DE3712082A1 - Implantable electrode probe with extendable and retractable screwing electrode - Google Patents

Abstract

The invention relates to an implantable electrode probe having a flexible feed line which comprises an insulating sheath and a tubular electrical conductor mounted in the insulating sheath, the electrical conductor being operatively connected electrically to a sleeve-shaped electrode head and a fixation spiral which can be screwed out by a relative movement between the flexible feed line and an auxiliary element arranged in this flexible feed line being mounted in the electrode head. Unscrewing of the fixation spiral is effected in that, by rotating the flexible feed line, an axial movement is achieved by the effect of force upon the auxiliary element, because the fixation spiral is arranged in the electrode head so as to be fixed against rotation and axially displaceable.

Description

The invention relates to an implantable Electrode probe with an insulated flexible lead according to the preamble of patent claim 1.

With a generic electrode probe (US 44 63 765) it is known that there is an electrical inside conductive lead spiral by a Insulating jacket is insulated from the body tissue and the electrical connection between the Pulse generator and the electrically active Electrode surface at the distal end of the electrode head produces a further spiral belt arrangement, which in turn is a lumen for receiving a Guide wire (stylet) has. This inner one Spiral band arrangement is at the distal end in Active connection with a screw-in spiral, which from the Electrode head by means of a thread device can be unscrewed. After introducing the whole Electrode with screw screw in the back is characterized in that at the proximal end of the probe Torque applied to the inner spiral belt assembly the screw-in spiral from the electrode head unscrewed. This is said to be the desired one achieved mechanical fixation of the probe in the body tissue will. Because the inner spiral band arrangement in the probe remains, the entire electrode probe is relatively stiff and heavy, which leads to an undesirable irritation of the Tissue near the distal part of the Leads electrode head. If you put that Spiral belt arrangement to reduce weight and the rigidity from thin strips of tape, so if you simultaneously lower the torsional strength, one Measure that is as direct a transfer as possible counteracts the torque. Depending on the length of the Electrode probes are between because of the compromise Material thickness of the tape strips and flexibility too several turns at the proximal end required to the screw-in spiral by the desired amount unscrew. The use of a Spiral belt arrangement for unscrewing the Screw-in spiral at the distal end of the electrode probe has another disadvantage: the Spiral belt arrangement itself and the required Clearance to the electrical supply spiral, in whose lumen it is arranged enlarged  inevitably the entire diameter of the feed line. But this is undesirable, especially if there are two in one vein Probes are used in two-chamber systems should.

The object of the present invention is to overcome the disadvantages to avoid the electrode probe described above and to create an electrode probe that is one if possible has light and flexible supply line and their Diameter is as small as possible.

The object of the invention is achieved in that the fixation coil 7 , which is located within a sleeve-shaped electrode head 2, is arranged in a rotationally fixed and axially displaceable manner, is in a backward position during the insertion phase and is screwed into an out of the by screwing on an auxiliary element 14 Electrode head 2 outstanding end position can be brought. The non-rotatable and axially displaceable arrangement is preferably formed in that a pin 10 or a molded body is attached to the screw-in spiral 7 or to an auxiliary body 8 firmly connected to it, which can be moved in an axially extending groove 9 or a slot in the electrode head sleeve 3 . The auxiliary body 8 can, for. B. consist of a plastic part which is glued to the screw 7 or otherwise firmly connected. A solution is also proposed in which the axially extending groove runs in the auxiliary body 8 and the pin or another guide body is fastened in the electrode head sleeve 3 .

In a further embodiment of the invention it is proposed that the non-rotatable and axially displaceable connection between the fixation coil 7 and the electrode head sleeve 3 by any positive connection element, for. B. hexagon cylinder and hexagon sleeve is formed.

In all of the above arrangements, stops are provided which ensure that the fixation coil 7 can only be moved by an intended dimension 1 , for. B. by the groove length 1 , which corresponds to the dimension by which the fixation coil 7 is to be screwed out of the electrode head sleeve 3 into its end position.

Depending on the design of the electrode probe according to the invention, the electrical feed line 20 can be in direct electrical connection with the electrode head sleeve 3 and part of the electrode head sleeve 3 on its front and / or outside 17 can be in electrical contact with the body tissue. In this case, it is advantageous if the fixation coil 7 is electrically insulated, either by an insulation layer or by being mounted in the electrode head sleeve 3 in such a way that it has no electrical contact with one another. It is also conceivable that the inside of the electrode head sleeve 3 is provided with an insulation layer. On the other hand, it is also conceivable that the electrically conductive lead spiral 20 is loosely mounted in the insulating sleeve 4 of the lead and that it is in an electrically operative connection with the fixation spiral 7 and / or the electrode head sleeve 3 . It is also proposed that the fixation coil 7 is electrically insulated and the electrode head sleeve 3 has electrically active surfaces and is in electrical connection with the supply coil 20 . A combination of an electrically active screw-in spiral 7 and an electrically active electrode head sleeve 3 is alternatively proposed according to the invention.

The auxiliary element 14 , which causes the axial movement of the fixation coil 7 by the action of force, is inventively by a torsionally rigid wire, for. B. formed a stylet, as is usually used to stiffen the electrode probe during the introductory phase. In the present case, however, the stylet is equipped at its distal end with a device for positive connection 16 with the support body 5 . It is also proposed that the auxiliary element 14 be formed by a torsionally rigid spiral band or spiral wire arrangement which can simultaneously represent the electrical supply line and which is equipped with a lumen for receiving a stylet. While the stylet is removed in any case after fixation, the latter embodiments of the auxiliary element 14 can remain in it as an integrated component of the electrode probe.

Another important characteristic of the electrode probe according to the invention is a movement element 22 , which is formed by a screw-nut connection and which is on the one hand connected to the fixation spiral 7 or the auxiliary body 8 in active connection and on the other hand is arranged rotatably and axially fixed relative to the electrode head sleeve 3 .

It is assumed that a support body 5 is secured against rotation by means of the positively inserted stylet or by means of a spiral band or spiral wire arrangement by holding the auxiliary elements 14 at the proximal end or, in the case of the stylet, itself by a course deviating from a straight line non-rotatably. The support body 5 is by any axial bearing element 15 , which, for. B. is represented by a groove-pin connection ( 13 and 12 ) or by an O-ring 19 used simultaneously for sealing against body fluid, axially fixed relative to the electrode head sleeve 3 , but rotatably arranged in it.

An auxiliary body 8 or, in another embodiment, the fixation spiral 7 is operatively connected to the support body 5 such that a relative movement between the two bodies has an axial movement with respect to one another. In the event that the fixation spiral 7 reaches over the support body 5 , this is achieved in that the spiral acts as a nut in which the support body 5 can move with thread replicas or even a single thread or pin 11 as a screw. In another embodiment, auxiliary body 8 and support body 5 are in direct thread engagement with one another, it being irrelevant which body the nut and which body the screwing function is assigned to. Preferably, the thread pitch of the combination of effects, referred to overall as the movement element 22, is selected to be the same as that of the fixation spiral 7 .

Regardless of which embodiment is chosen the principle of operation is as follows:

The electrode probe is inserted into the electrode head sleeve retracted fixation coil 7 in the usual manner using a stylet 14 , which can be bent as desired, into a heart chamber. The distal end of the fixation coil 7 lies so far in the protective area of the electrode head 2 that no injury to the vein intima and no unforeseen snagging can occur. Depending on the design of the probe, orienting electrical measurements can be carried out when the tip of the electrode is in contact with cardiac tissue. The stylet 14 is now brought into a form-fitting operative connection 16 by further advancement with the support member 5 and, if necessary, secured against twisting. The entire electrode probe 1 is then rotated in a direction of rotation corresponding to the direction of rotation of the fixation coil 7 . The electrode head 2 , which also rotates as a result, transmits the rotary movement to the auxiliary body 8 , which is known to be connected in a rotationally fixed manner to the fixation spiral 7 , so that the latter performs the same rotary movement. Through the threaded connection between the proximal end of the fixation scroll 7 and the support body 5, which is displaceable axially in the electrode head yes sleeve 3 not, the fixation helix 7 receives an axial feed. Since the slope of the movement element 22 corresponds to that of the fixation spiral 7 , the distal part of the fixation spiral 7 screws itself evenly into the heart tissue. The axial limit of the motion space of the auxiliary body 8 (through the flute length 1 z. B.) not only the degree of leakage of the fixation helix 7 is limited, but also at the same time their angle of rotation.

A reversal of the entire process, that is, a screwing back and a retraction of the fixation coil 7 into the protected position is also possible at any time.

To further explain the invention reference is made to the Drawings referenced in which various Designs of the electrode are shown in simplified form. It shows

Fig. 1 is a view of a distal end of the electrode probe with a section through the electrode head, wherein the fixation coil is in the retracted position

FIG. 2 shows a view of a distal end of the electrode probe with a section through the electrode head in another embodiment variant, the fixation coil being in the retracted position.

Fig. 3 is a partial view of the electrode head sleeve with an embodiment of the support body and the axial bearing.

Fig. 4 is a partial view with another embodiment variant of the electrode head.

, As far as shown in detail in FIGS. 1 to 4, referred to the distal end of an electrode probe having 1, which has a bezeichneen with 2 electrode head. The electrode head 2 has an electrically conductive electrode head sleeve 3 , which is designed as a contact surface 17 at the distal end of the electrode head. The electrode head sleeve 3 and the electrical lead spiral 20 are surrounded by an insulating sleeve 4 . An auxiliary body 8 is mounted in a rotationally fixed and axially displaceable manner within the electrode head sleeve 3 . The auxiliary body 8 , on the other hand, is firmly connected to the fixation coil 7 , which is located in the distal part of the electrode head sleeve 3 in a retracted position such that its distal spiral wire end is almost flush with the front surface of the electrode head sleeve 3 .

The rotationally fixed and axial connection between the auxiliary body 8 and the electrode head sleeve 3 is formed by a pin 10 which is mounted in a groove 9 . The groove length 1 corresponds to the amount by which the fixation coil 7 can be screwed out of the electrode head sleeve 3 .

Furthermore, a support body 5 is located within the electrode head sleeve 3 , which is axially fixed by means of an axial bearing element 15 , but is rotatably mounted. The axial bearing element 15 is formed by a pin 12 which is inserted through a bore in the electrode head sleeve 3 and an annular groove 13 in the support body 5 . Seals 18 and 19 are provided for sealing against body fluid.

As shown in Fig. 1, the fixation coil 7 is in a threaded connection with the support body 5 , which is engaged by the engagement of a pin 11 . A stylet with a screwdriver-shaped end serves as an auxiliary element 14 and has a slot in the support body 5 in a positive connection 16 . In the illustration shown, the stylet, as an auxiliary element 14, takes over the rotational forces which act on the support body 5 . The lead spiral 20 is fixedly connected to the electrode head sleeve 3 .

Fig. 2 shows another embodiment according to the invention. Here, the movement element 22 is formed by a screw-nut connection between the support body 5 and the auxiliary body 8 , the threaded device 23 being arranged between the two bodies. The O-ring 19 is arranged to seal against body fluid.

Another possibility for designing the movement element 22 is shown in FIG. 3. Here, the fixation spiral 7 engages within the support body 5 in a pin 24 and thus forms the thread device. In the exemplary embodiment shown in FIG. 3, the axial bearing element 15 is formed by the O-ring 19 , which in this case performs two functions, namely to absorb and seal axial forces.

Fig. 4 shows an embodiment in which the auxiliary element 14 is formed by the loose in the insulating sleeve 4 lead spiral 20 ' . In this case, the lead spiral 20 'is firmly connected to the support body 5 , it being necessary to imagine that all the parts located inside the electrode head sleeve 3 are electrically connected to one another.

Claims (22)

1. Implantable electrode probe with a flexible supply line, which has an insulating sleeve and a tubular electrical conductor mounted in the insulating sleeve, the electrical conductor being electrically operatively connected to a sleeve-shaped electrode head, and wherein in the electrode head - by a relative movement between the flexible supply line and an auxiliary element arranged in this flexible supply line - a screw-off fixation spiral is mounted, characterized in that the fixation spiral ( 7 ) is arranged in the electrode head ( 2 ) in a rotationally fixed and axially displaceable manner and in that the axial movement takes place by the action of force on the auxiliary element ( 14 ). 2. Implantable electrode probe according to claim 1, characterized in that the fixation coil ( 7 ) by means of a pin-groove connection ( 9 and 10 ) is arranged in a rotationally fixed and axially displaceable manner in the electrode head ( 2 ). 3. Implantable electrode probe according to one of claims 1 or 2, characterized in that the fixation coil ( 7 ) by means of an auxiliary body ( 8 ) is arranged in a rotationally fixed and axially displaceable manner. 4. Implantable electrode probe according to one of the preceding claims, characterized in that the auxiliary body ( 8 ) is arranged in the electrode head ( 2 ) in a rotationally fixed and axially displaceable manner by means of form-fitting connecting elements. 5. Implantable electrode probe according to one of the preceding claims, characterized in that the axial thrust path ( 1 ) is limited by stops. 6. Implantable electrode probe according to one of the preceding claims, characterized in that the axial thrust path ( 1 ) is limited by stops between the pin ( 10 ) and groove ( 9 ) or in the region of the connecting elements. 7. Implantable electrode probe according to one of the preceding claims, characterized in that the fixation spiral ( 7 ) is arranged in an electrically insulated manner in the electrode head ( 2 ). 8. Implantable electrode probe according to one of the preceding claims, characterized in that the electrode head ( 2 ) has electrically active contact surfaces ( 17 ). 9. Implantable electrode probe according to one of the preceding claims, characterized in that the auxiliary element ( 14 ) made of a torsionally rigid wire, for. B. there is a stylet. 10. Implantable electrode probe according to one of the preceding claims, characterized in that the auxiliary element ( 14 ) consists of a torsionally rigid spiral tape or spiral wire arrangement. 11. Implantable electrode probe according to one of the preceding claims, characterized in that the auxiliary element ( 14 ) is in electrical operative connection with the electrode head sleeve ( 3 ). 12. Implantable electrode probe according to one of the preceding claims, characterized in that in the electrode head ( 2 ) a movement element ( 22 ) consisting of a screw-nut connection is mounted, on the one hand with the fixation spiral ( 7 ) or the auxiliary body ( 8 ) is in operative connection and on the other hand is rotatably and axially fixed with respect to the electrode head ( 2 ). 13. Implantable electrode probe according to one of the preceding claims, characterized in that the fixation spiral ( 7 ) is designed as a nut or screw element. 14. Implantable electrode probe according to one of the preceding claims, characterized in that the auxiliary body ( 8 ) is designed as a nut or screw element. 15. Implantable electrode probe according to one of the preceding claims, characterized in that the nut or screw element which is in operative connection with the fixation spiral ( 7 ) or the auxiliary body ( 8 ) is designed as a support body ( 5 ) which is by means of an axial bearing element ( 15 ) is held in the electrode head ( 2 ). 16. Implantable electrode probe according to one of the preceding claims, characterized in that the axial bearing element ( 15 ) consists of a groove-pin connection ( 13 and 12 ). 17. Implantable electrode probe according to one of the preceding claims, characterized in that the support body ( 5 ) and the distal end of the auxiliary element 14 can be connected in a rotationally fixed manner by means of a positive connection ( 16 ). 18. Implantable electrode probe according to one of the preceding claims, characterized in that the auxiliary element ( 14 ) is removable. 19. Implantable electrode probe according to one of the preceding claims, characterized in that the support body ( 5 ) by means of a sealing body, for. B. an O-ring ( 19 ), is sealed in the electrode head ( 2 ). 20. Implantable electrode probe according to one of the preceding claims, characterized in that the sealing element or the sealing body is designed as an axial position for the support body ( 5 ). 21. Implantable electrode probe according to one of the preceding claims, characterized in that the movement element ( 22 ) consisting of a screw-nut connection has the same pitch as the fixation spiral ( 7 ). 22. Implantable electrode probe according to one of the preceding claims, characterized in that one or more spring contacts (e) produce the electrical operative connection between the electrode head sleeve ( 3 ) and / or fixation coil ( 7 ) and support body ( 5 ) (manufacture).