DE20220227U1 - Electrode arrangement, especially for electro-impedance tomography, has electrodes for electrically contacting measurement object attached to and positionable along length of belt-shaped carrier - Google Patents

Abstract

The electrode arrangement (1) has several electrodes (4) for electrically contacting a measurement object and a belt-shaped electrode carrier (3.2-3.4) for enclosing the measurement object, whereby the electrodes are attached to the carrier and can be positioned along the length of the carrier. The electrodes can be freely and durably positioned along the carrier.

Description

15955 Be/ps

ELECTRODE ARRANGEMENT Description

The invention relates to an electrode arrangement, in particular for electro-impedance tomography, according to the preamble of claim 1.

To perform the so-called electrical impedance tomography on a patient, numerous electrodes must be attached to the patient's chest, whereby precise positioning of the electrodes and permanent contact with the skin is important.

Electrode arrangements are therefore known in which the electrodes are attached to a belt-shaped electrode carrier made of an elastic material and placed around the patient's chest for measurement. The electrodes are fixed to the patient's skin mechanically or by gluing the electrodes.

A disadvantage of this known electrode arrangement, however, is the fact that the individual electrodes cannot be freely positioned in the circumferential direction, since the position of the individual electrodes is determined by the elasticity of the belt-shaped electrode carrier and the cross-sectional shape of the chest and can hardly or not at all be changed by the person being examined. In particular, it is not possible to set constant distances or angular distances between the individual electrodes with the known electrode arrangement, which is important in electro-impedance tomography.

The invention is therefore based on the object of improving the known electrode arrangement described above with a belt-shaped electrode carrier in such a way that the individual electrodes can be attached to the chest in the desired position.

The object is achieved, starting from the known electrode arrangement described above according to the preamble of claim 1, by the characterizing features of claim 1.

The invention includes the general technical teaching that the electrodes can be positioned on the belt-shaped electrode carrier in the longitudinal direction or in the circumferential direction of the belt-shaped electrode carrier, wherein the positioning should preferably be free and permanent within predetermined limits.

The positionability of the electrodes is preferably achieved by the belt-shaped electrode carrier being made at least partially of a plastically deformable material. The position of the individual electrodes on the thorax is preferably evenly distributed with preferably constant angular distances and/or can be changed by the person being examined by stretching the belt-shaped electrode carrier between the individual electrodes until the desired electrode distance is achieved. Due to the plasticity of the material of the belt-shaped electrode carrier, this electrode distance is maintained even when the person being examined no longer exerts any forces on the electrode carrier, which is the case, for example, when the electrode arrangement according to the invention is attached to the chest of a patient.

Preferably, the electrode carrier expands substantially uniformly over its length when stretched in the longitudinal direction. In this way, uniform distances or widths between the adjacent electrodes can be advantageously achieved.

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which is important for electrical impedance tomography. The electrode carrier is therefore preferably made of a material with homogeneous expansion behavior.

The plastically deformable material of the belt-shaped electrode carrier can be a plastic, for example, but other materials are also possible. It is also not necessary for the belt-shaped electrode carrier to be made entirely of a plastically deformable material. Rather, it is sufficient if the stretch sections between the individual electrodes are made of a plastically deformable material in order to enable the electrodes to be positioned in accordance with the desired electrode position on the thorax.

In a preferred embodiment of the electrode arrangement according to the invention, connecting lines are provided for electrically contacting the electrodes, wherein the connecting lines are attached to the belt-shaped electrode carrier and are stretchable in the longitudinal direction of the belt-shaped electrode carrier, so that damage to the connecting line is prevented when the belt-shaped electrode carrier is stretched in the circumferential direction.

One way to achieve the extensibility of the connecting lines is to route the connecting lines in a triangular, sinusoidal or meandering shape so that an expansion of the belt-shaped electrode carrier in the longitudinal or circumferential direction only leads to a slight deformation of the connecting lines, thus preventing damage to the connecting lines when the belt-shaped electrode carrier is expanded.

Another possibility, however, is that the connecting cables are made of an electrically conductive and yet mechanically stretchable material, so that, in a mean-

der-shaped routing of the connecting cables on the belt-shaped electrode carrier can be dispensed with.

Preferably, the belt-shaped electrode carrier consists of several parts which, when mounted on the measuring object, adjoin one another in the longitudinal direction of the electrode carrier and can be mechanically and/or electrically connected to one another in pairs. This division of the belt-shaped electrode carrier into several parts facilitates the attachment of the electrode arrangement according to the invention, particularly in bedridden patients, where only part of the chest is freely accessible at any one time.

The mechanical connection of the adjacent parts of the belt-shaped electrode carrier can be made, for example, by a plug connection or a crimp connection.

Preferably, however, the individual parts of the belt-shaped electrode carrier are attached to the measuring object separately from one another, for example by gluing the parts on.

Furthermore, in an advantageous variant of the invention, a contact liquid is provided for the electrical contact of the measuring object by the electrodes, which is stored in a reservoir, wherein the reservoir is attached to the belt-shaped electrode carrier. In this case, an optical and/or acoustic level indicator is preferably provided for the reservoir, which informs the patient or the person being examined in good time when the contact liquid is being used up. The level indicator therefore preferably generates an optical and/or acoustic warning signal, which allows a conclusion to be drawn about the level in the reservoir. The level indicator can be detected either electrically or chemically, but no other physical means are used.

see mechanisms for detecting the fill level in the storage container can be implemented.

The invention enables the electrode arrangement described above to be applied to a measurement object, such as the chest of a bedridden patient. In this case, the electrodes are first positioned in predetermined positions in the longitudinal direction of the belt-shaped electrode carrier, whereupon the electrode carrier with the electrodes is then attached to the measurement object, whereby the electrodes make electrical contact with the measurement object.

The positioning of the electrodes in the longitudinal direction of the belt-shaped electrode carrier before attaching the electrode arrangement according to the invention to the measurement object can be carried out, for example, by stretching the belt-shaped electrode carrier in the longitudinal or circumferential direction between the electrodes, wherein the thereby set and preferably uniform distance or angular distance between the adjacent electrodes is subsequently maintained due to the plasticity of the material of the electrode carrier.

In an advantageous variant of the invention, a template is also used which is placed on the measurement object. For example, the template can be placed in the form of a strip around the chest of a patient, with the excess length of the template being cut off so that the length of the template is equal to the circumference of the chest. The template can then be folded several times so that equidistant folds are created along the template, which form markings for positioning the individual electrodes.

The template can then be removed from the chest and placed on the belt-shaped electrode carrier, whereby the electrode carrier is positioned so that the position of the

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individual electrodes correspond to the position of the fold points.

With the multi-part design of the belt-shaped electrode carrier described above, the attachment of the electrode arrangement according to the invention is particularly simple, especially with a bedridden patient. To do this, first at least one part of the belt-shaped electrode carrier is attached to the exposed area of the chest of the lying patient. The patient is then rotated about its longitudinal axis, whereupon at least one further part of the belt-shaped electrode carrier is attached to the then exposed area of the patient's chest. The individual parts of the belt-shaped electrode carrier can then be electrically and/or mechanically connected to one another in pairs. Preferably, however, the individual parts of the belt-shaped electrode carrier are attached to the measurement object independently of one another and electrically connected separately from one another.

The electrode arrangement according to the invention can in principle have any number of electrodes. However, the number of electrodes is preferably a multiple of two or a power of two.

Other advantageous developments of the invention are characterized in the subclaims or are explained in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. They show:

Figure 1 shows an electrode arrangement according to the invention with a

multi-part belt-shaped electrode carrier and Figure 2a is an enlarged side sectional view of a part of the

Figure 1,

Figure 2b is a side sectional view of a part of the electrode arrangement according to the invention in normal size and

Figure 2c is a plan view of part of the electrode arrangement according to the invention.

The schematic representation in Figure 1 shows an electrode arrangement 1 according to the invention, which can be connected to a conventional EIT device 2 in order to carry out an electro-impedance tomography measurement.

The electrode arrangement 1 has a belt-shaped electrode carrier, which in this embodiment consists of four parts 3.1 - 3.4, wherein the individual parts 3.1 - 3.4 of the electrode carrier each carry four electrodes 4 on their side facing the measurement object, which electrically contact the patient's chest during the EIT measurement.

The individual electrodes 4 are each rectangular and aligned at right angles to the longitudinal axis or the circumferential direction of the belt-shaped electrode carrier. Other electrode shapes are also conceivable depending on the application.

The individual parts 3.1 - 3.4 of the belt-shaped electrode carrier each consist of a plastically deformable plastic, which enables positioning of the electrodes 4 in the circumferential direction in order to be able to maintain predetermined electrode positions on the patient's chest during the measurement.

For this purpose, a template in the form of a strip is placed around the patient's chest before the measurement, with the excess length of the template being cut off so that the length of the template corresponds to the circumference of the chest. The template is then folded four times along its length so that equidistant folds are created, each of which has a thickness of 1 mm.

The strip-shaped template is then placed next to the electrode carrier, with the individual parts 3.1 - 3.4 of the electrode carrier being stretched so that one of the electrodes is at one end of the template, while the positions of the other electrodes correspond to the fold points of the template.

When examining a bedridden patient using the EIT procedure, part 3.1 of the belt-shaped electrode carrier is first placed on the exposed area of the patient's chest.

The patient is then rotated around his longitudinal axis so that the second part 3.2 of the belt-shaped electrode carrier can be placed on the then exposed area of the patient's chest.

The two parts 3.1 and 3.2 are then electrically connected separately to the EIT device 2. Connection cables, each with a color-coded plug, are used for this purpose to prevent confusion. For example, part 3.1 can have a connection cable with a blue plug, while the plug on the connection cable for part 3.2 is red. For example, the plug on the plug for part 3.3 can be green, while the plug for part 3.4 is yellow.

The mechanical connection between the adjacent parts 3.1-3.4 of the belt-shaped electrode carrier is made by connections consisting of tongue-shaped plugs 5 and corresponding receptacles 6.

This process is then repeated for parts 3.3 and 3.4 of the belt-shaped electrode carrier until finally all parts 3.1 - 3.4 of the belt-shaped electrode carrier

are attached to the patient's chest, after which the EIT tomography can begin.

Figures 2a and 2b show side sectional views of one of the parts 3.1-3.4 of the electrode arrangement according to the invention, wherein the structure of the individual electrodes 4 can also be seen from Figure 2a.

Thus, part 3.1 of the belt-shaped electrode carrier has a rectangular cutout in the area of the electrodes 4.

On the side facing away from the measuring object, the cutout is covered by a liquid-impermeable layer 7, which is welded at its edges to part 3.1.

On the side facing the measuring object, however, the cutout in part 3.1 of the belt-shaped electrode carrier is covered by a partially permeable membrane 8.

The layer 7 and the membrane 8 enclose a contact liquid 9 which wets the surface of the measuring object and thereby reduces the contact resistance between the electrodes 4 and the measuring object.

Furthermore, it should be mentioned that the layer 7 is translucent, so that the person being examined can easily visually inspect the fluid level in the electrodes 4 in order to be able to replace the electrode arrangement in good time.

From Figure 2c it is also evident that the individual electrodes 4 each have separate connecting lines 10.1-10.4, which are brought together at a connection point 11, which enables contacting of all electrodes 4 of part 3.1 by means of a single plug connection.

In addition, the connecting lines 10.1, 10.3 and 10.4 are guided in a meandering shape in the area between the individual electrodes 4. This routing of the connecting lines 10.1, 10.3 and 10.4 offers the advantage that the connecting lines 10.1, 10.3, 10.4 are only slightly deformed when the part 3.1 is stretched in the longitudinal or circumferential direction, which counteracts damage.

The invention is not limited to the embodiment described above. Rather, a large number of variants and modifications are possible, which also make use of the inventive concept and therefore fall within the scope of protection.

Claims (14)

1. Electrode arrangement ( 1 ), in particular for electro-impedance tomography, with
several electrodes ( 4 ) for electrically contacting a measuring object,
a belt-shaped electrode carrier ( 3.1-3.4 ) to enclose the measuring object,
wherein the electrodes ( 4 ) are attached to the belt-shaped electrode carrier ( 3.1-3.4 ),
characterized in that
that the electrodes ( 4 ) on the belt-shaped electrode carrier ( 3.1-3.4 ) can be positioned in the longitudinal direction of the belt-shaped electrode carrier ( 3.1-3.4 ). 2. Electrode arrangement ( 1 ) according to claim 1, characterized in that the electrodes ( 4 ) on the belt-shaped electrode carrier ( 3.1-3.4 ) can be freely and permanently positioned in the longitudinal direction of the belt-shaped electrode carrier ( 3.1-3.4 ). 3. Electrode arrangement ( 1 ) according to claim 1 and/or claim 2, characterized in that the belt-shaped electrode carrier ( 3.1-3.4 ) consists at least partially of a plastically deformable material to enable the positionability of the electrodes ( 4 ). 4. Electrode arrangement ( 1 ) according to claim 3, characterized in that the electrode carrier stretches substantially uniformly over its length when stretched in the longitudinal direction. 5. Electrode arrangement ( 1 ) according to claim 3 and/or claim 4, characterized in that the plastically deformable material is a plastic or a fabric with a plastic coating. 6. Electrode arrangement ( 1 ) according to at least one of the preceding claims, characterized in that connecting lines ( 10.1-10.4 ) are provided for electrically contacting the electrodes ( 4 ), wherein the connecting lines ( 10.1-10.4 ) are attached to the belt-shaped electrode carrier ( 3.1-3.4 ) and are stretchable in the longitudinal direction of the belt-shaped electrode carrier ( 3.1-3.4 ). 7. Electrode arrangement ( 1 ) according to claim 6, characterized in that the connecting lines ( 10.1-10.4 ) run in a meandering manner on the belt-shaped electrode carrier ( 3.1-3.4 ). 8. Electrode arrangement ( 1 ) according to claim 6 and/or claim 7, characterized in that the connecting lines ( 10.1-10.4 ) consist of an electrically conductive and stretchable material. 9. Electrode arrangement ( 1 ) according to at least one of the preceding claims, characterized in that the belt-shaped electrode carrier ( 3.1-3.4 ) consists of several parts which, in the mounted state on the measuring object, adjoin one another in the longitudinal direction of the electrode carrier ( 3.1-3.4 ) and are mechanically connected to one another in pairs. 10. Electrode arrangement ( 1 ) according to claim 9, characterized in that a joining connection or a crimping connection is provided for the mechanical connection of adjacent parts of the belt-shaped electrode carrier ( 3.1-3.4 ). 11. Electrode arrangement ( 1 ) according to at least one of the preceding claims, characterized in that a contact liquid is provided for electrically contacting the measurement object, which contact liquid is stored in a storage container ( 9 ), wherein the storage container ( 9 ) is attached to the belt-shaped electrode carrier ( 3.1-3.4 ). 12. Electrode arrangement ( 1 ) according to claim 11, characterized in that the storage container ( 9 ) is integrated into the electrodes ( 4 ). 13. Electrode arrangement ( 1 ) according to claim 11 and/or claim 12, characterized by an optical and/or acoustic level indicator for the storage container. 14. Electrode arrangement ( 1 ) according to claim 13, characterized in that the level indicator detects the level electrically or chemically.