DE9316259U1 - Biomedical electrode - Google Patents

Description

The invention relates to a biomedical electrode consisting of an adhesive and conductive polymer layer, which is intended to be placed on the skin, and a covering layer covering the polymer layer away from the skin, to which an electrical connection element is attached, which protrudes through the covering layer and establishes contact with the polymer layer.

Such biomedical electrodes are primarily used to transmit electrical signals from the skin of a mammal, in particular from human skin, to an electromedical device, and possibly also to transmit electrical currents to the skin.

It is known to place such electrodes on the skin with a dry adhesive and electrically conductive layer. In a very simple structure, the electrode is completed by a support or carrier film to which a snap fastener element is attached, which serves to pick up the electrical signals and protrudes through the support or carrier film, thus establishing electrical contact with the conductive and adhesive layer. Such electrodes are known, for example, from EP 0 029 297 Bl or US 4 554 924.

Theodor-Heuss-Strasse 1 D-38122 Braunschweig

Bund^epjJbüHPeuftcMand.: ":

Telephone 0531-80079 Telex 0-9 52 620 gramm d Fax 0531-812 97

A wide variety of polymer materials have been proposed for the production of the adhesive and conductive layer. The materials can be based on naturally occurring polysaccharides or suitable synthetic polymers, which should polymerize as completely as possible.

A certain minimum size is required for such electrodes to adhere securely to the skin. It is therefore not possible to produce small electrodes, which are desirable in themselves. Furthermore, it has been shown that the adhesive effect of the conductive and adhesive layers, which are somewhat skin-compatible, is not so good that artifacts can be safely avoided.

The present invention is therefore based on the object of specifying a simple and reliable construction of a biomedical electrode of the type mentioned at the beginning.

This object is achieved according to the invention in that the polymer layer is introduced into a cavity, adhering to the cover layer, by pouring liquid, unpolymerized material into the cavity, which is then polymerized, and that the cavity is delimited on all sides parallel to the skin surface of the polymer layer in such a way that a flat continuation of the skin surface of the polymer layer is provided with a non-conductive adhesive layer.

The electrode structure according to the invention thus provides a cavity into which the adhesive and conductive polymer layer is introduced. The skin surface of the polymer layer intended to be placed on the skin continues flat on all sides with a non-conductive adhesive layer.

Accordingly, the biomedical electrode according to the invention forms a flat adhesive surface which is internally separated by the skin surface of the adhesive and conductive polymer layer and immediately adjacent to it by a non-conductive adhesive layer

is formed. Before the biomedical electrode is placed on the skin, the adhesive layer, which is thus constructed in at least two parts, is expediently covered by a protective film which can be removed before it is placed on the skin.

The inventive design of the biomedical electrode offers the advantage that a secure, artifact-free adhesion of the electrode to the skin is ensured by means of a non-conductive, skin-friendly adhesive, so that numerous suitable adhesives are available. The adhesive property of the adhesive and conductive polymer layer, preferably designed as a hydrogel, contributes to the secure adhesion of the electrode to the skin and to the prevention of relative movements between the skin and the skin layer of the electrode, but is only of minor importance for the adhesion of the electrode to the skin.

Particular advantages are achieved by the polymer layer being formed by pouring the liquid, unpolymerized material into the cavity, so that the polymerization of the polymer layer takes place in the cavity itself. It is particularly expedient to use a material that polymerizes using UV rays, as this makes the polymerization process easy to control. During the production of the adhesive and conductive polymer layer, the cavity is expediently sealed with a suitable film that is permeable to UV rays after the liquid, unpolymerized material has been poured in.

In a first embodiment of the invention, which is very easy to manufacture, the cavity is bordered on all sides parallel to the skin surface by a flexible foam layer, the surface of which facing the skin is coated with an adhesive.

The cavity is made by punching out the foam layer. The foam layer is at least predominantly closed-cell.

The cover layer is preferably fully coated with adhesive that bonds the cover layer to both the polymer layer and the foam layer.

For reasons of stability, it is advantageous if the cover layer extends beyond the polymer layer by at least 4 mm on all sides. However, this dimension is also sufficient so that very small electrodes can be produced with stability and with reliable functionality using the structure according to the invention. Suitable sizes for the cavity are 10 to 16 mm in diameter for a circular cavity, so that stable electrodes can be produced without any problems even with external dimensions of 23 to 30 mm.

For the foam layer, a material thickness of between 0.75 and 2.5 mm, preferably between 1.0 and 1.6 mm, can be selected.

In another embodiment of the invention, the cover layer is formed with a thermoplastic material and the cavity is formed by a trough-shaped deformation of the thermoplastic material. This significantly simplifies the structure of the electrode, since the cover layer itself can form the flat continuation of the skin surface of the polymer layer introduced into the cavity if it is coated on the skin side with a suitable skin-friendly pressure-sensitive adhesive.

The cover layer can be formed by a polymer film, which preferably consists of polyethylene or polyurethane. The thickness of the film can be between 50 and 800 μηι. A preferred thickness for PE films is in the order of 150 μηι and for PU films in the order of 200 μηι.

The formation of the cavity with a film allows a new and advantageous formation of body electrodes in - with the exception of the electrical connection - completely transparent. Both the polymer cover film and

The polymer layer in the cavity can also be made completely transparent. This has the advantage that the skin area covered by the electrode, for example during long-term ECGs, can be observed during operation, so that any hypersensitive reactions of the skin can be identified immediately and countermeasures can be taken.

The deformation of the thermoplastic covering material to form the cavity is preferably carried out thermally, for example by deep drawing. To maintain a dimensionally stable covering film, it can be expedient if the polymer film has rotationally symmetrical grooves that run around the cavity and are preferably circular. This significantly improves the shape and dimensional stability of the film deformed to form the cavity.

The simple formation of the cavity by deforming a thermoplastic cover film can have the disadvantage in sensitive patients that the skin reacts due to the reduced oxygen supply. This disadvantage can be remedied by providing the thermoplastic film with fine holes through which oxygen can reach the skin.

In an alternative embodiment, the breathability of the electrode can be improved by the covering layer in the area of the cavity consisting of a thermoplastic insert, to which a fabric or fleece layer is attached on the side. The insert can be made of polypropylene, for example, and can be thermally deformed to form the cavity. The fabric or fleece layer can surround the insert in a ring shape and be glued to it in an overlapping manner, preferably on the side of the plastic insert furthest from the skin. In this case, the skin-side flat surface of the electrode consists in the center of the skin surface of the conductive and adhesive polymer layer, followed by a ring-shaped

Flange surface of the molded plastic insert and then the ring-shaped fabric or fleece layer. The largest part of the surface of the electrode that covers the skin is made up of the outer fabric or fleece layer, which can be designed to be highly permeable to oxygen.

In any case, it is advisable for the cover layer to be evenly and completely coated with the pressure-sensitive adhesive on its skin-facing side.

The invention will be explained in more detail below using the embodiments shown in the drawing. They show:

Figure 1 - a vertical section through a first embodiment of a biomedical electrode according to the invention

Figure 2 - an exploded view of the parts of the electrode according to Figure 1

Figure 3 - a vertical section through a second embodiment of the biomedical electrode according to the invention
15

Figure 4 - an exploded view of the parts of the electrode according to Figure 3

Figure 5 - a vertical section through a third embodiment of the electrode according to the invention

Figure 6 - an exploded view of the parts of the electrode according to Figure 5.

According to the first embodiment of the electrode according to the invention shown in Figures 1 and 2, it consists of a cover layer 1 with a central opening 2 in which an electrical push-button connection 3 is fastened. The electrical push-button connection 3 is formed in two parts and consists of an outer part 4 and an inner part 5, which protrudes through the opening 2 into the outer part 4 and can be connected in a form-fitting manner to the outer part 4 through the cover layer 1 by compression in the manner of a rivet connection. The inner part 5 of the electrical connection 3 is formed on the skin side of the cover film 1 in a plate-like manner with a convexly curved underside. This is in contact with a

circular adhesive and conductive polymer layer 6, which is located in a cavity 7, which is made by punching out a circular part from a foam layer 8. The foam layer 8 is essentially oval and protrudes longitudinally on both sides beyond the cover layer 1. On one side, the foam layer 8 has a tongue-like projection 9. The side 10 of the foam layer 8 facing the skin is coated with a skin-friendly adhesive. The side 10 of the foam layer 8 coated in this way is flush with the skin side 11 of the adhesive and conductive polymer layer 6, so that the sides 11 and 11 form a uniform adhesive side facing the skin, which is covered by a protective film 12 before use. In order to make it easier to remove the protective film 12, an intermediate piece 13 in the form of the tongue-shaped attachment 9 is located between the protective film 12 and the foam layer 8 in the area of the tongue-shaped attachment 9, so that the film below the intermediate piece 13 rests against it in a non-adhesive manner and forms a grip tab by which the protective film 12 can be easily grasped and removed.

The flat design of the adhesive surface of the electrode, which is composed of the surfaces 10 and 11, is preferably achieved by filling the adhesive and conductive polymer layer 6 in liquid form into the cavity 7 delimited by the foam layer 8 and the cover layer 1 and only then allowing it to polymerize in situ, whereby the use of a UV-polymerizable material is recommended.

In the second embodiment of the invention shown in Figures 3 and 4, a cavity 7' for the conductive and adhesive polymer layer 6 is produced by a pot-shaped deformation of the cover layer 1 ' formed by a polymer film. The underside 10' of the polymer film 1 ^y continues the skin side 11 of the adhesive and conductive polymer layer 6 outwards. The polymer film 1' is provided with three concentrated

tric grooves 14, which are formed during the thermal deformation of the polymer film 1' to form the cavity 7' and during this deformation ensure that the polymer film 1' is not affected by the deformation - possibly also unevenly in its external dimensions.

Since the polymer film 1' is circular in the embodiment shown, this also applies to the protective film 12'. To form a grip tab, the intermediate piece 13' is adapted to the outer contour of the circular protective film 12' or the circular polymer film 1'.

Otherwise, all the same parts as in the embodiment according to Figures 1 and 2 are provided with the same reference numbers.

The electrode shown in Figures 3 and 4 offers the particular advantage that it can be manufactured completely transparent - except for the push-button connection 3, since both the polymer film 1' and the adhesive and conductive polymer layer 6 can be manufactured and used transparently.

A third embodiment of the invention is shown in Figures 5 and 6. Here too, the same parts as in the previous embodiments are provided with the same reference numbers. The difference to the second embodiment arises from the fact that the cover layer 1'' is not consistently made of a thermoplastic polymer film 1', but consists of a central plastic insert 15 and a fabric or fleece layer 16 surrounding this plastic insert 15 in a ring shape.

The plastic insert 15, which preferably consists of polypropylene, is thermally deformed into a trough shape and forms the cavity ' . The plastic insert 15 is closed at its outer edge with an annular flange 17, the underside 18 of which is connected to the underside 11 of the adhesive and conductive polymer

Layer 6 is aligned and is provided with a skin-friendly adhesive. The underside 19 of the fabric or fleece layer 16 is in turn aligned with the underside 18, so that the flat adhesive surface of the electrode is formed from the inside outwards by the underside 11 of the polymer layer 6, the underside 18 of the flange 17 of the plastic insert 15 and the underside 19 of the fabric or fleece layer 16.

The fabric or fleece layer 16 is punched out in a ring shape so that its inner edge overlaps the top of the flange 17 of the plastic insert 15 and is connected there by adhesive to the plastic insert 15.

The fabric or fleece layer 16 can be highly permeable to oxygen, so that the skin covered by the electrode is well supplied with oxygen over a large area, since the fabric or fleece layer 16 makes up the majority of the surface area of the electrode.

The respective adhesive and conductive polymer layer 6 is expediently produced for all embodiments by pouring it in liquid form into the cavities 7 , 7'. For this purpose, at least the boundary wall of the cavity remote from the skin, which is formed by the cover layer 1, 1', 1'' , is coated with a hypoallergenic pressure-sensitive adhesive based on acrylic resin, so that a stable connection to the walls of the cavities 7, 1' is produced.

The reaction solution, which was previously stored in a dark place, is then polymerized by irradiation with UV rays. Polymerization is complete after about 70 seconds.

A suitable preparation based on acrylic acid is, for example (in parts by mass):

100 Acrylic acid, stabilized with 0.05% hydroquinone methyl ether (pure)

300 Glycerol (86 %)
5

150 deionized water

5.0 Potassium chloride (pure)

10 3.5 Photoinitiator Darocur 1173 (Ciba Geigy)

58.8 Triethanolamine (pure)

5.3 Triethylene glycol dimethacrylate (pure) 15

3.0 Polyacrylic acid (Goodrite K702, 25% in water)

9.5 Amylopectin (solubilized). 20

The finished electrodes can be manufactured - as shown in the drawings - in bottle form, with a width of 24 mm and a length of 40 mm (including grip tab) as a mini electrode or as a normal-sized electrode in circular form with a diameter of 45 mm.

30 According to a standard test procedure, in which a measurement is taken at

The high quality of the electrical properties was determined by a test carried out on a pair of electrodes "face to face" (see US 4,848,353). These were as follows for the mini electrode:

35 190 DC resistance in Ohm (after 30 see, <

100 μα, 10 Hz)

185 as above, after defibrillation simulation

220V
40

0.3 DC self-potential in mV (after 60 seconds of stabilization)

9.4 DC residual potential in mV, 5 see after 45 defibrillation simulation)

0.0 DC potential decay rate in mV/sec, 30...35 see after defibrillation simulation.

For the electrode according to the second embodiment, the electrical properties were:

380 DC resistance in Ohm (after 30 seconds, < 100 μα, 10 Hz)

385 as above, after defibrillation simulation 220 V

0.3 DC self-potential in mV (after 60 see Stabilization

ization)

6.8 DC residual potential in mV, 5 see after defibrillation simulation) 15

0.0 DC potential decay rate in mV/sec, 30...35 see after defibrillation simulation.

In wear tests, the electrodes showed significantly superior properties in terms of adhesive strength, practically no residue on the skin after removal and any skin irritation that might occur compared to known electrodes with commercially available Karaya layers or layers according to US Patent No. 4,890,622.

Patent attorneys

Gramm + Lins 35 Li/ne

Claims (20)

1. Biomedical electrode comprising an adhesive and conductive polymer layer (6) which is intended to be placed on the skin, and a covering layer (1, 1', 1'') which covers the polymer layer (6) away from the skin and to which an electrical connection element (3) is attached which projects through the covering layer (1, 1', 1'') and establishes contact with the polymer layer (6), characterized in that the polymer layer (6) is introduced into a cavity (7, 7') in such a way that it adheres to the covering layer (1, 1', 1'') by pouring liquid, unpolymerized material into the cavity (7, 7') which is then polymerized, and in that the cavity (7, 7') is delimited on all sides parallel to the skin surface of the polymer layer (6) in such a way that a flat continuation of the skin surface (11) of the polymer layer (6) is provided with a non-conductive adhesive layer is given. 2. Electrode according to claim 1, characterized in that the cavity (7) is delimited on all sides parallel to the skin surface (11) by a flexible foam layer (8), the skin-side surface (10) of which is coated with an adhesive. Theodor-Heuss-Strasse 1 D-38122 Braunschweig Telephone 05 31-800 79
Telex 0-9 52 620 gramm d Fax 05 31-812 97 3. Electrode according to claim 2, characterized in that the foam layer (8) is at least predominantly closed-cell. 4. Electrode according to claim 2 or 3, characterized in that the cover layer (1) is coated over its entire surface with adhesive which bonds the cover layer (1) both to the polymer layer (6) and to the foam layer (8).
10 5. Electrode according to one of claims 2 to 4, characterized in that the covering layer (1) projects beyond the polymer layer (6) by at least 4 mm on all sides. 6. Electrode according to one of claims 2 to 5, characterized in that the foam layer (8) has a material thickness between 0.7 and 2.5 mm. 7. Electrode according to claim 6, characterized in that the foam layer has a material thickness between 1.0 and 1.6 mm. 8. Electrode according to claim 1, characterized in that the covering layer (I', I'') is formed with a thermoplastic material and the cavity (7') is formed by a trough-shaped deformation of the thermoplastic material. 9. Electrode according to claim 8, characterized in that the covering layer (1') is formed by a polymer film, preferably made of polyethylene or polyurethane. 10. Electrode according to claim 9, characterized in that the polymer film has a thickness between 50 and 600 µm. 11. Electrode according to claim 10, characterized in that the polymer film consists of polyethylene and has a thickness 3
in the order of 150 µm. 12. Electrode according to claim 10, characterized in that the polymer film consists of polyurethane and has a thickness in the order of 200 μm . 13. Electrode according to one of claims 9 to 12, characterized by a transparent polymer film. 14. Electrode according to claim 13, characterized by a transparent formation of the polymer layer (6) in the cavity (7 '). 15. Electrode according to one of claims 9 to 14, characterized characterized by rotationally symmetrical grooves (14) in the polymer film that run around the cavity (V). 16. Electrode according to claim 15, characterized in that the grooves (14) are circular. 17. Electrode according to claim 8, characterized in that the covering layer (I'') in the region of the cavity (7') consists of a thermoplastic insert (15), to which a fabric or fleece layer (16) is laterally connected. 18. Electrode according to claim 17, characterized in that the plastic insert (15) consists of polypropylene. 19. Electrode according to claim 17 or 18, characterized in that the plastic insert (15) has a diameter of approximately 25 mm. 20. Electrode according to one of claims 1 to 19, characterized in that the polymer layer (6) consists of a material polymerized by UV rays.