RU63688U1 - DEFIBRILLATOR ELECTRODE - Google Patents

Abstract

The utility model relates to medicine, and more particularly to equipment used in the treatment of patients with cardiac arrhythmias. The purpose of the utility model is to reduce trauma. The electrode comprises a housing, a sealing ring, a porous elastic gasket and a contact element made in the form of a spiral made of an electrically conductive material of circular cross section. 2 pf, 2 ill.

Description

The utility model relates to medicine, namely to cardiology and cardioreanimation, and is intended for the treatment of patients with cardiac arrhythmias.

When defibrillation by pulsed currents, good contact between the electrode and the skin of the patient is necessary. For this purpose, the skin is usually degreased, and the electrode is moistened with an electrically conductive solution. In case of poor contact, skin burns are possible.

A known method of electrotherapeutic effect on a patient, in which graphitized tissue is used as an electrode (1).

The disadvantage of this method is the inconvenience of use and the lack of effectiveness of the therapeutic effect in the treatment of patients with cardiac arrhythmias.

A known defibrillator electrode comprising a contact plate, a rod, a handle, a reservoir with an electrically conductive solution and an injection mechanism (2).

The disadvantage of this defibrillator electrode is the increased complexity of use in the treatment of patients with cardiac arrhythmias.

Known defibrillator electrode containing a housing, a rod, a spring, a handle and a contact plate (3).

The disadvantage of this defibrillator electrode is the design complexity and inconvenience of use in the treatment of patients with cardiac arrhythmias.

A known electrode containing a conductive cable with a core of graphitized filament (4).

The disadvantage of this electrode is the inability to use it for electrical exposure on the skin surface.

Known electrode containing a contacting element with a device that limits the area of contact with the skin of the patient (5).

The disadvantage of this electrode is the increased complexity of the design and the complexity of use.

A known electrode for physiotherapeutic effects on the patient’s body, made in the form of a plate of electrically conductive rubber, reinforced with an electrical conductor with increased conductivity (6).

The disadvantage of this electrode is the low effectiveness of the therapeutic effect in the treatment of patients with cardiac arrhythmias.

Also known is an electrode for a defibrillator comprising a housing, a sealing ring, a porous elastic gasket, contact and conductive elements (7).

The disadvantage of this electrode is the possibility of burns to the patient’s skin due to the uneven fit of the contact element to the patient’s body and the uneven distribution of the specific current density over the entire surface of the contact element.

The purpose of creating a utility model is to reduce the morbidity by increasing the uniformity of the current distribution on the working surface of the contact element.

This goal is achieved in that the contact element is made in the form of a flat spiral of electrically conductive material of circular cross section, and the output for connecting the contact element to the defibrillator is located in the central part of the case, and the case can be equipped with an attachment element to the patient’s body, made in the form of elastic belts.

Comparison of the proposed electrode with others known in the field of medicine, showed its compliance with the criteria of a utility model.

The utility model is illustrated by graphic material. Fig. 1 shows the proposed electrode for the defibrillator, a top view, and Fig. 2 - section AA in Fig. 1.

The defibrillator electrode comprises a housing 1 made in the form of a disk of dielectric material, a sealing ring 2, a porous elastic gasket 3 and a contact element 4 are located on the housing 1, the terminal 5 of which is located in the center of the housing 1 for connecting to the defibrillator conductor 6. Housing 1 can be equipped with an attachment element to the patient’s body, made, for example, in the form of elastic belts 7.

A useful model for the treatment of patients with cardiac arrhythmias is used as follows.

They impregnate the elastic porous pad with an electrically conductive fluid and place the electrode under the patient's back so that it is located under the heart region. If necessary, the housing is additionally fixed on the patient’s body using the fastening element 7. Under the weight of the patient’s body, the contact element 4 fits snugly on the patient’s skin, slightly changing its shape, which is ensured by its spiral design, the porous pad 3 is compressed under the influence of the patient’s body, moisturizing the skin and contact element 4. The conductor 6 is connected to the defibrillator and defibrillation is carried out according to the established method.

Due to the fact that the contact element 4 takes the shape of the patient’s body at the point of contact with it, and the contact surface is lubricated with an electrically conductive liquid, reliable contact with the skin of the patient is ensured, which eliminates the possibility of burns to individual skin areas.

Due to the fact that the contact element 4 is made of a metal conductor of circular cross section located in the form of a flat spiral, the discharge defibrillating current supplied in the central part of the spiral is evenly distributed over its entire surface, since free charges are located on the surface of the conductor. This is also facilitated by the fact that at the time of passage of current through the spiral conductor from the center of the spiral to

the periphery. Due to the low resistance of the electrode and the high resistance of the patient's body, the current tends to go from the center of the electrode to the periphery. On the other hand, due to the fact that the contact element 4 is made of a metal conductor of circular cross section in the form of a flat spiral, there is no contact between the turns of it, when an electric current passes from the center to the periphery, the self-induction EMF is directed in the opposite direction, i.e. . to the center of the electrode. Moreover, according to physical laws, this force will be the greater, the greater the strength of the flowing current. The interaction of the two named forces at the time of the defibrillator discharge also leads to a uniform distribution of the electric current density over the entire surface of the contact element.

All of the above increases the reliability of the electrode, eliminates the possibility of an edge effect during defibrillation, increases the effectiveness of the therapeutic effect and eliminates the damaging effects of electric current on the biological tissues of the patient (skin, muscles, heart).

The proposed electrode for the defibrillator is simple in design, reliable and efficient in operation.

The proposed utility model can and should be used in cardiology departments and intensive care units for the treatment of patients with cardiac arrhythmias.

INFORMATION SOURCES:

1. Auth. testimonial. USSR No. 3111644, cl. A 61 N 1/04, 1971

2. Auth. testimonial. USSR No. 296350, class A 61 N 1/04, 1971

3. Auth. testimonial. USSR No. 612684, cl. A 61 N 1/04, 1978

4. Auth. testimonial. USSR No. 1367980, class A 61 N 1/04, 1988

5. UK patent No. 2209282, CL A 61 N 1/04, 1989

6. RF patent No. 2082449 class. A 61 N 1/04, 1997

7. Auth. testimonial. USSR No. 694198, cl. A 61 N 1/04, 1979

Claims (2)

1. An electrode for a defibrillator comprising a housing, a sealing ring, a porous elastic gasket and a contact element, characterized in that the contact element is made in the form of a flat spiral of circular conductive material, the terminal for connecting the contact element to the defibrillator is located in the central part of the housing. 2. The electrode for the defibrillator according to claim 1, characterized in that the housing is equipped with an attachment element to the patient’s body, made in the form of elastic belts.