DE102021100688A1 - Electromedical Electrode - Google Patents

Abstract

The invention addresses improvements in the technical field of electromedical electrodes. For this purpose, an electromedical electrode (1) is proposed which has at least one anchoring means (2) at its distal end (3), which consists of printed circuit board material (Fig. 1).

Description

The invention relates to electromedical electrodes which have at least one anchoring means at their distal end.

Electromedical electrodes of the type mentioned above are used, for example, as so-called transcutaneous electromedical electrodes and/or as temporary myocardial electrodes and are laid through the skin of a person to be treated to a target tissue, for example a muscle and/or a nerve, in order to apply electromedical stimulation pulses to the deliver target tissue and/or receive electromedical body signals and/or physiological parameters and/or signals from sensors from or on the target tissue and transmit them to an evaluation unit connected to the electrode.

An application example of such electromedical electrodes is, for example, the use on external heart pacemakers in order to temporarily monitor the heart function of people after heart operations and/or to support it if necessary.

In order to be able to attach the electromedical electrodes in the target tissue of the person, the previously known electromedical electrodes have at least one anchoring means at their distal end.

The object of the invention is to provide an electromedical electrode of the type mentioned at the outset, the handling and production of which is simplified and which enables the implementation of further properties and/or functions.

To solve the problem, an electromedical electrode with the features of the first independent claim is proposed. In particular, in order to solve the problem with an electromedical electrode of the type mentioned at the outset, it is proposed that the at least one anchoring means consists of printed circuit board material, in particular printed circuit board foil.

To solve the problem, an electromedical electrode with the features of the second independent claim is also proposed. In particular, in order to solve the problem with an electromedical electrode of the type mentioned at the outset, it is proposed that the electromedical electrode have a base carrier which consists of printed circuit board material, in particular printed circuit board foil. Such a base support can simplify the production of the electromedical electrode and promote the implementation of further properties and/or functions.

In one embodiment of the electrode, it is provided that it has a base support and at least one anchoring means, which consist of printed circuit board material, in particular printed circuit board foil.

The printed circuit board material of the at least one anchoring means and/or the base support can comprise a layered structure. With a layered structure, the printed circuit board material can be assembled in such a way that it has the properties required for the respective application. For example, it is possible to combine a stable layer with a flexible layer in the layer structure of the printed circuit board material in order to obtain a flexible and at the same time resistant printed circuit board structure. Furthermore, the layer structure can also include at least one electrically conductive layer.

For the application of the electrode inside the body, it can also be advantageous if the printed circuit board material has an outer layer made of biocompatible material. The outer layer can completely seal off the printed circuit board material from the outside. Contact surfaces, for example an electromedical contact pole, can of course be free of the outer layer and not covered by it.

The outer layer can consist of polyurethane and/or silicone, for example. The outer layer can be created in the printed circuit board manufacturing process or in a subsequent coating process.

In one embodiment of the electrode it is provided that the anchoring means is in the form of a pull-out safeguard. In this way, the at least one anchoring means can be used for particularly reliable fixation of the electrode in or on the target tissue.

In one embodiment of the electrode, at least one anchoring means is hook-shaped and/or zigzag-shaped and/or designed as a barb. At least one anchoring means of the electrode can be designed as a tab. The at least one anchoring means can comprise at least two, preferably at least three, webs which are arranged in such a way that they form a pull-out protection. Two or three webs of at least one anchoring means can be connected to one another, have a curved and/or angled course and/or a cross-sectional enlargement of a base support of the Elect form rode and/or produce a hook-shaped or barb-shaped outer contour of the at least one anchoring means.

In order to prevent tissue from growing through the at least one anchoring means of the implanted electrode, at least one anchoring means can have at least one membrane with which an intermediate space between structures, for example between webs, of the anchoring means is closed. Such a membrane can be used, for example, in the case of an anchoring means designed as a tab and/or comprising webs. In the case of anchoring means designed as tabs, it can be advantageous if at least one tab, preferably each tab, has a membrane. Such a membrane makes it possible to avoid traumatic removal of the electrode from the target tissue, which would be a concern if the anchoring agent grows into the tissue.

The membrane can be more flexible than the structures of the anchoring means surrounding it and/or more flexible than, for example, than the previously mentioned base support of the electrode. This can enable reliable anchoring of the anchoring means despite the presence of a membrane in the target tissue. The flexible membrane can yield to the tissue. In this way, a type of form fit can result between the tissue and the anchoring means when the electrode is implanted, without the tissue growing through the intermediate space closed by the membrane.

In one embodiment of the electrode, the membrane consists of a more flexible material than the surrounding structures of the anchoring means, for example a biocompatible material. The membrane can be made of polyurethane and/or silicone, for example. The at least one membrane can be formed, for example, by the aforementioned outer layer of the printed circuit board material. In this way, the membrane can be produced comparatively easily in the printed circuit board production process or also in a subsequent coating process.

Furthermore, the at least one anchoring means can have an application needle at its free end. With the aid of the application needle, the at least one anchoring means can be pierced at least superficially into the target tissue in order to anchor the electrode in the target tissue. The application needle can be severed after the anchoring agent has been introduced into the target tissue.

If the electrode has at least one electronic functional element, specific electromedical functions can still be carried out directly on or on the electromedical electrode. For example, it is possible for the electrode to have a processing module as at least one electronic functional element, which is set up, for example, for the pre-processing of signals. Furthermore, the electromedical electrode can also have a communication module as at least one electronic functional element. This communication module can enable the transmission of signals, measured values and/or physiological variables from the electrode to a receiving and/or evaluation unit. The communication module can be set up for wired and/or wireless communication.

In a preferred embodiment of the electrode, it has at least one sensor. The electrode can have, for example, an acceleration sensor and/or a physiological sensor and/or a biosensor as at least one sensor. Physiological sensors and/or biosensors can be used to detect inflammation, for example. For example, a movement of the target tissue and/or a movement of the electrode can be detected with the aid of an acceleration sensor. For example, it is possible to use an acceleration sensor on the electrode to record wall movements of a heart.

At least one sensor of the electrode can be arranged on the at least one anchoring means. It is also possible that at least one sensor of the electrode is arranged adjacent to the at least one anchoring means. At least one sensor of the electrode is preferred here at a distal end of the electrode and/or a region of the electrode that is adjacent to and/or adjacent to the target tissue in the position of use.

If the electrode has at least one dislocation sensor, which is set up to detect a dislocation of the electrode, in particular of the at least one anchoring means, it is possible to detect an unintentional detachment of the electrode from the target tissue. This can increase safety in monitoring and/or treatment using the electromedical electrode.

In one embodiment, the at least one dislocation sensor is for detecting a dislocation of the electrode, in particular of the at least one anchoring means, based on deformation and/or loading and/or damage set up the at least one anchoring means.

In one embodiment, the at least one dislocation sensor of the electrode can have at least one electrical conductor which is influenced, in particular damaged and/or severed, when the electrode, in particular the at least one anchoring means, is dislocated. If the electrical conductor, through which current can flow when using the electromedical electrode, is severed when the electrode, in particular the at least one anchoring means, is dislocated, this can be detected by an interruption in a circuit that was previously closed with the at least one electrical conductor. If the electrical conductor is severed, this indicates a dislocation of the electrode, in particular of the at least one anchoring means.

In this context it should be mentioned that the at least one electrical conductor can have a predetermined breaking point. The predetermined breaking point can encourage the at least one electrical conductor to be severed when the electrode, in particular the at least one anchoring means, is dislocated. The at least one electrical conductor can be arranged on the anchoring means. In this way it is ensured that in the event of impermissible deformation and/or loading and/or damage to the anchoring means, the electrical conductor is actually severed and the dislocation of the electrode, in particular of the at least one anchoring means, can also be detected.

As already mentioned above, it can be provided that the electrode has a base carrier made of printed circuit board material, in particular printed circuit board foil. In the case of this electrode, the at least one anchoring means and the base support can be produced in one method step, for example stamped and/or cut from a printed circuit board material blank and/or produced using microlithographic methods. A separate attachment of anchoring means on the base support is not necessary here. This can significantly simplify the production of the electromedical electrode and/or at least facilitate the implementation of further properties and/or functions.

One embodiment of the electrode provides that a base support, for example the aforementioned one, of the electrode connects a proximal end of the electrode to the distal end of the electrode, on which the at least one anchoring means is arranged, in particular formed.

The at least one anchoring means can be connected to the base support and/or formed on the base support. In particular when both the at least one anchoring means and the base support are made from the same circuit board material, in particular from circuit board foil, the base support and the at least one anchoring means can be produced in one production process. Provision can be made for the at least one anchoring means and the base carrier of the electromedical electrode to be produced from a printed circuit board material blank, in particular from a printed circuit board foil blank, in particular cut or punched and/or using methods of printed circuit board production, in particular using lithographic methods.

The electrode can have at least two anchoring means, of which at least one anchoring means is arranged on both sides of a longitudinal central axis of a distal end section of the electrode, in particular of the base support. In this way, the electromedical electrode can be anchored uniformly and thus particularly reliably via its distal end section in the target tissue of a person to be treated.

The base support can have a distal end section on which at least one electromedical contact pole is formed. An electromedical stimulation pulse can be delivered to the target tissue of a person to be treated via the at least one electromedical contact pole. However, it is also possible to record electromedical body signals via the at least one electromedical contact pole of the electrode and to transmit them to an evaluation unit connected to the electrode, for example in order to write an ECG of the person to be treated.

The electrode, in particular the base support, can have at least one conductor track which is connected to at least one electromedical contact pole of the electrode. Via this at least one conductor track it is possible on the one hand to transmit electromedical stimulation pulses to the contact pole and on the other hand to transmit electromedical body signals and/or sensor signals from the at least one contact pole of the electrode and/or from at least one sensor of the electrode to an evaluation unit connected to the electrode .

At least one electromedical contact pole of the electrode can be arranged and/or formed on the at least one anchoring means. This ensures that the at least one electromedical contact pole in is in good contact with the target tissue to be monitored and/or treated when the electromedical electrode is anchored in the target tissue.

In one embodiment of the electrode it is provided that it has a sleeve, in particular a sleeve, in which a base support, for example the previously mentioned base support of the electrode, is arranged when the electrode is in use. The base support of the electrode can be protected from external influences by the cover.

In one embodiment of the electrode, the latter has a connecting means, in particular on its sleeve, with which the electrode can be connected to an electromedical device. The connecting means can be a thread and/or a locking mechanism, for example.

At its proximal end, the electrode can have a connector plug made of printed circuit board material, in particular printed circuit board foil. The connector plug is preferably a proximal end section of the base support of the electrode, on which at least one connector contact is formed. In this way, the connecting plug of the electromedical electrode can be produced together with the base carrier of the electrode from a printed circuit board material blank, in particular from a printed circuit board foil blank, in one work step.

In one embodiment of the electrode, it is provided that it has an electromedical pulse generator and/or an electromedical evaluation unit. The pulse generator and/or the evaluation unit can be arranged and/or formed on a proximal end section of the base support of the electrode. In a particularly preferred embodiment of the electrode, provision is made for the electromedical pulse generator and/or the evaluation unit to be integrated into the base carrier of the electromedical electrode. In this case, the electromedical pulse generator and/or the evaluation unit can be firmly connected to the base support, in particular to its proximal end section, so that they are no longer present as separate functional units from the electromedical electrode. In this way, a separate connection of the electrode to an electromedical pulse generator can be dispensed with.

The electrode can be designed as a transcutaneous and/or implantable electromedical electrode, in particular as a stimulation and/or sensing electrode. The electrode can then be used, for example, as an electromedical electrode of an external cardiac pacemaker.

The invention is described below using exemplary embodiments, but is not limited to the exemplary embodiments shown. Further exemplary embodiments are obtained by combining the features of individual or multiple claims with one another and/or by combining individual or multiple features of the exemplary embodiments shown.

• 1 eine Darstellung einer elektromedizinischen Elektrode, die an ihrem distalen Ende ein zick-zack-förmiges Verankerungsmittel aus Leiterplattenmaterial aufweist, wobei an dem Verankerungsmittel zwei elektromedizinische Kontaktpole und benachbart zu dem Verankerungsmittel ein elektronischer Bauteilträger mit einem Verarbeitungsmodul, einem Beschleunigungssensor und einem Kommunikationsmodul angeordnet ist,
• 2 eine elektromedizinische Elektrode mit zwei Verankerungsmitteln aus Leiterplattenmaterial, die als Widerhaken ausgebildet sind, wobei auch hier die Verankerungsmittel jeweils einen elektromedizinischen Kontaktpol aufweisen und benachbart zu den Verankerungsmitteln ein elektronischer Bauteilträger mit einem Verarbeitungsmodul, einem Beschleunigungssensor und einem Kommunikationsmodul angeordnet ist,
• 3 eine dritte Ausführungsform einer elektromedizinischen Elektrode mit zwei Verankerungsmitteln in Form von Laschen, wobei jede Lasche drei Stege aufweist, von denen mittlere Stege jeweils mit einem elektromedizinischen Kontaktpol versehen sind, und wobei auch diese Elektrode benachbart zu den Verankerungsmitteln einen elektronischen Bauteilträger mit einem Verarbeitungsmodul, einem Beschleunigungssensoren und einem Kommunikationsmodul aufweist,
• 4 eine abgewandelte Ausführungsform der in 3 gezeigten elektromedizinischen Elektrode mit insgesamt vier laschenförmigen Verankerungsmitteln,
• 5 eine perspektivische Ansicht des proximalen Endes einer der in den 1 bis 4 gezeigten elektromedizinischen Elektrode, wobei am proximalen Ende der Elektrode ein Anschlussstecker mit insgesamt fünf Anschlusskontakten zu erkennen ist, der im sogenannten Rigid-Flex-Verfahren mit einem Grundträger der Elektrode verbunden ist,
• 6 eine Darstellung einer alternativen Ausführungsform eines Anschlusssteckers, der als Teil des Grundkörpers der elektromedizinischen Elektrode ausgebildet ist, wobei ein Einsteckbereich des Kontaktsteckers mit daran angeordneten, beidseitig kontaktierbaren Anschlusskontakten zu erkennen ist, wobei der Steckerbereich durch Umfaltung einer einseitig prozessierten, flexiblen Leiterplatte gebildet ist, sowie
• 7 eine der in den vorherigen Figuren gezeigte Elektrode mit einem Hüllschlauch, in dem ein Grundträger der gezeigten Elektrode aus Leiterplattenfolie angeordnet ist.

Show it

• 1 a representation of an electromedical electrode which has a zigzag-shaped anchoring means made of printed circuit board material at its distal end, with two electromedical contact poles being arranged on the anchoring means and an electronic component carrier with a processing module, an acceleration sensor and a communication module being arranged adjacent to the anchoring means,
• 2 an electromedical electrode with two anchoring means made of printed circuit board material, which are designed as barbs, the anchoring means each having an electromedical contact pole and an electronic component carrier with a processing module, an acceleration sensor and a communication module being arranged adjacent to the anchoring means,
• 3 a third embodiment of an electromedical electrode with two anchoring means in the form of tabs, each tab having three webs, of which central webs are each provided with an electromedical contact pole, and wherein this electrode, adjacent to the anchoring means, also has an electronic component carrier with a processing module, a acceleration sensors and a communication module,
• 4 a modified embodiment of the 3 shown electromedical electrode with a total of four tab-shaped anchoring means,
• 5 a perspective view of the proximal end of one of the in 1 until 4 shown electromedical electrode, with a connector plug with a total of five connection contacts being visible at the proximal end of the electrode, which is connected to a base carrier of the electrode using the so-called rigid-flex method,
• 6 an illustration of an alternative embodiment of a connector plug, which is formed as part of the body of the electromedical electrode, wherein a Einsteckbe rich of the contact plug with arranged on it, contactable connecting contacts can be seen, the plug area is formed by folding a one-sided processed, flexible printed circuit board, as well as
• 7 one of the electrodes shown in the previous figures with an enveloping tube in which a base support of the electrode shown made of printed circuit board foil is arranged.

All figures show at least parts of an electromedical electrode denoted by 1 as a whole. The electromedical electrode 1 is designed as a so-called transcutaneous electrode and can be used, for example, to transmit electromedical stimulation pulses from an electromedical pulse generator, such as an external cardiac pacemaker, to a target tissue of a person to be treated.

Each electromedical electrode 1 has at least one anchoring means 2 at its distal end 3, with which the electromedical electrode 1 can be reliably anchored in the target tissue of the person to be treated. The anchoring means 2 shown in the figures thus serve as protection against being pulled out.

All anchoring means 2 shown are hook-shaped. At the in 1 In the electromedical electrode shown, the anchoring means 2 is designed in a zigzag shape and thus forms a pull-out safeguard that allows the electrode to be reliably anchored in the target tissue.

In the 2 The electromedical electrode 1 shown has two anchoring means 2 in the form of barbs 14 .

At the in the 3 and 4 Electromedical electrodes shown are two ( 3 ) or four ( 4 ) Anchoring means 2 provided in the form of tabs 15. Each of the tabs 15 comprises a total of three webs 16 which are arranged in such a way that they form a protection against being pulled out. Outer webs 16 of the tabs 15 are angled and form a cross-sectional extension of the base support 5 in the 3 and 4 shown electromedical electrodes 1. This cross-sectional enlargement increases the pull-out resistance of the electrode 1 from the target tissue.

Spaces 27 between the webs 16 of the anchoring means 2 designed as tabs 15 are closed by membranes 26 . These membranes 26 prevent tissue from growing through the gaps 27 between the anchoring means 2 structures. Each of the tabs 15 thus has at least one membrane 26 . The use of such membranes 26 is also conceivable for the anchoring means 2 of the electrodes 1 shown in the other figures.

The membranes 26 consist of a biocompatible material, for example polyurethane and/or silicone, and are more flexible than the structures, for example the webs 16, of the anchoring means 2 which surround the membranes 26.

In the case of the electrodes 1 shown in the figures, the anchoring means 2 consist of printed circuit board material, namely printed circuit board foil. The anchoring means 2 are each provided with an application needle 4 at their free ends. The application needle 4 can be separated from the anchoring means 2 after application of the electrode 1 in the target tissue.

All of the electrodes 1 shown have at least one electronic functional element 17 . The electronic functional elements 17 are arranged in a component carrier designated as a whole by 24 . The electrodes 1 have, as electronic functional elements 17 , a processing module 18 for preprocessing signals and a communication module 19 for wireless or wired communication with an electromedical device connected to the electrode 1 .

At least one sensor 20 is also provided in each case as an electronic functional element 17 in the component carriers 24 . All of the electrodes 1 shown have at least one acceleration sensor and/or at least one physiological sensor and/or at least one biosensor as sensors 20 . For example, physiological sensors and/or biosensors can be used to detect inflammation of the target tissue.

The component carriers 24 are arranged with the sensors 20 adjacent to the anchoring means 2 at the distal end 3 or at the distal end section 7 of the respective electromedical electrode 1 .

The electrodes 1 also have at least one dislocation sensor 21 for detecting a dislocation of the electrode 1, namely the anchoring means 2, based on a deformation and/or loading and/or damage to the at least one anchoring means 2.

The dislocation sensors 21 each comprise at least one electrical conductor 22 which is severed upon dislocation of the electrode 1, namely upon dislocation of the anchoring means 2. In order to promote a severing of the electrical conductor 22 when the electrode 1 is dislocated from the target tissue, the electrical conductor 22 can have a predetermined breaking point 23 . Furthermore, the electrical conductor 22 is arranged on the respective anchoring means 2 .

Based on the embodiment of an electrode 1, as shown in 2 is shown, the function of the dislocation sensor 21 can be explained particularly well. The two barb-shaped anchoring means 2 of the in 2 The electromedical electrode 1 shown is covered with an electrical conductor 22 . When the electrode 1 is dislocated from the target tissue, legs 25 of the barbs 14 are spread open, as a result of which the electrical conductors 22, which are arranged on the legs 25, are loaded and severed, for example, at their predetermined breaking point 23. By severing the electrical conductors 22, a circuit previously closed by the electrical conductors 22 is interrupted. The interruption of the electrical circuit can be detected, with an interruption in the electrical circuit being able to indicate a dislocation of the electromedical electrode 1 from the target tissue.

The electrodes 1 include a base support 5, which is also made of printed circuit board material, namely printed circuit board foil. The base support 5 connects a proximal end 6 of the electrode 1 to the distal end 3 of the respective electrode 1. The printed circuit board material of the base support 5 and the anchoring means 2 comprises a layered structure, with an outer layer of the printed circuit board material made of biocompatible material, for example polyurethane and/or silicone consists. The aforementioned membranes 26 may be formed from the outer layer.

The figures show that the anchoring means 2 are connected to the base support 5 of the electrode or are formed on the base support 5 . The base support 5 and the anchoring means 2 consist of the same printed circuit board material and even the same blank printed circuit board material—here the same printed circuit board foil blank. The base support 5 and the anchoring means 2 thus form a materially homogeneous monolithic unit.

The figures show that several of the anchoring means 2 are arranged on both sides of a longitudinal center axis of a distal end section 7 of the base support 5 of the electrode 1 . The anchoring means 2 are thus distributed evenly on both sides of the longitudinal center axis of the distal end section 7 of the electrode 1 . This favors reliable anchoring of the electromedical electrode 1 in the target tissue of a person to be treated with the electromedical electrode 1 .

The base support 5 of each electrode has at least one electromedical contact pole 8 on the distal end section 7 . Electromedical stimulation pulses can be delivered to the target tissue of the person to be treated via the electromedical contact poles 8 . Furthermore, the electromedical contact poles 8 can also be used to record and transmit electromedical body signals from the target tissue of the person to be treated.

At least one electromedical contact pole 8 is arranged on an anchoring means 2 in all of the electrodes 1 shown in the figures. This favors a reliable recording of electromedical body signals from the target tissue as well as a reliable delivery of electromedical stimulation pulses from the electromedical contact poles 8 to the target tissue in which the electromedical electrode 1 is anchored in the position of use.

The electromedical electrodes 1 shown in the figures can be designed as transcutaneous and/or implantable electromedical electrodes and in particular as stimulation and/or sensing electrodes.

With the help of sensing electrodes, electromedical body signals and/or physiological variables and/or measured variables can be recorded from the target tissue by sensors 20 and 21 of the electrode 1 .

The electrodes 1 have a number of conductor tracks 9 which are connected to the electromedical contact poles 8 of the electrode 1 . The conductor tracks 9 can be embedded at least in sections in the circuit board material of the base support 5 and/or the anchoring means 2 and/or can be arranged at least in sections on a layer of the circuit board material. Electromedical stimulation pulses can be transmitted to the contact poles 8 and from there to the target tissue via the conductor tracks 9 . If electromedical body signals are picked up by the contact poles 8 from the target tissue of the person to be treated, they can be transmitted via the conductor tracks 9 of the electrode 1 to an evaluation unit connected to the electrode 1 .

7 shows that the electrode 1 has a sleeve 28, namely a sleeve, in which the base support 5 of the electrode 1 is arranged.

At their proximal end 6, the electrodes 1 have a connection stretcher 10, which is also made of printed circuit board material, namely printed circuit board foil. The connector plug 10 protrudes from the proximal end of the sleeve 28 and can be plugged into a connector socket of an electromedical pulse generator. It can be clearly seen that the connection plug 10 with its connection contacts 11 forms a proximal end section 12 of the base support 5 of the electrode 1 . In this way, the base support 5 and the connector plug 10 also form a materially homogeneous monolithic unit. Consequently, there is no joint between the connector plug 10 and the base support 5 .

A connection means 13 in the form of a thread is provided at the proximal end of the sheath 28 . With this connecting means 13, the electrode 1 can be connected, for example, to a corresponding mating connecting means—here with a matching mating thread—of an electromedical device. In this way, the electrode 1 can be reliably fixed to the device. The device can be, for example, an electromedical pulse generator, such as an external cardiac pacemaker, and/or an electromedical evaluation unit with which electromedical body signals are evaluated.

In an embodiment of the electrode that is not shown in the figures, it has an integrated electromedical pulse generator. This is arranged or formed on the previously mentioned proximal end section 12 of the base support 5 of the electrode 1 .

The electromedical electrodes 1 shown in the figures are designed as transcutaneous stimulation electrodes and can be used, for example, on an external heart pacemaker to support and/or monitor the heart function of a person after a heart operation.

The invention addresses improvements in the technical field of electromedical electrodes. For this purpose, an electromedical electrode 1 is proposed, which has a base carrier 5 made of printed circuit board material at its distal end 3 with at least one anchoring means 2 made of printed circuit board material.

Reference List

1

electromedical electrode

2

anchoring means

3

distal end

4

application needle

5

base carrier

6

proximal end of 1

7

distal end section

8th

electromedical contact pole

9

trace

10

connector plug

11

connection contact

12

proximal end section

13

lanyard

14

barb

15

tab

16

web

17

electronic functional element

18

processing module

19

communication module

20

sensor

21

displacement sensor

22

electrical conductor

23

predetermined breaking point

24

component carrier

25

thighs of 14

26

membrane

27

space

28

Covering

Claims (22)

Electromedical electrode (1) with at least one anchoring means (2) at its distal end (3), characterized in that the at least one anchoring means (2) consists of printed circuit board material, in particular printed circuit board foil. Electromedical electrode (1), in particular according to claim 1 , having at least one anchoring means (2) at its distal end (3), characterized in that the electromedical electrode (1) has a base support (5) which consists of printed circuit board material, in particular printed circuit board foil. electrode (1) after claim 1 or 2 , wherein the circuit board material of the at least one anchoring means (2) and / or the base support (5) comprises a layered structure and / or an outer layer made of biocompatible material, in particular made of polyurethane and/or silicone. Electrode (1) according to one of the preceding claims, wherein at least one anchoring means (2) is designed as a pull-out safeguard and/or wherein the at least one anchoring means (2) has an application needle (4) at its free end. Electrode (1) according to one of the preceding claims, wherein at least one anchoring means (2) is hook-shaped and/or zigzag-shaped and/or designed as a barb (14) and/or as a tab (15) and/or at least two preferably comprises at least three webs (16) which are arranged in such a way that they form a pull-out protection. Electrode (1) according to one of the preceding claims, wherein at least one anchoring means (2) is designed as a tab (15) and/or comprises at least two, preferably at least three, webs (16) which are arranged in such a way that they form a pull-out protection . Electrode (1) according to one of the preceding claims, wherein at least one anchoring means (2) has at least one membrane (26) with which an intermediate space (27) between structures, in particular between webs (16), of the anchoring means (2) is closed, in particular the membrane (26) being more flexible than the structures of the anchoring means (2) surrounding it. Electrode (1) according to one of the preceding claims, wherein the electrode (1) has at least one electronic functional element (17), in particular a processing module (18), for example for preprocessing signals and/or a communication module (19). Electrode (1) according to one of the preceding claims, wherein the electrode (1) has at least one sensor (20,21), for example an acceleration sensor and/or a physiological sensor and/or a biosensor, for example for detecting inflammation, preferably wherein at least a sensor (20) is arranged on the at least one anchoring means (2) and/or adjacent to the at least one anchoring means (2). Electrode (1) according to one of the preceding claims, wherein the electrode (1) has at least one dislocation sensor (21) which is set up to detect a dislocation of the electrode (1), in particular of the at least one anchoring means (2). Electrode (1) according to the preceding claim, wherein the at least one dislocation sensor (21) for detecting a dislocation of the electrode (1), in particular the at least one anchoring means (2), preferably based on a deformation and/or loading and/or damage to the at least an anchoring means (2) is set up. Electrode (1) according to one of the preceding claims, wherein the at least one dislocation sensor (21) has at least one electrical conductor (22) which is severed when the electrode (1), in particular the at least one anchoring means (2), is dislocated, preferably wherein the at least one electrical conductor (22) has a predetermined breaking point (23) and/or is arranged on the anchoring means (2). Electrode (1) according to one of the preceding claims, wherein one or the base support (5) of the electrode (1) connects a proximal end (6) of the electrode (1) to the distal end (3) of the electrode (1). Electrode (1) according to one of the preceding claims, wherein the at least one anchoring means (2) is connected to the base support (5) and/or formed on the base support (5) and/or wherein the at least one anchoring means (3) and the base support (5) are produced from a circuit board material blank, in particular from a circuit board foil blank, in particular cut and/or stamped and/or lithographically and/or produced using circuit board production methods. Electrode (1) according to one of the preceding claims, wherein the electrode (1) has at least two anchoring means, of which at least one anchoring means (2) is arranged on both sides of a longitudinal center axis of a distal end section (7) of the electrode (1). Electrode (1) according to one of the preceding claims, wherein the base support (5) has a distal end section (7) on which at least one electromedical contact pole (8) is formed and/or wherein at least one electromedical contact pole (8) is formed on the at least one Anchoring means (2) is arranged and / or formed. Electrode (1) according to one of the preceding claims, wherein the electrode (1), in particular the base support (5), has at least one conductor track (9) which is connected to at least one electromedical contact pole (8) of the electrode (1). Electrode (1) according to one of the preceding claims, wherein the electrode (1) has a sleeve (28), in particular a sleeve, in which one or the base support (5) of the electrode (1) is arranged. Electrode (1) according to one of the preceding claims, wherein the electrode (1), in particular one or the shell (28) of the electrode (1), a connecting means (13), in particular a thread and / or a locking mechanism, with which the Electrode (1) can be connected to an electromedical device. Electrode (1) according to one of the preceding claims, wherein the electrode (1) has a connector plug (10) at its proximal end (6), which consists of printed circuit board material, in particular printed circuit board foil, preferably wherein the connector plug (10) has a proximal end section (12) of the base support (5) of the electrode (1), on which at least one connection contact (11) is formed. Electrode (1) according to one of the preceding claims, wherein the electrode (1) has an electromedical pulse generator which is arranged and/or formed on a proximal end section (12) of the base support (5) of the electrode (1). Electrode (1) according to one of the preceding claims, wherein the electrode (1) is designed as a transcutaneous and/or implantable electromedical electrode, in particular as a stimulation and/or sensing electrode.

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