 3. This allows a very large stop surface 7 realize, with the stop surface 7 transverse to the central longitudinal axis of Spring leg 6 extends uninterrupted over the inside. The spring legs 6 are in the supply state with the stop surfaces 7 directly against the injection needle 3 on, i. gap. The gap-free contact of the spring leg 6 against the tool ensures a very space-saving design, wherein the cross-sectional contour of the spring leg 6 is adapted to the inner contour of the outer catheter 2 or to the curvature of the inner circumferential surface of the outer catheter 2 on the outside 9 of the spring legs 6 , In the delivery state shown in Fig. 1, this results in a very compact construction of the catheter device 1, which facilitates insertion into a Körperöffhung or a vessel.

A percutaneous injection by means of the catheter device 1 is now carried out such that the catheter device 1 is demonstrated with its proximal end 4 of a puncture site, for example in the groin or in a crook of the arm over arteries into the heart. This is preferably done under MRI, CT or X-ray control. During the movement of the catheter device 1 within the vessels, both the injection needle 3 and the inner catheter 8 are located inside the outer catheter 2. The spring legs 6 of the stop 5 are compressed and surround the injection needle 3. When the catheter device 1 has been demonstrated to the destination is, the inner catheter 8 is pushed out of the outer catheter 2. In this case, the spring legs 6 of the stopper 5 then spring outwards. Thus, there is a deployment of the stopper 5, until the injection needle 3 is fully released, as shown in Fig. 2. The injection needle 3 can then be pushed far enough into the tissue until, due to the spring legs 6 resting against the tissue, is prevented from entering. Subsequently, the injection can take place. After the injection, the inner catheter 8 is first pulled back into the outer catheter 2. Subsequently, the outer catheter 2 can be pulled out of the body.

In Fig. 3, the proximal end of an inner catheter 10 is shown in a developed view, wherein in Fig. 3 is not shown that the inner catheter 10 is fixedly connected to an injection needle 3. The inner catheter 10 is arranged to be movable relative to an outer catheter 2 shown in FIG. 4 and is provided to extend the injection needle 3 out of the outer catheter 2.

The inner catheter 10 has spring legs 11, 12 of different lengths, so that it first comes to the rebound of the long spring legs 12 and then the short spring legs 11 when extending the injection needle 3 from the outer catheter. Due to the different length of the spring legs 11, 12, a stop 13 is formed, which has two umbrella-like abutment portions 14, 15 which protrude differently far in the proximal direction over the outer catheter 2. This is shown in Fig. 4. In this case, after piercing the injection needle 3 into the tissue, first the abutment-side abutment surfaces 16 of the longer spring legs 12 strike the tissue, which is perceived by the type of treatment as the first increase in resistance to further advancement of the injection needle 3. Upon further advancement of the injection needle 3, the longer spring legs 12 feather until stop surfaces 17 of the shorter spring legs 11 also abut against the tissue, which is perceived as a further increase in resistance. From this, the doctor can conclude that the maximum depth of engagement of the injection needle 3 has been reached.

In Figs. 3 and 4 is shown only schematically that the abutment surfaces 16, 17 are formed by end faces of the banana shell-like spring legs 11, 12. In principle, however, it is also possible for rebend of the spring legs 12 to cause the proximal ends to bend over, with the spring legs 12 abutting against the tissue in the engaged state with the inner sides bearing against the injection needle 3 in the feed state. The same applies to the shorter spring legs 11. In addition, it is possible that the stop surfaces 16, 17 are curved outwards, as shown in FIGS. 1 and 2. It is essential that on the one hand, the injury of tissue when contacting the spring legs 11, 12 is excluded. On the other hand, the change in the resistance during the advancement of the injection needle 3 into the tissue should be easily perceptible. The multiple incision of the inner catheter 10 at its proximal end results in spring legs 11, 12, which have a comparatively small width. The small width leads to a reduction in the stiffness of the spring legs 11, 12, which results in that the spring legs 11, 12 easily yield when in contact with the tissue and a tissue injury can be safely excluded.

As is further apparent from Fig. 3, the spring legs 11, 12 have different sized stop surfaces 16, 17, which also have a different contour. The larger stop surfaces 16 mean that when the injection needle 3 advances, the contact of the front stop region 14 with the tissue can not lead to tissue damage. Since the attending physician perceives the contacting as an increase in resistance, he can then reduce the feed force of the injection needle 3, so that a tissue injury despite smaller abutment surfaces 17 can be prevented even in the subsequent Inkontakttreten the second rear abutment portion 15.

Moreover, the cross-sectional contours of the spring legs 11, 12 formed complementary to each other, wherein the longer spring leg 12 is L-shaped and the shorter spring leg 11 frontally with the stop surface 17 against the shorter Schenkelab- section 18 of the longer spring leg 12 rests. This space-saving arrangement of the spring legs 11, 12 enables optimum space utilization with a small size of the catheter device Ia.

FIG. 5 shows the proximal end of an inner catheter 19 in a development view. The inner catheter 19 has three spring legs 20 which can be obtained by cutting, each spring leg 20 having a central leg section 21 and a head section 22 at its proximal end. The width b _{2 of} the spring leg 20 is minimal in the transition region between the middle leg portion 20 and the head portion 22. Moreover, the width of the spring leg 20 decreases steadily in the direction of the head portion 22. By reducing the width in the longitudinal direction of the spring leg 20, the rigidity of the spring leg 20 is reduced and the rebound easier.

It is not shown that the spring legs 20 may be bent banana cup-shaped, wherein the spring legs 20 are available by cutting a tubular inner catheter 19 at its proximal end. In principle, the spring legs 20 but also have an oval or elliptical or a circular cross section and be curved in the engaged state to the outside.

Moreover, the spring legs 20 due to the enlargement of the head portion 22 comparatively large stop surfaces 23 which are intended to prevent penetration of the spring legs 20 in the tissue. It is also possible that the spring legs 20 are truncated cone-shaped with hemispherical head portions 22 are formed.

As is further apparent from FIG. 5, the spring legs may have relief openings 24 for stress relief during rebounding or bending up.

In Fig. 6, a catheter device Ic is shown in the engaged state, in which an inner catheter 25 has at its proximal end four spring legs 26 which in the engaged state have an opposite an elongated central leg portion 27 angled or bent head portion 28, wherein the head portion 28 has the stop surface and upon extension of the spring leg 26 springs out of the outer catheter 2 after reaching a predetermined head length Ii in the angled position. As the extension proceeds, the angle α i between the longitudinal axis Xi of the middle leg section 27 and the longitudinal axis X _{2 of} the outer catheter 2 steadily increases while the angled section or bend of the head section 26 remains constant. After rebounding the head section 28, the angle α ₂ between the central longitudinal axis X _{3 of} the head section 28 and the central longitudinal axis Xi of the middle leg section 27 may be more than 60 °, preferably approximately 90 °. To facilitate rebounding, the spring leg 26 may be thinned and / or notched in the transition region between the middle leg portion 27 and the head portion 28 to form a bend. By the rebound of the head portion 28 ensures that the spring legs 26 come even with incomplete extension of the outer catheter 2 with a maximum stop surface against the tissue to the plant. A tissue damage is excluded.

FIG. 7 schematically shows the proximal end of a catheter device 29 in a cross-sectional view in the engaged state. The spring legs 30 are guided displaceably in the interior of an outer catheter 2 and have a circular cross section, which results from FIG. 8. In the engaged state shown in FIG. 7, the spring legs 30 abut against the tissue on the face side, abutment surfaces 31 being formed by bevels of the spring legs 30 on the end faces. The spring legs 30 may have a circular or oval-shaped cross-section. In the embodiment shown in FIG. The contact surfaces 31 are essentially planar, but in principle they can also be curved outward. After rebounding, the spring legs 30 form a multi-toothed stop 32, the stop faces 31 being arranged on both sides next to the injection needle 3. This ensures anchoring of the catheter device 29 in or on the tissue in the engaged state.

As is further apparent from FIG. 7, the spring legs 30 in the engaged state have a substantially horizontally extending middle section 33 and a substantially vertically extending front section 34, wherein the front section 34 has a height hi of approximately 2 to 4 mm, preferably of about 3 mm, may have. In this case, the proximal edges of the adjacent spring legs 30 are aligned. The length h of the central portions is between 3 to 4 mm, wherein the distance aj between the central longitudinal axes X _{4 of} the sections 34 may be about 10 to 15 mm. If the spring legs 34 have a circular cross section, the diameter can be between 1 and 1.5 mm. The inner diameter of the outer catheter 2 is then about 3 mm.

According to FIG. 8, the spring legs 30 and the injection needle 3 lie against one another on the inner sides and against the inner wall of the outer catheter 2 on the outer sides. As a result, the position of the spring legs 30 and the injection needle 3 within the outer catheter 2 is determined. Not shown is that the spring legs 30 can be arranged differently than in Fig. 8 and laterally next to the injection needle 3, so that the spring legs 30 and the injection needle 3 can be arranged in a cross-sectional view on a common straight line through the centers of the Spring leg 30 and the injection needle 3 extends. The cross-sectional shape of the outer catheter 2 can then be adapted accordingly, so that the position of the spring legs 30 and the injection needle 3 is fixed within the outer catheter 2. It is understood that despite the mutually fitting spring legs 30 and the injection needle 3 and the associated positional fixation of the spring leg 30 and the injection needle 3 in the outer catheter 2, a mobility of the spring legs 30 and the injection needle 3 must be ensured to extend out of the outer catheter 2.

Moreover, the spring legs 30 may have an oval or elliptical cross-section. Also, a reticule-like arrangement of spring legs 30 around the injection needle 3 is possible around or a circular arrangement, as shown in Fig. 9. In the catheter device 35 shown in FIG. 9, 8 spring legs 36 are provided, the structure of which may correspond to the spring legs 30 shown in FIG. there the spring legs 36 are arranged such that in the engaged state, the distance a ₂ between the centers of the abutment surfaces 37 of adjacent spring legs 36 may be about 3 to 5 mm. The vertical distance a ^ and the horizontal distance & _A between the centers of horizontally or vertically opposed spring legs 36 is preferably about 10 to 15 mm. Moreover, the spring legs 36 surround the injection needle 3 in the engaged state umbrella-like and are arranged tightly packed in the delivery state around the injection needle 3 in the outer catheter 2.

10 and 11, an outer catheter 38 is shown in a front view from the front, which has a working channel 39 and a Zugseilkanal 40 and according to FIG. 11 a working channel 39 and two Zugseilkanäle 40, 41 as shown in FIG. The Zugseilkanal 40 is provided for a Zugseilverbindung, which is to allow the adjustment of the Öffhungsweite of spring legs, wherein the spring legs are guided within the working channel 39. In the working channel 39, the tool is guided in addition to the spring legs. The second traction cable channel 41 provided in the outer catheter shown in FIG. 11 is provided for a further traction cable connection, which may be provided for controlling the alignment of the proximal end of the outer catheter 2. If a pull rope is provided for adjusting the opening width of the spring legs, it is understood that the spring legs may have eyes or the like through which the pull rope is passed. About the traction cable, it is then possible to set the Öffhungsweite the spring leg and thus the maximum depth of engagement manually from the distal end of the outer catheter 2 ago.

As is apparent from FIGS. 10 and 11, the outer catheter 38 consists of a solid material, in which the channels 39, 40, 41 are incorporated. In principle, it is also possible, of course, to provide a tubular outer catheter which has hoses in the interior in which the tool and the spring legs on the one hand and the pull rope or the pull cables on the other hand are guided. Thus, a low-friction feed of the tool together with the spring legs in the working channel 39 and the simple adjustment of the opening width of the spring leg and / or the curvature of the outer catheter via the guided in the Zugseilkanälen 40, 41 ropes is possible.

As can be seen from FIGS. 12 and 13, the outer catheter 38 shown there can have two spring legs 6, 30 in addition to the injection needle 3 and a traction cable channel 40, the injection needle 3, the traction cable channel 40 and the spring legs 6, 30 are arranged within the tubular outer catheter 38. In the in Figs. 12 and 13 illustrated embodiments, the outer catheter 38 is thus not made of a solid material.

As will be apparent from Fig. 2, markers 42 may be provided to determine the exact position of a spring leg by MRI or CT imaging techniques.

As a result, the depth of engagement of the injection needle 3 can be determined with high accuracy. Preferably, the marker 42 is arranged in the immediate vicinity or along the stop surface 7, so that the distance of the stopper 5 to the adjacent tissue can be determined with high accuracy.

Claims

claims:

1. catheter device (1) for percutaneous procedures, in particular for injections, biopsies or the like, with an outer catheter (2) and a tool for the intervention, in particular a hypodermic needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4) the catheter device,

wherein the tool is received in a delivery state in the outer catheter (2) and the tool tip of the tool in the delivery state in the outer catheter (2) sunk or aligned with the proximal end of the outer catheter (2), - wherein the tool relative to the outer catheter (2) is movable such that at least the tool tip protrudes beyond the proximal end of the outer catheter (2) in an engaged state,

- Wherein a stop (5) for limiting the depth of engagement of the tool is provided during the procedure, - wherein the stop (5) has a plurality of in the supply state within the outer catheter (2) arranged spring legs (6) as a stop means,

- The spring legs (6) spring down during the extension of the tool and open to the outside,

- Wherein the spring legs (6) in the extended engaged state in the radial direction over the outer catheter (2) and survive

- Wherein each spring leg (6) at its proximal end at least one stop surface (7) for abutment against a body tissue in the engaged state, characterized in that the stop surface (7) is curved outwardly.

2. Catheter device according to claim 1, characterized in that the spring leg (6) has at its proximal end a flat oval-shaped cross-section.

3. A catheter device according to claim 1 or 2, characterized in that the cross-sectional width (bi) of the spring leg (6) at its proximal end at least one third of the cross-sectional width (B), preferably at least half the cross-sectional width (B), of the tool at the proximal thereof End corresponds.

4. Catheter device according to one of the preceding claims, characterized in that the abutment surface (7) transverse to the central longitudinal axis of the spring leg (6) under without any rupture over the engaged in the state against the tissue inside of the spring leg (6).

5. Catheter device according to one of the preceding claims, characterized in that for extending the tool from the outer catheter (2) within the outer catheter (2) relative to the outer catheter (2) movable inner catheter (8) is provided and that the spring legs ( 6) abut directly against the tool in the feed state.

6. Catheter device according to one of the preceding claims, characterized marked, that the cross-sectional contour of the spring legs (6) on the outer side (9) of the spring legs (6) complementary to the inner contour of the outer catheter (2) is formed.

7. Catheter device (Ia) for percutaneous interventions, in particular for injections, biopsies or the like, with an outer catheter (2) and a tool for the intervention, in particular an injection needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4 ) of the catheter device,

- Wherein a stop (13) for limiting the depth of engagement of the tool is provided during the procedure, - wherein the stop (13) a plurality of in the supply state within the outer catheter (2) arranged spring legs (11, 12) as a stop means,

- wherein the spring legs (11, 12) rebound during extension of the tool and open to the outside,

- Wherein the spring legs (11, 12) in the extended engagement state in the radial direction over the outer catheter (2) survive and

- Each spring leg (11, 12) has at its proximal end at least one stop surface (16, 17) for bearing against a body tissue in the engaged state,

- in particular according to one of the preceding claims, characterized that at least two spring legs (11, 12) are provided with different lengths, wherein the stop (13) is formed such that spring legs (11, 12) of different length during extension of the tool spring out one after the other and in the engaged state in the proximal direction differently over the Proximal end of the outer catheter (2) survive.

8. Catheter device according to claim 7, characterized in that spring legs (11, 12) of different lengths are arranged alternately next to each other.

9. Catheter device (Ia) for percutaneous interventions, in particular for injections, biopsies or the like, with an outer catheter (2) and a tool for the intervention, in particular an injection needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4 ) of the catheter device,

wherein the tool is received in a delivery state in the outer catheter (2) and the tool tip of the tool is sunk in the delivery state in the outer catheter (2) or aligned with the proximal end of the outer catheter (2),

- wherein the tool is movable relative to the outer catheter (2) such that at least the tool tip protrudes beyond the proximal end of the outer catheter (2) in an engaged state, - a stop (13) is provided for limiting the engagement depth of the tool during the procedure,

- Wherein the stop (13) has a plurality of in the supply state within the outer catheter (2) arranged spring legs (11, 12) as a stop means,

- The spring legs (11, 12) in the extended engagement state in the radial direction over the outer catheter (2) and survive

- Each spring leg (11, 12) has at its proximal end at least one stop surface (16, 17) for abutment against a body tissue in the engaged state,

- In particular according to one of the preceding claims, characterized in that at least two spring legs (11, 12) have different sized stop surfaces (16, 17) and / or that at least two spring legs (11, 12) differently contoured stop surfaces (16, 17) ,

10. Catheter device according to one of the preceding claims, characterized in that at least two spring legs (11, 12) are provided with different lengths and that the longer spring leg (12) has a larger stop surface (16) than the shorter spring leg (11).

11. Catheter device according to one of the preceding claims, characterized in that the contours of the supply state adjacent spring legs (11, 12) of different lengths are complementary to each other.

12. Catheter device according to one of the preceding claims, characterized in that the longer spring leg (12) is L-shaped and that the shorter spring leg (11) abuts the front side against the shorter leg portion (18) of the longer L-shaped spring leg (12) ,

13. Catheter device according to one of the preceding claims, characterized in that the cross-sectional contour of the spring legs (11, 12) complementary to the outer contour of the tool in the region of the tool tip is formed, wherein the spring legs (11, 12) in the supply state substantially gap-free against the tool issue.

14. A catheter device for percutaneous procedures, in particular for injections, biopsies or the like, with an outer catheter and a tool for engagement, in particular a hypodermic needle, a biopsy forceps, electrodes or the like, at the proximal end of the catheter device, - wherein the tool in a feed state in External catheter added and the

Tool tip of the tool is sunk in the delivery state in the outer catheter or aligned with the proximal end of the outer catheter,

wherein the tool is movable relative to the outer catheter in such a way that at least the tool tip projects beyond the proximal end of the outer catheter in an engaged state,

wherein a stop is provided for limiting the depth of engagement of the tool during the procedure,

- Wherein the stop has a plurality of spring legs (20) arranged in the feed state within the outer catheter as a stop means, - wherein the spring legs (20) rebound during the extension of the tool and open to the outside, - The spring legs (20) in the extended engagement state in the radial direction over the outer catheter and survive

- Each spring leg (20) has at its proximal end at least one stop surface (23) for abutment against a body tissue in the engaged state, - in particular according to one of the preceding claims, characterized in that the spring leg (20) has an elongated central leg portion ( 21) and at its proximal end a stopper surface (23) having head portion (22), wherein the width of the spring leg (20) in the region of the central leg portion (21) towards the head portion (22) preferably decreases steadily.

15. Catheter device according to one of the preceding claims, characterized marked, that the spring leg (20) has at least one discharge opening (24) for stress relief.

16. Catheter device (Ic) for percutaneous interventions, in particular for injections, biopsies or the like, with an outer catheter (2) and a tool for the intervention, in particular an injection needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4 ) of the catheter device,

- Wherein a stop (5) for limiting the depth of engagement of the tool is provided during the procedure, - wherein the stop (5) has a plurality of in the feed state within the outer catheter (2) arranged spring legs (26) as a stop means,

- The spring legs (26) rebound during extension of the tool and open to the outside,

- The spring legs (26) in the extended engagement state in the radial direction over the outer catheter (2) and survive

- Each spring leg (26) has at its proximal end at least one stop surface for abutment against a body tissue in the engaged state, - In particular according to one of the preceding claims, characterized in that the spring leg (26) in the engaged state has an opposite an elongated central leg portion (27) angled or bent head portion (28), wherein the head portion (28) has the stop surface and during extension of the Spring leg (26) springs out of the outer catheter (2) after reaching a predetermined head length (U) in the angled or bent position and wherein with further increasing extension of the spring leg (26) of the angle (αi) between the longitudinal axis

(Xi) of the middle leg portion (27) and the longitudinal axis (X ₂ ) of the outer catheter (2) steadily increases with constant bending or bending of the spring-loaded head portion (28).

17. Catheter device according to one of the preceding claims, characterized in that after the rebound of the head portion (28) of the angle (0C ₂ ) between the longitudinal axis (X ₃ ) of the head portion (28) and the longitudinal axis (X ₁ ) of the central leg portion ( 27) more than 60 °, preferably about 90 °.

18. Catheter device according to one of the preceding claims, characterized in that the wall thickness of the spring leg (26) is thinned in the region of the proximal end to form a bending point and / or that the spring leg (26) is notched.

19. Catheter device (29) for percutaneous interventions, in particular for injections, biopsies or the like, with an outer catheter (2) and a tool for the intervention, in particular an injection needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4) the catheter device,

- wherein the tool is received in a delivery state in the outer catheter (2) and the tool tip of the tool in the delivery state in the outer catheter (2) is lowered or aligned with the proximal end of the outer catheter (2),

- wherein the tool relative to the outer catheter (2) is movable such that at least the tool tip in an engaged state beyond the proximal end of the outer catheter (2),

- Wherein a stop (32) is provided for limiting the depth of engagement of the tool during the procedure,

- wherein the stop (32) has a plurality of in the supply state within the outer catheter (2) arranged spring legs (30) as a stop means, - The spring legs (30) spring down during the extension of the tool and open to the outside,

- wherein the spring legs (30) in the extended engagement state in the radial direction on the outer catheter (2) survive and - each spring leg (30) at its proximal end at least one stop surface (31) for abutment against a body tissue in the engaged state

- In particular according to one of the preceding claims, characterized in that the stop surface (31) on an end face of the spring leg (30) is provided.

20. Catheter device according to one of the preceding claims, characterized in that the end face is curved outward.

21. Catheter device according to one of the preceding claims, characterized in that the spring leg (30) has at its proximal end a circular or oval-shaped cross section and that the stop surface (31) is formed by a bevel on the front side.

22. Catheter device according to one of the preceding claims, characterized in that form the spring legs (6, 11, 12, 20, 26, 36) after rebounding a umbrella-shaped stop (5, 13).

23. Catheter device according to one of the preceding claims, characterized in that the spring legs (30) after rebounding form a multi-toothed stop (32), wherein the stop surfaces (31) on both sides of the outer catheter (2) are arranged.

24. Catheter device according to one of the preceding claims, characterized in that the stop surfaces (7, 16, 17, 23, 31) in the engaged state (7, 16, 17, 23, 31, 37) are arranged uniformly spaced from each other.

A catheter device for percutaneous procedures, in particular for injections, biopsies or the like, with an outer catheter (38) and a tool for the intervention, in particular a hypodermic needle, a biopsy forceps, electrodes or the like, at the proximal end of the catheter device, wherein the tool is received in a delivery state in the outer catheter (38) and the tool tip of the tool is sunk in the delivery state in the outer catheter (38) or aligned with the proximal end of the outer catheter (38),

wherein the tool is movable relative to the outer catheter (38) so that at least the tool tip projects beyond the proximal end of the outer catheter (38) in an engaged state,

- Wherein the stop has a plurality of in the supply state within the Außenkathe- ters (38) arranged spring legs (6, 30) as a stop means,

- The spring legs (6, 30) rebound during extension of the tool and open to the outside,

- wherein the spring legs (6, 30) in the extended engagement state in the radial direction beyond the outer catheter (38) and - each spring leg (6, 30) has at its proximal end at least one stop surface for abutment against a body tissue in the engaged state

- In particular according to one of the preceding claims, characterized in that at least one Zugseilverbindung for adjusting the opening width of the spring legs (6, 30) is provided in the engaged state.

A catheter device for percutaneous procedures, in particular for injections, biopsies or the like, with an outer catheter (38) and a tool for the intervention, in particular an injection needle, a biopsy forceps, electrodes or the like, at the proximal end of the catheter device,

- wherein the tool is received in a delivery state in the outer catheter (38) and the tool tip of the tool in the delivery state in the outer catheter (38) sunk or aligned with the proximal end of the outer catheter (38),

- wherein the tool relative to the outer catheter (38) is movable such that at least the tool tip in an engaged state beyond the proximal end of the outer catheter (38),

- Wherein the stop has a plurality of in the supply state within the outer catheter arranged spring legs (6, 30) as a stop means, - The spring legs (6, 30) rebound during extension of the tool and open to the outside,

- wherein the spring legs (6, 30) project in the extended engagement state in the radial direction over the outer catheter (38) and - each spring leg (6, 30) has at its proximal end at least one abutment surface for abutment against a body tissue in the engaged state,

- In particular according to one of the preceding claims, characterized in that the outer catheter (38) has at least one working channel (39) for the tool and the spring legs and at least one Zugseilkanal (40, 41) for a Zugseilverbindung.

27. Catheter device according to one of the preceding claims, characterized in that the outer catheter (38) consists of a channels (39, 40, 41) having solid material.

28. A catheter device (1) for percutaneous interventions, in particular for injections, biopsies or the like, with an outer catheter (2) and a tool for the intervention, in particular an injection needle (3), a biopsy forceps, electrodes or the like, at the proximal end (4 ) of the catheter device,

- wherein the tool relative to the outer catheter (2) is movable such that at least the tool tip in an engaged state beyond the proximal end (4) of the outer catheter (2),

- Wherein a stop (5) is provided for limiting the depth of engagement of the tool during the procedure,

- wherein the stop (5) has a plurality of in the supply state within the outer catheter (2) arranged spring legs (6) as a stop means,

- The spring legs (6) during extension of the tool rebound and open to the outside, - wherein the spring legs (6) in the extended engagement state in the radial direction on the outer catheter (2) and survive - Each spring leg (6) has at its proximal end at least one stop surface (7) for bearing against a body tissue in the engaged state,

- In particular according to one of the preceding claims, characterized in that at least one spring leg (6) preferably at its proximal end an active or passive marker (42) for visualization of the spring leg (6) by means of MRI or CT imaging.

29. Catheter device according to one of the preceding claims, characterized in that the marker (42) is provided immediately adjacent to the stop surface (7) or in the region of the stop surface (7).