JPH0479253B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to disposable electrodes. The signal detection electrode according to the invention aims to achieve a noise-free signal detection of signals from the body by being fixed, for example, on the skin of a patient, and comprises a carrier element, one side is provided with an electrical contact and the other side is provided with an electrical contact. The surface is provided with an adhesive layer and is used as a disposable electrode intended to form the front side of the carrier element with the intention of adhering to the skin by means of electrical contact.

[Prior art and problems to be solved by the invention]

For example, in the case of electrocardiogram monitoring, both reusable and disposable electrodes are commonly used.
Disposable electrodes are constructed using small plates, usually made of rigid, unbendable plastic and coated with silver/silver chloride, which are arranged in the center of a self-adhesive plastic plate with some recesses formed within it. It has several parts. To make it possible to electrically connect the electrodes to a monitoring device or an onroscope, the silver plates are electrically connected by cables or metal contacts. Before applying the electrodes onto the skin, the wells in the silver plate are filled with conductive electrogel. Some types of commercially available electrodes are delivered with this electrolytic gel already added to them. The silver/silver chloride is used to achieve a low polarization potential and the gel is used to levitate the electrode to the skin, thereby avoiding noise in the signal transmission if the patient moves. However, adding gel requires great care. Too much gel causes the gel to float over the surface of the electrode covered by the adhesive. The adhesive effect of the electrode is thereby reduced and the electrode can be easily loosened after application on the patient's skin. Too little gel, on the other hand, results in poor electrical contact. Electrode types already doped with gels are dosed accurately in practice, but on the other hand have a finite storage time, since over time the gel will dry out or change its quality.

In order to achieve noise-free signal detection of human body signals with easy-to-apply electrodes,
What is important is that the adhesion ability of the electrode to the human body is very good, because if the patient moves, noise will easily appear due to instantaneous changes in impedance. . Several different electrodes intended for this purpose are available on the market and as many as possible are disclosed in the patent literature. For example, electrode devices are described in U.S. Pat.
No. 3,911,906, which comprises an adhesive layer applied onto a layer of an electrically conductive carrier element with carbon powder mixed therein. A metal contact is placed in the center of the circular electrode, but more precisely a nailing method is used.
procedure). The contact part mainly consists of a neck with an enlarged end at its top and is intended for connection to a standardized patient gable.
This electrode has several disadvantages. Among them, conductive adhesive layers cannot obtain completely noise-free signal detection from the skin because the impedance changes due to body movements on the skin. Due to the fact that the contacts must be fixedly mounted, the electrodes are expensive to manufacture.

The main object of the invention is to create a disposable electrode of the type described above, which is simple in construction, can be applied quickly and provides good electrical contact. . Another object of the invention is to
The object of the present invention is to provide an electrode that can be manufactured at low cost and that can be stored for a long period of time.

[Means for solving problems]

According to the invention, the aforementioned object provides that the adhesive layer on the front side of the carrier element has at least one opening in which a carbon-containing element in direct contact with the material of the carrier element is applied. This is achieved by

That is, according to the present invention, it is a disposable electrode that is fixed on a part to be measured of an object and whose main purpose is to achieve noise-free signal detection of each signal from the object body. , the electrode comprises a carrier element 1 of electrically conductive or semiconductive plastic material, one side of which carries an electrical contact 3 in electrically conductive contact with one side of the carrier element 1. provided, the carrier element 1
The other side of the carrier element is provided with an adhesive layer 5 and forms the front face of the carrier element intended to be adhered in electrical contact to the site to be measured, the electrode is made of non-metallic material, and The adhesive layer 5 on the front side of the carrier element has at least one opening into which a carbon-containing element 6 is added which is in direct contact with the material of the carrier element 1; a disposable electrode, characterized in that it is a carbon fiber cloth with carbon fiber ends protruding from the surface of the cloth as brushes in order to reduce the resistance between the site to be measured and the carrier element, is provided.

Another feature of the invention is that the carbon-containing element is a knitted carbon fiber cloth.

A further feature of the invention is that the carrier element and the electrical contact are integrally molded from a conductive or semiconductor material.

〔Example〕

A top perspective view of the disposable electrode according to the present invention is shown in FIG.
As shown in the figure. The planar carrier element 1 of the electrode and the electrical contact 3 are integrated using a conductor or semiconductor material, preferably molded from polyethylene mixed with carbon. If carbon is used as the conductive material, unwanted polarization effects are avoided with this material. The amount of carbon that must be included depends on the type of carbon used. A suitable mixing ratio of carbon may be 40 to 45%.

The carrier element 1 of the electrode is substantially circular and has around its outer edge a wide, thin and flexible bearing collar 4, in the center of which the part 2 is slightly elevated. The carrier element 1 is made with an adhesive layer 5 on its lower side, which is the contact or front surface, which adhesive layer is arranged to adhere the electrode to the patient's skin. . In the center of the front surface, the adhesive layer has a circular aperture with an outer diameter of, for example, 12 mm and no adhesive. The contact elements or plates 6 are arranged in a circular area such that their edges slightly overlap and are thus secured to the adhesive and thereby kept in place. Another method of fixing the plate 6 is to melt or sinter the plate against the front side of the carrier element. The plate 6 forming the contact surface against the patient's skin may be composed of a high-strength activated carbon fiber cloth or fabric, known as activated carbon fabric manufactured by SIEBE GORMAN, UK, for example. This is desirable. The total length of such carbon fibers can be on the order of several thousand meters per square centimeter, and it is also possible to essentially take advantage of the ionic transport between the patient's skin and the carrier element. The fiber ends of this cloth protrude from the cloth like a brush. The ends of these fibers come into contact with a larger number of carbon particles than, for example, a layer of silver, due to the fact that each point of the fiber end passes through a very thin layer that covers most of the charcoal particles. Because it does. Therefore, the surface resistance will be extremely reduced. Therefore, the transient resistance is approximately 10
twice as low.

As another example, carbon-containing plate 6
can be composed of a glue/gel mixture with a mixture of carbon fibers and/or carbon crystals in woven and/or rigid form.

A protective paper with an aperture in its center (not shown) is provided to protect against undesired adhesion of the electrodes during storage time.

In order to increase the conductive capacity to the patient's skin, the front surface of the electrode is provided with, for example, a wettex cloth, containing a physiological saline solution which may be effective up to 15%, preferably up to 8-10%. Plate 6, wet in a pot
Aspirate the solution immediately. The protective paper is removed and the electrodes are applied.

As another example, the carbon-containing plate 6
It is also possible that the electrodes can be formulated with a dry salt content that is immersed immediately before being applied to the skin, or that the salt can be wetted by body fluids or by the natural temperature of the human body. It is.

The absence of metals makes manufacturing extremely simple and inexpensive, and if the electrodes are prepared in a dry state, they can be stored for long periods without damage.

On the top side of the raised central part 2 of the electrode an electrode contact 3 with a neck 7 is arranged, at the top of which a widened top 8 is located.
The outer diameter of the top part 8 is 4 mm, and the outer diameter of the neck part 7 is 1/10.
It is thinner by two mm. Contacts 3 are internationally approved and fit commonly used contacts on patient cables (not shown).

Needless to say, the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the claims. It is thereby also possible to produce the electrodes in other designs or in other dimensions.
The central part 2 of the electrode can for example be designed with a smaller or larger outer diameter, and the effective diameter of the electrode can be selected to achieve better performance and conductivity. .
In the so-called working ECG monitoring situation, the electrodes are exposed to greater mechanical strain than in the normal case;
In such cases it is advantageous to use electrodes with large adhesive and/or contact areas. It is therefore possible to construct the electrode as a rectangular tape or the like with a carbon fiber fabric on the back side. For connection to the patient cable, a carrier element is used according to the invention.

The electrical connection of the electrodes can of course also be designed in other ways. For example, it is common for patient cables to have a 4 mm diameter pin, whereby the electrode has a socket (not shown) molded integrally with the electrode.

[Brief explanation of drawings]

FIG. 1 is an angular top view of a disposable electrode according to the present invention, FIG. 2 is a side sectional view of the disposable electrode, and FIG. 3 is a plan view showing the front side of the disposable electrode according to the present invention. DESCRIPTION OF SYMBOLS 1... Carrier element, 2... Center part, 3... Contact part, 4... Flexible bearing collar, 5... Adhesive layer, 6...
Carbon-containing plate, 7...net, 8...widened top.

Claims (1)

[Scope of Claims] 1. A disposable electrode that is fixed on a part to be measured of an object and whose main intention is to achieve noise-free signal detection of each signal from the body of the object. The electrode comprises a carrier element 1 of conductive or semiconductive plastic material, one side of which has an electrical contact 3 in conductive contact with one side of the carrier element 1. is provided, and the carrier element 1
The other side of the carrier element is provided with an adhesive layer 5 and forms the front face of the carrier element intended to be adhered in electrical contact to the site to be measured, the electrode is made of non-metallic material, and The adhesive layer 5 on the front side of the carrier element has at least one opening into which a carbon-containing element 6 is added which is in direct contact with the material of the carrier element 1; Disposable electrode, characterized in that it is a carbon fiber cloth with carbon fiber ends protruding from the surface of the cloth as brushes in order to reduce the resistance between the site to be measured and the carrier element. 2. Disposable electrode according to claim 1, characterized in that the carbon-containing element 6 is a knitted carbon fiber cloth. 3. Disposable electrode according to claim 1 or 2, characterized in that the carbon-containing element 6 is at least partially fixed to the carrier element 1. 4. Claims characterized in that the carbon-containing element 6 has a size slightly larger than the size of the opening in the adhesive layer, and is arranged so that its inner edges overlap slightly. Disposable electrode according to any one of clauses 1 to 3. 5. The carbon-containing element 6 is a mixture of glues and gels with a mixture of carbon fibers and/or carbon crystals in organized and/or rigid form. The electrode according to range 1. 6. Disposable electrode according to claim 1, characterized in that the carrier element 1 and the electrical contact 3 are integrally molded using a conductor or a semiconductor material. 7 The conductive or semiconducting material of the carrier element 1 is
7. Disposable electrode according to claim 6, characterized in that it is composed of a plastic material mixed with carbon. 8. Any of claims 1 to 7, characterized in that the carbon-containing element 6 is provided with a contact-improving salt solution prior to its addition to the intended application area. Disposable electrodes as described above. 9 The carbon-containing element 6 may be added prior to or when added to the intended use area.
Disposable electrode according to any one of claims 1 to 8, characterized in that it is provided with a content of dry salt intended for immersion.