RU2032377C1 - Spacer for flat electrode - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: this spacer for flat electrode includes porous member impregnated with nondrying electrolyte and electrode displacement limiter which is hollow dielectric casing which houses porous member and whose nonworking member includes holdfast. EFFECT: disclosed spacer reduces probability of transmission of infection in using nonexpendable electrodes and electric interference caused by patient's movements. 9 cl, 6 dwg

Description

 The invention relates to medical equipment, in particular to devices for conducting electrophysiological measurements and electrotherapy.

 Known electrode gasket, made in the form of a porous element impregnated with an electrolyte, which is associated with a latch that secures the gasket to the electrode. This gasket provides conductive contact between the electrode and the surface of the body. However, when the patient moves, the electrode moves relative to the body, and since the gasket is made of elastic material, the electrolyte ions move and the charges oscillate at the electrode-electrolyte interface. In this case, the displacement and oscillation data cause electrical noise in the measuring circuit. Due to the fact that the gasket is made of elastic material, the infection through it reaches the electrode surface, and when the electrode is reused, despite the fact that the gasket is replaced, the infection from the electrode surface can be transmitted to another patient, i.e. the use of this pad does not preclude the transmission of infection from one patient to another.

 The closest technical solution is an electrode gasket containing a porous element impregnated with a non-drying electrolyte, equipped with an electrode displacement limiter. This gasket also does not provide protection against electrical interference caused by patient movements, and does not exclude the transmission of infection when using a reusable electrode.

 The purpose of the invention is to reduce the likelihood of transmission of infection when using reusable electrodes and to reduce the level of electrical interference caused by patient movements, as well as to increase the reliability of fixation on the body, as well as to increase the accuracy and stability of measurements of biopotentials from small areas, for example, at acupuncture points, as well as to provide control biopotentials during electric exposure, as well as reducing interference when registering on surfaces with complex terrain.

 Figure 1 shows a view of the gasket in contact with the electrode; figure 2 gasket with a housing; figure 3 view a in figure 2; figure 4 curly gasket; figure 5 gasket with metallization; Fig.6 flexible gasket with metallization.

 The device contains a porous element 1 intended for contact with the electrode 2. The element 1 is impregnated with a non-drying electrolyte so that all its communicating pores are filled. An electrode displacement limiter 3 can be made in the element 1, for example in the form of a groove, which improves the fixation of the electrode 2. The element 1 can be located in the dielectric housing 4 containing the clamp 5, which can be made in the form of a tongue.

 The housing 4 may contain a latch 6 of the radial position of the electrode 2, which can be made in the form of a figured element, for example a radial protrusion, and the electrode must contain several radially located and intersecting grooves 7 in the center. A flat latch can be located in the working part of the housing 4 8, which for round electrodes 2 has a ring shape with an adhesive layer 9. The latch 6 can also be made in the form of recesses 10, which are designed to interact with the shank 11 of the electrode 2.

When the element 1 is shaped, the area of its working surface 12 is much smaller, for example, 10-20 times less than the area under the electrode. This is due to the fact that the working area used for measurements at acupuncture points is up to 10 mm ² , and the implementation of the electrodes of this area does not allow them to be obtained with good metrological characteristics. Increasing the area to 100-200 mm ² allows measurements from small areas with high accuracy. The figured element 1 can be fixed by means of the elastic element 15 with the housing 4. In the element 1, a part of the surface can be made with metallization 16 connected to the current lead 17, and also parts of the element 1 with the limiter 3 and metallization 16 can be connected through a flexible dielectric 18.

 Work with the gasket is as follows. In the simplest execution of the gasket, only in the form of an element 1 (see Fig. 1), it is applied to the surface of the body and an adhesive 2 is fixed with an adhesive plaster or rubber tape with perforation to it. The implementation of the limiter 3, corresponding to the dimensions of the working part of the electrode 2, eliminates the slipping of the electrode 2 on the contact surface, which reduces the level of electrical interference.

 The implementation of the element 1 (see figure 2) allows the first stage to fix the required number of gaskets to the body, and then insert the electrodes 2 connected to the cable into the housing 4. In this case, the spacings of the pads and electrodes are spaced apart in time, which allows increasing the throughput of electrocardiographic rooms, since while the ECG of one patient is being recorded, the medical staff is simultaneously preparing for registration of the next. With long-term periodic monitoring, housing 4 with element 1 allows repeated measurements in the same places, which increases the reliability of the assessment of the survey results. The clamp 5 provides the necessary pressing of the electrode 2 to the element 1, and also when the protrusion and recesses 10 on the electrode 2 are made on it, it is possible to fix the radial position of the electrode 2. In this case, the lateral tangential forces applied through the cable to the electrode 2 cause its axial movement with subsequent fixation by means of grooves 7 or recesses 10. This reduces the likelihood of the body 4 tearing off the surface of the body during possible cable movements.

 Conducting research at acupuncture points is conveniently done through the figured element 1 (see figure 3). The working surface 12 is, for example, in the form of a hemisphere, which eliminates skin injury. The fixing of the element 1 is carried out by the foot 13, which, for example, is made spring-loaded relative to the housing 4, and due to the presence of a slot 14 when the foot 13 is fed to the surface 12, it is easily replaced.

 If it is necessary to conduct electrophysiological studies in which significant measuring currents are required to pass, it is advisable to metallize 16 in the part of element 1, and potential characteristics can be recorded from the same element 1 by means of an electrode 2, located, for example, in the limiter 3. gives good results when conducting tetrapolar rheography. It is convenient to record signals on parts of the body surface with a complex relief by a gasket in which its individual parts, for example, metallization 16 and the limiter 3 are connected by means of a flexible dielectric 18, which ensures good contact over the entire surface under study. Element 1 can be made of a variety of materials with interconnected pores, such as ceramic. Moreover, the main thing is that element 1 should be solid, i.e. with all the efforts made to it, during operation, its geometric dimensions would not undergo changes that cause electrical interference.

Claims (9)

 1. GASKET FOR A PLANE ELECTRODE, containing a porous cell impregnated with a non-drying electrolyte, equipped with an electrode displacement limiter, characterized in that, in order to reduce the likelihood of infection transmission when using a reusable electrode and to reduce the level of electrical noise caused by patient movements, the porous element is made solid, the displacement limiter is made in the form of a hollow dielectric body, in the working part of which a porous element is installed, and the non-working part contains a clamp.  2. The gasket according to claim 1, characterized in that the clip is made in the form of a tongue.  3. The gasket according to claim 2, characterized in that, in order to increase the reliability of fixation on the body, in the working part of the housing contains a flat supporting element.  4. The gasket according to claim 3, characterized in that an adhesive layer is applied to the working surface of the flat support element.  5. The gasket according to claim 2, characterized in that the tongue is made in the form of a flat spring.  6. The gasket according to claim 1, characterized in that, in order to increase the accuracy and stability of the measurement of biopotentials from small areas, for example, at acupuncture points, by reducing the specific density of the measuring current flowing through the electrode, the porous element is shaped, and its area the working surface is less than the area of the contact surface under the electrode.  7. The gasket according to claim 6, characterized in that the clamp is made in the form of a foot with a slot for the working part of the figured porous element, mounted with the possibility of axial movement relative to the latter.  8. The gasket according to claim 1, characterized in that, in order to provide the possibility of controlling the biopotentials during electric exposure, for example, during rheography, a part of the surface on the non-working side of the porous element is made with metallization of the upper pore layer, which is connected to the current lead.  9. The gasket according to claim 8, characterized in that, in order to reduce interference when registering biopotentials on surfaces with complex relief, the porous element is made of at least two parts, one of which is metallized, the parts being interconnected by means of a flexible dielectric.

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