SE0900936A1 - Catheter and method for manufacturing such catheter - Google Patents

Description

a conductive plug 8 is built up in the hole 7, 7a, b. Several plugs can advantageously builds up at the same time and the plug can be built up without separate manual handling.

Most advantageously, the plug is built up with electroplating, which means that the construction can electrically controlled from connections to the conductor end of the catheter. The control can be used to check which plug or plugs are building up. In addition, this procedure provides a more stable mechanical and electrical connection between the inner conductor and the outer ring than if the plug is made, for example, of conductive epoxy or the like.

In a particularly advantageous embodiment, the catheter comprises at least one channel 2b which extends in the longitudinal direction of the catheter, in which a conductor or a wire carrier is arranged.

The conductor carrier 3 may consist of an elongate flexible printed circuit board rolled perpendicular to its longitudinal extent, where at least one conductor is arranged on the printed circuit board.

The invention also relates to a method for manufacturing such catheters, the method comprising one step then on the inner connecting element 5a, b a conductive plug 8 is built up in the hole 7, 7a, b, typically with electroplating.

Brief description of the figures Fig. 1 shows a catheter to which the invention can be applied Fig. 2 shows a first manufacturing step in a first embodiment of the invention Fig. 3 shows a second manufacturing step in the first embodiment of the invention Fig. 4 shows a third manufacturing step in the first embodiment of the invention Fig. 5 shows a first manufacturing step in a second embodiment of the invention Fig. 6 shows a second manufacturing step in the second embodiment of the invention Description of preferred forms of dehydration Fig. 1 shows a catheter with a design suitable for use with the invention.

The catheter comprises a rod 1 in a resilient material through which two channels 2a, b run circular cross section. The channels extend in the longitudinal direction of the rod and the first channel 2a has a larger cross-sectional area than the second channel 2b. The first channel may be intended for or discharge of liquid or gas and this channel is illustrated in the figure as empty. In the other a resilient electrical conductor carrier 3 is inserted in the duct. The conductor carrier 3 is formed by a narrow, rectangular, fl Exemplary printed circuit board that has been rolled up over most of its length to a pipe. The tubular part of the flexible printed circuit board has then been filled with adhesive as in hardened state is resilient. The printed circuit board then forms one rod which is inserted into the other the channel.

The printed circuit board is double-sided and extends on the side of the board that forms the inside of the bar. leader in the longitudinal direction of the card. At the upper end of the card, which extends a distance outside the catheter upper end, the card is not rolled up but flat and here the members are available and can be connected to electronic equipment. Different conductors extend from different longitudinal directions of the card the upper end from the upper end of the card and are connected at their other end to inner connecting rings Sa, b.

The inner connection rings Sa, b are arranged on the side of the visible circuit board which in rolled-up condition is arranged on the outside of the conductor carrier.

Holes 7 a, b are arranged on the catheter which extend from the outside of the catheter to the other the channel at the two places where the inner connecting rings are arranged. Around the catheter extends outer connecting rings 6a, b which are electrically connected to the inner ones via the holes connecting rings Sa, b. With common technology, separate conductors in the former had to lead wires drawn through the channels of the catheter from its upper end to the respective outer connecting ring and connected to each individual connection ring. With the described device is achieved separately electrical contact to each outer connection ring with a single wire carrier 3. Obviously can other types of conductors are used with the invention than the described conductor carrier, but that year particularly advantageous.

The outer connecting rings are electrodes that can be used for sensor end needle or for apply electric current for various medical purposes. Obviously, the connecting rings Sa, b, 6a, b, which in the fi gures are illustrated as ring-shaped elements, may also be formed on other way. Ring-shaped elements, however, have the advantage that it does not matter how they are rotated relatively the rest of the catheter, electrical contact is still achieved.

Fig. 2 shows in greater detail a cross section through the catheter 1 in a first manufacturing step in a first embodiments of the invention. The cross section through the catheter extends through one of the holes 7 and this can be seen in the figure as an opening in the otherwise round catheter. The opening 7 extends to the second channel 2b and separately from this the first channel 2a is also illustrated. In the i cross-section round the first channel, the line carrier 3 is arranged. The wire carrier is also round and fills the main part of the channel. An inner surface extends around the outer surface of the cable carrier connecting ring and this is exposed to the surroundings through the opening 7.

Fig. 3 shows a second manufacturing step in the first embodiment of the invention therein electroplating metal laid on the inner connecting ring. Metal laid on the ring is built up and finally fills the entire hole 7 and forms a plug 8. The plug 8 extends to the catheter outer surface and is electrically connected to the inner connection ring.

The electroplating is performed by immersing the catheter in an electrolyte with metal ions.

Thereafter, electrical current is connected to that of the conductors on the wire carrier on the inside of which connection ring a metal plug must be built up. By connecting power to all the conductors on the wire carrier, metal plugs can be built up on all the inner connection rings at the same time.

If needed, the plugs can be built up individually with different metals or at different heights each plug by directing the current to the respective conductor below the electroplating process.

The plugs are built naturally from the part of the inner connecting rings which is exposed by the hole 7 and the plug assumes the shape of the hole. The plug then forms one with the inner connecting ring cohesive metal elements and no problems can arise with play between the interior the connecting ring and the plug.

Fig. 4 shows a third manufacturing step in the first embodiment of the invention. In the third the step has a separate metal ring 6 threaded over the catheter so that it abuts the plug S.

Since the catheter is resilient, a ring 6 can be pressed on which has a slightly smaller inner diameter than the outer diameter of the catheter in the unloaded position. The ring will then be naturally pressed against the plug and ends up in electrical contact with it.

In an illustrated embodiment, the plug is constructed so that it extends beyond the catheter outer surface. With a ring 6 with a corresponding receiving hole or annular receiving recess on the inside of the ring, the ring can be made to lock in position in the middle of the inner the connection ring and when manually mounting rings, the fitter receives a tactile indication that the ring is in position.

Fig. 5 shows a first manufacturing step in a second embodiment of the invention. In the other In the embodiment, the outer connecting ring 6c does not consist of a detachable separate element which in the first embodiment, without the ring being applied to the catheter with one of olika your different possible application methods.

Possible application methods include spraying or brush painting of conductive paint, casting or plating with metals or other conductive materials. A plating method that can be used described in EP0985333B1 and with this a layer of metal can be laid on the catheter with the desired shape on the formed electrode. Regardless of the application method used, it extends the metal layer not only on the outer surface of the catheter but also reaches into the hole 7. The metal layer can thus reach and also extend over the portion of the inner connecting ring that is exposed in the hole.

Especially when applying thin metal layers, the strength of the outer connecting ring limited. Especially in the joint between the inner connecting ring and the applied metal layer on inside the hole, breakage may occur and no electrical contact may be achieved between the interior the connecting ring and the metal on the inside of the hole. Other critical points are the edge portion of the hole at the connection to the outer surface of the catheter.

Fig. 6 shows a second manufacturing step in the second embodiment of the invention. Here is on a method corresponding to the electroplating step in the first embodiment a plug 8 is constructed in the hole. The metal plug mainly fills the hole and is built up from the applied metal layer.

The plug thus forms an element connected to the metal layer and forms both mechanically as an electrically part of the metal layer. The plug therefore guarantees electrical connection between it the outer connecting ring and the inner one. In addition, it provides improved stability and strength, so that none mechanical fractures occur.

When the plug is built up with electroplating, the outer connection ring will also be the same process steps thicker. After the plating has been going on for so long that a stable electrical connection has been achieved between the inner connecting ring and the deposited thin outer ring the thickness of the metal layer on the outer ring up at about the same speed as with the plug.

Claims (8)

A catheter having at least one outer electrical connecting member (6, 6a-c) disposed on the outside of the catheter, which is connected to a conductor (4a, b) extending within the catheter along at least part of the length of the catheter, where the outer connecting member ( 6, 6a-c) are electrically connected to an inner electrical connection element (Sa, b) on the conductor, and where a hole (7, 7 a, b) is provided on the surface of the catheter extending to the inner connection element (Sa, b). ), characterized in that on the inner connecting element (Sa, b) there is a conductive plug (8) built up in the hole (7, 7a, b). A catheter according to claim 1, characterized! that the plug is constructed with electroplating. A catheter according to claim 1 or 2, characterized in that the outer connecting element (6, 6a-c) consists of a separate annular element which is electrically connected to the plug with abutment. A catheter according to any one of the preceding claims, characterized in that the catheter comprises at least one channel (2b) extending in the longitudinal direction of the catheter, in which the conductor is arranged. A catheter according to claim 4, characterized in that a conduit carrier (3) is arranged in the channel best consisting of an elongate fl visible printed circuit board perpendicular to its longitudinal extent, where at least one conductor is arranged on the printed circuit board. A method of manufacturing a catheter, wherein the catheter is arranged to receive at least one outer electrical connection element (6, 6a-c) on the outside of the catheter, which is connectable to a conductor (4a, b) extending inside the catheter along at least part of the length of the catheter, where the outer connecting element (6, 6a-c) is electrically connected to an inner electrical connecting element (Sa, b) on the conductor, and where a hole (7, 7a, b) is provided on the surface of the catheter extending to the inner connecting element (Sa, b), characterized in that on the inner connecting element (Sa, b) a conductive plug (8) is built up in the hole (7, 7a, b). A method according to claim 6, characterized in that the plug (8) is built up with electroplating. A method according to claim 7, characterized in that the plug is built up by immersing the catheter in a solution with at least metal salt and current is connected to the conductor which is electrically connected to the inner connecting element (Sa, b).