DE102016120138B4 - Applicator for introducing high-frequency currents into the human body - Google Patents

Abstract

Applicator for introducing high-frequency currents into the human body, with a base element (1) and at least one electrode element (2a), wherein the base element and the electrode element each have at least one electrical contact and the base element and electrode element are designed to interact in such a way that in a usage configuration with the electrode element arranged on the base element, the electrical contact of the electrode element (2a'.1, 2a'.2, 2a'.3) is electrically conductively connected to the electrical contact of the base element (1a, 1b, 1c), the electrode element being at least an electrode (2a.1) for application to human tissue, which is electrically conductively connected to the electrical contact (2a'.1) of the electrode element, characterized in that in the usage configuration the electrode element (2a) can be detached by means of a magnetic holder of the applicator is arranged on the base element (1), the magnet holding tion has at least one permanent magnet (12) and at least one ferromagnetic counter-element (22), and the base element (1) has the permanent magnet (12) and the electrode element (2a) has the ferromagnetic counter-element (22), the permanent magnet (12) and/or the ferromagnetic counter-element (22) has a recess (25) which is designed in such a way that the base element (1) and electrode element (2a) make contact through the recess (25) in the usage configuration.

Description

The invention relates to an applicator for introducing high-frequency currents into the human body according to the preamble of claim 1. The invention also relates to a device for generating high-frequency currents according to the preamble of patent claim 14.

Devices are known which, by means of, for example, monopolar, bipolar or multipolar electrodes, make it possible to introduce high-frequency currents, which are also referred to as “radio-frequency currents” or RF currents, into the human body.

Such devices find application in heat therapy or hyperthermia of human tissue in particular. The basic principle here is the heating of the tissue and thus the generation of structural changes in the tissue. Typical areas of application are, for example, the thermal treatment of unstable joint capsules by means of thermal capsulorrhaphy ("thermal collagen shrinkage"), thermokeratoplasty and skin tightening ("skin tightening"). All these applications have in common that collagen network structures should be changed by means of heat.

The basic principle of heating using high-frequency currents is the introduction of RF currents into the tissue using electrodes. Typical devices for this have a high-frequency (HF) energy source for generating the high-frequency currents, and at least one pair of electrodes. The electrodes are connected to the high-frequency energy source and each have a contact surface, by means of which they are applied to the tissue to be acted upon. The tissue is exposed to the currents generated by the high-frequency energy source via the contact surfaces, so that the tissue is heated due to the current flow due to Joule heat.

A device with a multipolar electrode is in EP 2 022 429 A2 described.

Typical devices for introducing high-frequency currents into the human body have an HF energy source which is electrically conductively connected to an applicator. The applicator is typically designed as a handpiece and has one or more electrodes which can be placed on the human body by means of the handpiece.

Applicators for introducing high-frequency currents into the human body are known, which have exchangeable electrode elements. In this case, an electrode element is attached to a base element by means of a clip fastener.

In EP 2 862 533 A1 describes an electrosurgical instrument in which a connecting piece in the form of an adapter attachment comprising an electrode can be connected to a handle in an exchangeable manner. The adapter attachment can be clipped onto the handle by inserting locking elements provided on the handle into corresponding locking recesses of the adapter attachment. Alternatively, it can also be provided that magnetic or similar fastening means are provided on the adapter attachment and on the handle for connecting the two parts.

In US 2013/0289559 A1 discloses an electrosurgical instrument having a handle and a needle-shaped electrode element releasably attached to the handle. In this case, however, the needle-shaped electrode element is not held with a magnetic holder, but with a mechanical holder through the recess on the handle.

The object of the present invention is to provide an applicator and an associated device for generating high-frequency currents, which are characterized by improved handling in practical use compared to the prior art and a cost-effective improvement in the hygiene properties.

This object is achieved by an applicator according to claim 1. Advantageous configurations of the applicator according to the invention can be found in subclaims 2 to 11. The wording of all claims is hereby included in the description by reference.

According to the invention, an applicator for introducing high-frequency currents into the human body is provided. Such an applicator system can be electrically conductively connected to an energy source for generating the high-frequency currents.

The applicator according to the invention for introducing high-frequency currents into the human body has a base element and at least one electrode element, with the base element and the electrode element each having at least one electrical contact. The base element and electrode element are designed to work together in such a way that in a configuration of use when the electrode element is arranged on the base element, the electrical contact of the electrode element is electrically conductive with the electrical contact of the base element is connected.

When using the applicator in the use configuration, the electrode element is detachably arranged on the base element by means of a magnetic holder of the applicator, so that there is an electrical connection between an electrical contact of the base element and the electrical contact of the electrode element. The electrode element has at least one electrode for application to human tissue, which is electrically conductively connected to the electrical contact of the electrode element. In particular, this electrode can be designed as one or more point-like contact surfaces, in particular metallic contact surfaces.

In the use configuration, the electrode element is thus arranged on the base element by means of the magnet holder of the applicator, so that an electrical contact of the base element is conductively connected to the electrical contact of the electrode element. The electrode element can thus be arranged on the human body by means of the base element, which is preferably designed as a hand element, so that the electrode of the electrode element is in contact with the human body. When a high-frequency current is fed into the base element, this current is introduced into the human body by means of the electrode via the electrical connection described above. Advantageously, the one electrode element can also be replaced by further electrode elements, which can each be connected or are connected to the base element in a detachable manner.

When only one base element is provided, the applicator thus makes it possible to use any electrode element from a group of several electrode elements.

Investigations by the applicant have shown that intensive cleaning of those elements which come into contact with the human body is necessary or sometimes mandatory in order to meet hygienic standards. The investigations showed that making all elements that come into contact with the human body as single-use products is expensive. According to the invention, a division into a base element and an electrode element is proposed, as described above, since the electrode element can be produced at comparatively low cost. In addition, the magnetic holder of the applicator enables the quick replacement of the electrode element in practical use. The applicator according to the invention thus makes it possible, on the one hand, to meet prescribed hygiene standards in a cost-saving manner, for example by using a new electrode element for each treatment, and on the other hand, the magnetic holder optimizes the applicator's ease of handling.

In particular, a magnet holder can be designed with fewer protruding elements compared to a clip holder and thus has no surfaces, or at least less difficult to access surfaces, on which deposits can occur.

Typical electrode elements are flat—in particular, disk-shaped or plate-shaped—and have a contact surface for contact with human tissue. The applicator is therefore advantageously designed in such a way that, in the usage configuration, the electrode element is held on the base element at least perpendicularly to the contact surface exclusively by the magnetic holder. Advantageously, the base element has at least one stop element, which is designed and arranged in such a way that lateral displacement of the electrode element relative to the base element and parallel to the contact surface is prevented by the stop element. In particular, it is advantageous that the stop element encloses the electrode element in the usage configuration, in particular encloses it in a ring-like manner. In particular, the stop element is preferably designed as a depression for receiving the electrode element.

In the applicator according to the invention, the magnet holder has a permanent magnet and a ferromagnetic counter-element, with the permanent magnet being arranged in or on the base element and the ferromagnetic counter-element in or on the electrode element. Alternatively, the magnet holder can also have more than one permanent magnet and more than one ferromagnetic element. This has the advantage that when the electrode element is replaced, the expensive part of the magnet holder (the permanent magnet) remains in the base element and only the less expensive part (the ferromagnetic counter-element) is replaced with the electrode element.

In a preferred embodiment of the applicator, the base element has a depression that serves to accommodate the electrode element. This ensures that the electrode element sits optimally in the base element and, in particular, prevents it from slipping sideways during use.

In order to improve the handling of the applicator in practical use, the detachment of the electrode element is facilitated in that the base element has a recess at which a partial area of the surface of the electrode element facing the base element is accessible in the usage configuration. As a result, the electrode element can be detached and replaced manually, in particular without tools. In this embodiment, the electrode element can thus be inserted into the base element with simple handling and can thus be detachably arranged on the base element. After the treatment, the electrode element is detached from the base element, preferably in order to dispose of the electrode element. As a result, the user can replace the electrode element without using a tool.

In a further preferred embodiment, both the permanent magnet and the ferromagnetic plate are designed as approximately disc-shaped molded parts. In a further development of the present invention, the permanent magnet itself can be a hard magnetic material made from iron, cobalt, nickel, rare earth metal alloys or ferrites.

It is within the scope of the invention to form the electrode elements in a manner known per se: in particular, the formation as a monopolar, bipolar or multipolar electrode, such as in EP 2 022 429 A2 described, in particular a tripolar electrode, possible.

It is within the scope of the invention for the base element to have a plurality of electrical contacts which can each be connected to one of a plurality of electrical contacts of the electrode element. The electrical contacts of the electrode element are respectively electrically conductively connected to an electrode of the electrode element. It is therefore possible that in an applicator system which is designed, among other things, for use with tripolar electrode elements and thus has at least three electrical contacts, only some of these electrical contacts are used in a selected usage configuration if the currently selected electrode element has fewer electrodes and thus not all contacts of the base element are each electrically conductively connected to an electrode.

The applicator according to the invention has at least one electrode element and one base element. The invention will therefore largely be described based on these elements. It is also within the scope of the invention to provide more than one electrode element, in particular to enable a larger selection of different electrode configurations.

In an advantageous embodiment, the shape of the base element has a selective shape area and the electrode element has a selective shape area complementary thereto for problem-free establishment of the electrical contacting of the electrode element with the base element of the applicator and thus for exact fitting of the electrode element into the recess of the base element. These are designed to interact in such a way that the electrode element can be arranged on the base element in only one orientation.

Furthermore, in an advantageous embodiment, the named shaped areas are designed and arranged in such a way that, in the usage configuration, the selective shaped area of the base element and the complementary selective shaped area of the electrode element are arranged facing one another, preferably abut one another, in particular a form-fitting abutment in at least one spatial direction. In this way, the arrangement of the electrode element on the base element is facilitated and, in particular, shifting or slipping of the electrode element through the selective shaped areas is avoided.

In an advantageous embodiment, a simple and cost-effective production of the electrode element and base element is promoted in that at least one selective mold area is designed as an indentation or bulge. Shaped areas of this type designed as an indentation or bulge can be produced inexpensively on the one hand with the base element typically made of plastic. Likewise, indentations and/or bulges in the electrode elements, which are typically in the form of circuit boards, can easily be produced by milling or cutting.

According to the invention, the permanent magnet and/or the ferromagnetic element have a cutout, preferably a rectangular cutout, so that electrical contact is established between the base element and the electrode element in the usage configuration.

Furthermore, in an advantageous embodiment, the electrode element is formed in two layers. In this case, the first layer is assigned to the base element in the usage configuration and has the ferromagnetic material. In particular, said layer can be designed as a ferromagnetic metal plate. The second layer of the electrode element, which faces away from the base element in the usage configuration, has the electrical contact here and can advantageously be designed as a printed circuit board be. This results in a simple and inexpensive manufacture of the electrode element. In particular, it is advantageous to form the first and the second layer as a plate, in particular the first layer as a metallic plate and the second layer as a printed circuit board, in which the electrode is formed on one side and the electrical contact is formed on an opposite side.

Alternatively or additionally, it is advantageous that at least one selective shaped area is designed as a depression, preferably as a recess that completely penetrates the electrode element. In this advantageous embodiment, when the electrode element is arranged on the holding element, a pin-like element rests against a complementary depression or a complementary recess, so that the pin penetrates the recess, in particular penetrates it. Due to different configurations with regard to the geometric dimensions, the shape or the arrangement of such pins and the complementary associated indentations and/or recesses, an unambiguous association between the electrode element and the associated holding element is also possible in a simple manner.

As already described, the applicator according to the invention is particularly advantageous when using different electrode configurations, since the electrode elements can be quickly exchanged here (in particular for single use). The applicator therefore advantageously has at least one first and one second electrode, which can be optionally arranged on the applicator by means of the magnetic holder. The first electrode element therefore preferably differs from the second electrode element in at least one parameter from the group of number of electrodes, area of the electrodes, spacing of the electrodes, spatial arrangement of the electrodes.

In particular, it is advantageous to provide several electrode elements that have a different spacing in order to select an electrode element with a suitable electrode spacing depending on the thickness of a dermis layer of the tissue and/or depending on a reflection coefficient of the tissue at the boundary of the dermis layer facing away from the surface of the tissue. The selection of the electrode spacing depending on the above parameters is in DE 10 2015 108 469 described.

As previously described, it is often desirable to use multipolar electrodes, particularly bipolar electrodes. Preferably, therefore, at least one electrode element has at least two electrodes and at least two electrical contacts, and accordingly the base element has at least two electrical contacts, so that the human body can be subjected to high-frequency currents from a multipolar electrode, in particular a bipolar electrode, in a manner known per se. In the usage configuration, one electrical contact of the base element is electrically conductively connected to one electrical contact of the electrode element, so that high-frequency currents can be transmitted from the base element to the electrode element via the contacts.

The electrodes of the electrode elements can be designed in a manner known per se, in particular as point-like contact surfaces which do not penetrate into the human tissue and are referred to as non-invasive electrodes. It is also within the scope of the invention to provide electrode elements with electrodes which penetrate slightly into the human tissue. The introduction of current is improved by such minimally invasive electrodes. The minimally invasive electrodes can in particular be needle-shaped and/or pyramid-shaped.

In particular, it is advantageous that one electrode element has only non-invasive electrodes and the other electrode element has only minimally invasive electrodes, so that the user can select the type of electrode.

In order to introduce high-frequency currents into the human tissue, at least one electrical contact of the base element is connected to an electrode of the electrode element in the usage configuration in such a way that this electrical contact enables the high-frequency currents to be transmitted into the human tissue.

In an advantageous embodiment, the base element has at least one detection means and the electrode element has at least one identification means. Detection means and identification means are designed and arranged to work together in such a way that, in the usage configuration, the electrode element can be identified by detecting the identification means by the detection means.

This results in the advantage that the electrode element arranged on the applicator in the usage configuration can be identified by a detection unit using the detection means using the identification means of the electrode element.

In this case, the detection unit can be realized by a computer unit which accesses a database in which the corresponding configurations of the identification means are stored for one or preferably several electrode elements. When using the applicator with several different electrode elements, it is therefore advantageous that a specific configuration of the identification means is assigned to each type of electrode element.

Preferably, the detection means and the identification means each have a plurality of electrical contacts which are arranged in such a way that, in the usage configuration, one contact of the detection means is electrically conductively connected to one contact of the identification means. This results in a technically simple embodiment. In particular, different means of identification can differ in that the electrical contacts of the means of identification are connected differently. In a preferably simple and error-free embodiment, different identification means have a binary coding in which the identification means is provided with an electrically conductive connection corresponding to a “1” of the binary code between two electrical contacts or corresponding to a “0” of the binary code between two electrical contacts no electrically conductive connection is provided. In this way, at least two 2 ^n-1 different electrode elements can be identified by n electrical contacts.

When using the applicator with an external high-frequency energy source for generating high-frequency currents, the detection unit is preferably arranged in or on the high-frequency energy source and connected to the electrical contacts of the detection means by means of electrical lines. The invention also relates to a device for generating high-frequency currents for the cosmetic and/or therapeutic treatment of tissue using electrodes. The device comprises a high-frequency energy source for generating high-frequency currents and an applicator according to the invention, in particular a preferred embodiment thereof. In the usage configuration, the electrode of the electrode element is electrically conductively connected to an output of the high-frequency energy source, so that it is possible to apply the high-frequency currents generated by the high-frequency energy source to the human body.

It is particularly advantageous here that the base element is designed as a hand-held element which is electrically conductively connected to the output of the high-frequency energy source by means of a cable, preferably detachably via a plug.

The high-frequency energy source can be designed in a manner known per se. In particular, it is advantageous that frequencies in the range from 0.1 MHz to 20 MHz, preferably between 0.3 MHz and 20 MHz, in particular in the range from 0.5 MHz to 10 MHz, can be selected for the currents generated by the high-frequency energy source.

• 1 ein erstes Ausführungsbeispiel eines erfindungsgemäßen Applikators mit einem Basiselement, einem Elektrodenelement sowie die Rückansicht des Elektrodenelementes zur besseren Veranschaulichung;
• 2 eine Detailansicht des Basiselementes und das Elektrodenelementes aus 1 in perspektivischer Darstellung und
• 3 drei Elektrodenelemente für ein zweites Ausführungsbeispiel eines Applikators

Further preferred features and embodiments are described below using exemplary embodiments and the figures. It shows:

• 1 a first embodiment of an applicator according to the invention with a base element, an electrode element and the rear view of the electrode element for better illustration;
• 2 a detailed view of the base element and the electrode element 1 in perspective and
• 3 three electrode elements for a second embodiment of an applicator

Schematic representations are shown in all figures. The same reference symbols denote the same elements or elements that have the same effect.

• Das Elektrodenelement 2a weist mehrere bipolare Elektroden auf, welche aus jeweils zwei Teilelektroden ausgebildet sind. Jede der zwei Teilelektroden ist aus einer Zeile von punktartigen Kontaktflächen ausgebildet (beispielsweise beinhaltet eine Teilelektrode die punktartigen Kontaktflächen 2a.1, 2a.2 und 2a.3), welche untereinander elektrisch leitend verbunden sind. Alle punktartigen Kontaktflächen einer Zeile sind jeweils miteinander elektrisch leitend verbunden. Weiterhin sind die Zeilen, welche jeweils eine Teilelektrode aufweisen, alternierend angeordnet. Alle Zeilen stehen zudem miteinander in elektrischem Kontakt. Des Weiteren ist jede punktartige Kontaktfläche auf der gegenüberliegenden Seite des Elektrodenelements 2a mit einem elektrischen Kontakt elektrisch leitend verbunden.

1 shows a first embodiment of an applicator for introducing high-frequency currents into the human body. The applicator has a base element 1 which is designed as a hand element. Furthermore, the applicator has an electrode element 2a. The electrode element 2a has at least one electrode for application to the human body and at least one electronic contact which is electrically conductively connected to the electrode:

• The electrode element 2a has a plurality of bipolar electrodes which are each formed from two sub-electrodes. Each of the two sub-electrodes is formed from a row of point-like contact areas (for example, one sub-electrode contains the point-like contact areas 2a.1, 2a.2 and 2a.3), which are electrically conductively connected to one another. All of the punctiform contact areas in a row are connected to one another in an electrically conductive manner. Furthermore, the rows, which each have a sub-electrode, are arranged alternately. All rows are also in electrical contact with one another. Furthermore, each point-like contact area on the opposite side of the electrode element 2a is electrically conductively connected to an electrical contact.

In 1 Partial image a) shows the electrode element 2a in perspective with a top view of a treatment side of the electrode element, which has the point-like contact surfaces 2a.1, 2a.2 and 2a.3. In the usage configuration, this treatment side is applied to the human tissue, so that RF currents can be introduced into the tissue by means of the point-like contact surfaces.

In 1 , partial image b), the electrode element 2a is shown in perspective with a top view of a contacting side of the electrode element opposite the treatment side, which has electrical contacts 2a'.1, 2a'.2 and 2a'.3.

The base element has a total of eight electrical contacts, in particular two rows, each with four contacts, which are each designed as spring-loaded pin contacts. Three contacts 1a, 1b and 1c are marked as examples.

In the use configuration, the electrode element 2a is arranged by means of the magnetic holder with the contacting side on the base element 1, the electrical contacts (2a'.1, 2a'.2, 2a'.3), which electrodes are electrically conductively connected, each with the electrical contacts (1a, 1b, 1c) are electrically conductively connected. Current can thus be supplied to the electrodes (2a.1, 2a.2, 2a.3) in the usage configuration via the contacts (1a, 1b, 1c). As a result, in the usage configuration, the contact 1a of the base element 1 is electrically conductively connected to a sub-electrode of the electrode element 2a. Correspondingly, the contact 1b is electrically conductively connected to the second sub-electrode of the electrode element 2a in the usage configuration. This electrical contact enables the emission of RF currents when the applicator is in contact with human tissue.

For arranging the electrode element 2a, the base element 1 has a contact surface 11, the contact surface 11 being arranged in a circular depression of the base element. The contact surface 11 is surrounded by a ring-like stop element 13, which is designed in such a way that a lateral displacement of the electrode element 2a relative to the base element 1 and parallel to the contact surface 11 in the usage configuration is prevented by the stop element 13. In addition, a permanent magnet 12 is arranged in the contact surface 11, with the permanent magnet 12 forming the magnetic holder of the applicator in the usage configuration with a ferromagnetic element 22 of the electrode element 2a. Both the permanent magnet 12 and the ferromagnetic element 22 are approximately disk-shaped.

• Das Basiselement 1 weist einen selektierenden Formbereich 14 auf, wobei im dargestellten Ausführungsbeispiel dieser Formbereich als Ausbuchtung ausgebildet ist. Das Elektrodenelement 2a weist eine hierzu komplementäre Formgebung 24 auf, wobei diese selektierende Formgebung 24 im dargestellten Ausführungsbeispiel als Einbuchtung ausgebildet ist. Beide Formbereiche sind derart ausgebildet und angeordnet, dass in Benutzungskonfiguration der selektierende Formbereich 14 des Basiselementes 1 und der komplementäre selektierende Formbereich 24 des Elektrodenelementes 2a einander zugewandt angeordnet sind, wobei diese derart aneinander anliegen, dass das Elektrodenelement 2a in nur einer Orientierung an dem Basiselement 1 anordenbar ist. Hierdurch wird in Benutzungskonfiguration eine korrekte Ausrichtung des Elektrodenelements 2a zu dem Basiselement 1 des Applikators gewährleistet.

The base element 1 has a shape complementary to the associated electrode element 2a:

• The base element 1 has a selective shape area 14, with this shape area being designed as a bulge in the exemplary embodiment shown. The electrode element 2a has a shape 24 complementary thereto, with this selective shape 24 being designed as an indentation in the exemplary embodiment shown. Both mold areas are designed and arranged in such a way that, in the configuration of use, the selective mold area 14 of the base element 1 and the complementary selective mold area 24 of the electrode element 2a are arranged facing one another, with these abutting one another in such a way that the electrode element 2a can be attached to the base element 1 in only one orientation can be arranged. This ensures correct alignment of the electrode element 2a with respect to the base element 1 of the applicator in the usage configuration.

This prevents the electrode element 2a from being displaced or twisted in the base element 1 when it is in place.

Furthermore, the electrode element 2a is formed in two layers. The first layer faces the base element 1 and contains the ferromagnetic element 22, the ferromagnetic element being in the form of a disc-shaped metal plate, as already described above. The second layer of the electrode element 2a, which faces away from the base element 1 in the usage configuration, is designed as a printed circuit board and has the electrical contacts (2a'.1, 2a'.2, 2a'.3) and the point-like contact surfaces (2a.1, 2a.2, 2a.3) on the user page.

To produce the electrical contact between the base element 1 and the electrode element 2a, the permanent magnet 12 and the ferromagnetic element 22 have a rectangular recess 25. In addition, the base element 1 has a contacting area 15 that is raised relative to the contact surface 11 , this contacting area 15 penetrating the cutout 25 of the ferromagnetic element 22 in the usage configuration. This forms the electrical contact between the base element 1 and the electrode element 2a.

For manual, in particular tool-free, lifting of the electrode element 2a from the base element 1, the base element 1 has a recess 16, which is designed in such a way that in the usage configuration a partial area of the surface of the electrode element 2a facing the base element 1 is accessible for manual detachment of the electrode element. This enables rapid replacement of the electrode element 2a in practical use and significantly improves handling compared to comparable applicators with an additional holding element.

A high-frequency energy source 3 is also provided for forming a device for generating high-frequency currents for the cosmetic and/or therapeutic treatment of tissue by means of electrodes. The high-frequency energy source 3 is electrically conductively connected to all contacts of the base element 1 by means of electrical lines.

The high-frequency energy source 3 is designed in a manner known per se; in the present case, currents with frequencies in the range from 0.1 MHz to 20 MHz can be specified by means of a control panel.

The base element also has a switch 17 . This switch is also electrically conductively connected to the high-frequency energy source 3 via a cable. The high-frequency energy source 3 is designed in such a way that currents are only applied to the contacts of the base element 1 and accordingly to the electrodes of the arranged electrode element 2a when the switch 17 is actuated.

The applicator 1 also has a detection means 18 . This detection means comprises a row of four electrical contacts (see reference number 18 in 1 ), which is arranged over the electrical contacts 1a, 1b and 1c. In the usage configuration, each of the four electrical contacts of the detection means 18 is electrically conductively connected to a respective electrical contact of an identification means 28 of the electrode element 2a. The electrical contacts of the identification means 28 are in part b) of 1 apparent.

The identification means 28 of the electrode element 2a is designed in such a way that a binary coding was carried out: With the present electrode element 2a only (from left to right according to the view in 1 ) the first and the second electrical contact are electrically conductively connected to one another. The other electrical contacts have no electrically conductive connection.

The electrical contacts of the detection means 18 are each electrically conductively connected to the high-frequency energy source 3 via an electrical line. The high-frequency energy source 3 also has a detection unit designed as a computer unit with a database in which a binary code is assigned to an electrode element type. The detection unit can be used to detect via the electrical lines which of the four electrical contacts of the detection means 18 are electrically conductively connected. The type of electrode element arranged on the applicator in the usage configuration is identified by a comparison with the database.

Treatment parameters, in particular the frequency and/or power of the high-frequency currents, are advantageously set as a function of the electrode element type. Alternatively or additionally, it is advantageous to show the user the type of electrode element currently arranged on the applicator by means of an optical display.

In 2 the first embodiment of the applicator is shown in a perspective view as a detailed view. The following elements are shown: the front part of the base element 1, the shaped area 14 facing the electrode element 2a, the contact surface 11 containing the permanent magnet 12, the bordering stop element 13 as well as the contacting element 15 and the detection means 18.

Also shows 2 the two-layer structure of the electrode element 2a: the ferromagnetic element 22, the rectangular recess 25, the electrodes (2a'.1, 2a'.2, 2a'.3) and the identification means 28. The recess 16 is also indicated in this perspective view .

In the configuration of use, the magnetic holder allows the electrodes to be replaced quickly and easily, thereby improving the applicator's manageability with regard to the hygiene regulations mentioned. In this context, the use of multipolar electrodes, in particular bipolar electrodes, is often desirable.

In 3 three different electrode elements 2b, 2c and 2d are shown as an example in a plan view of the treatment side of the electrode elements. All electrode elements are disc-shaped. Furthermore, all the electrode elements (2b, 2c, 2d) each have a selective shaped area 24 . This ensures the exact orientation of the electrode elements in the base element 1 in the usage configuration.

• Jede bipolare Elektrode weist zwei Teilelektroden auf. Eine erste Teilelektrode ist aus einer Zeile von punktartigen Kontaktflächen jeweils ausgebildet (beispielsweise bei den Elektrodenelementen 2b und 2c mit „1“ markiert), welche untereinander elektrisch leitend verbunden sind. Eine dazugehörige zweite Teilelektrode ist ebenfalls aus einer Zeile von punktartigen Kontaktflächen ausgebildet (beispielsweise bei den Elektrodenelementen 2b und 2c mit „2“ markiert), welche untereinander elektrisch leitend verbunden sind. Alle punktartigen Kontaktflächen einer Zeile sind jeweils miteinander elektrisch leitend verbunden. Weiterhin sind alle Zeilen der Nummer 1 sowie alle Zeilen der Nummer 2 elektrisch miteinander verbunden. Die Zeilen sind alternierend angeordnet. Zur besseren Übersichtlichkeit wurde im Fall des Elektrodenelementes 2d auf die Zeilennummerierung verzichtet. Es wird jedoch darauf hingewiesen, dass diese Zeilen ebenfalls alternierend Teilelektroden des Typs „1“ und „2“ aufweisen.

Furthermore, the electrode elements (2b, 2c, 2d) differ in their number of bipolar electrodes:

• Each bipolar electrode has two sub-electrodes. A first sub-electrode is formed from a row of point-like contact surfaces (for example marked “1” in the case of the electrode elements 2b and 2c), which are electrically conductively connected to one another. An associated second sub-electrode is also formed from a row of point-like contact surfaces (for example marked “2” in the case of the electrode elements 2b and 2c), which are electrically conductively connected to one another. All of the punctiform contact areas in a row are connected to one another in an electrically conductive manner. Furthermore, all rows of number 1 and all rows of number 2 are electrically connected to one another. The rows are arranged alternately. For better clarity, the row numbering was omitted in the case of the electrode element 2d. However, it is pointed out that these rows also have alternating sub-electrodes of type “1” and “2”.

The second electrode element 2b shown as an example has two bipolar electrodes. In contrast to this, the third and fourth electrode elements (2c, 2d) have a higher number of bipolar electrodes.

The electrode elements 2b, 2c and 2d differ in the number of bipolar electrodes and in the spacing of the point-like contact surfaces and in the size of the point-like contact surfaces. These three electrode elements thus each belong to different electrode element types. These electrode elements also have identification means on the back, each with four electrical contacts, as shown in 2 shown (reference number 28). The distinction can be made, for example, by electrically conductively connecting only a first and a second electrical contact for electrode element 2b, only a second and a third electrical contact for electrode element 2c, and only a third and fourth electrical contact for electrode element 2d. This enables unambiguous identification by means of a detection unit.

Claims (14)

Applicator for introducing high-frequency currents into the human body, with a base element (1) and at least one electrode element (2a), wherein the base element and the electrode element each have at least one electrical contact and the base element and electrode element are designed to interact in such a way that in a usage configuration with the electrode element arranged on the base element, the electrical contact of the electrode element (2a'.1, 2a'.2, 2a'.3) is electrically conductively connected to the electrical contact of the base element (1a, 1b, 1c), the electrode element being at least an electrode (2a.1) for application to human tissue, which is electrically conductively connected to the electrical contact (2a'.1) of the electrode element, characterized in that in the usage configuration the electrode element (2a) can be detached by means of a magnetic holder of the applicator is arranged on the base element (1), wherein the magnet holder has at least one permanent magnet (12) and at least one ferromagnetic counter-element (22), and the base element (1) has the permanent magnet (12) and the electrode element (2a) has the ferromagnetic counter-element (22), the permanent magnet (12) and/or the ferromagnetic counter-element (22) has a recess (25) which is designed in such a way that the base element (1) and electrode element (2a) make contact through the recess (25) in the usage configuration. applicator after claim 1 , characterized in that the base element (1) has a recess for the electrode element (2a). applicator after claim 2 , characterized in that the base element (1) has a recess (25) at which a portion of the surface of the electrode element (2a) facing the base element (1) is accessible in the usage configuration for manual detachment of the electrode element (2a). Applicator according to one of the preceding claims, characterized in that both the permanent magnet (12) and the ferromagnetic counter-element (22) are designed as approximately disc-shaped molded parts and/or that the shape of the base element (1) has at least one selective shaped area (14) and the electrode element (2a) has a selective shaped area (24) complementary thereto, which are designed to interact in such a way that the electrode element (2a) can be arranged on the base element (1) in only one orientation. applicator after claim 4 , characterized in that the shape areas (14,24) are designed and arranged such that in the configuration of use the selective shape area of the base element (14) and the complementary selective shape area of the electrode element Elements (24) are arranged facing one another, preferably resting against one another, in particular resting against one another in a form-fitting manner in at least one spatial direction. Applicator according to one of Claims 4 until 5 , characterized in that at least one selective shaped area (14) is designed as an indentation or bulge and/or that at least one selective shaped area (24) is designed as a depression, preferably as a recess that completely penetrates the electrode element (2a). Applicator according to one of the preceding claims, characterized in that the recess (25) is a rectangular recess. Applicator according to claim one of the preceding claims, characterized in that the base element (1) has a contact surface (11) for the electrode element (2a) and a contacting area (15) which is raised relative to the contacting surface (11) in such a way that in the usage configuration the contacting area (15) of the base element (1) penetrates the recess (25) of the ferromagnetic counter-element (22). Applicator according to one of the preceding claims, characterized in that the electrode element (2a) has an at least two-layer, preferably exactly two-layer structure, with a first layer facing the base element (1) in the usage configuration, which layer has the ferromagnetic element (22) and a second layer facing away from the base element (1) in the usage configuration, which has the electrode (2a) and preferably the electrical contact (2a'.1), in particular that the second layer is designed as a printed circuit board and/or that the first layer is designed as a ferromagnetic metal plate is formed. Applicator according to one of the preceding claims, characterized in that the base element has at least one detection means (18) and the electrode element has at least one identification means (28), which are designed and arranged to interact in such a way that in the usage configuration the electrode element can be identified by detecting the identification means the detection means is feasible. applicator after claim 10 , characterized in that the detection means (18) and the identification means (28) each have a plurality of electrical contacts which are arranged in such a way that, in the usage configuration, one contact of the detection means (18) is electrically conductively connected to one contact of the identification means (28). is. Applicator system, with an applicator according to one of the preceding claims and at least one second electrode element (2b, 2c, 2d), wherein the second electrode element (2b, 2c, 2d) has at least one electrode for application to human tissue, which is electrically conductive with an electrical contact of the second electrode element (2b, 2c, 2d) is connected, wherein the first electrode element (2a) differs from the second electrode element (2b, 2c, 2d) in at least one parameter from the group - number of electrodes, - area of electrodes, - distance of the electrodes, - Spatial arrangement of the electrodes differs, in particular that the first and second electrode element each have an identification means. applicator system claim 12 , characterized in that the applicator according to claim 11 is designed such that the identification means of the first and second electrode elements (2a, 2b, 2c, 2d) each have a plurality of electrical contacts and that the electrical contacts of the first identification means are connected differently than the electrical contacts of the second identification means. Device for generating high-frequency currents for the cosmetic and/or therapeutic treatment of tissue using electrodes (2a.1, 2a.2), comprising a high-frequency (HF) energy source for generating high-frequency currents and an applicator according to one of the preceding ones Claims 1 until 11 wherein, in the configuration of use, the electrode is electrically conductively connected to an output of the high-frequency energy source (3).

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