RU2085224C1 - Physiotherapeutic device and a method for affecting live cells of organism by way of transdermal electroneutrostimulation and with infrared emission - Google Patents

Abstract

FIELD: physiotherapeutic treatment. SUBSTANCE: device contains control panel with electronic unit forming bipolar asymmetric pulses with rectangular positive part approaching triangular one with steep front and exponential back, wherein amplitude of positive part is equal to 25 V and that of negative part is varied within the range from 0 to 185 V. Infrared emission source is also incorporated. Electrode is constructed in the form of attached multielectrode plate, on which electric pulse-intake multielectrodes in the form of contact rods and infrared emitters are disposed. Contact rods are arranged in three sets to form multielectrode stripe, and distance between adjacent contact rods in each set and distance between adjacent sets are the same. EFFECT: achieved compounded effect of electric pulses and infrared irradiation. 12 cl, 2 dwg

Description

 The invention relates to a physiotherapeutic device and method for acting on living cells of the body by percutaneous electroneurostimulation and infrared radiation used in medicine to treat a wide range of diseases.

 Known apparatus of magneto-infrared irradiation "MIO-1" (passport 3.293.000 PS, plant "Magma", Rybinsk), containing a source of infrared radiation and three infrared emitters located at a distance of 5 cm from each other. The device is designed for topical application to the wound area or focus of inflammation.

 A known method of percutaneous electroneutrostimulation, in which parts of the skin were exposed to electric pulses in the form of a bipolar asymmetric pulse with a rectangular positive part and a negative part close to triangular with a steep leading edge and exponential trailing edge, and the amplitude of the positive part of the pulse is 25 B, and the amplitude of the negative part is smoothly regulated from 0 to 185 B. Current issues in the development of equipment and methods of electroneurostimulation in medicine: С ornik. Kuibyshev, 1990, p. 19-23). To implement this method, the device "Electronics CHENS-2M" was used. Electrical pulses were applied to the skin areas using an electrode made in the form of a multi-electrode head, on which multi-electrodes are located in the form of contact pins (10 pieces). The exposure was carried out by moving the multi-electrode head on the surface of the body manually (to the area of pain).

 The disadvantage of this device is that it is necessary to move the multi-electrode head manually for a sufficiently long time of 5-10 minutes. With the patient’s independent work with the device, they are available to affect all parts of the body.

 The basis of the invention is the task of optimizing the effect on living cells of the body while reducing the parameters and time of exposure to electrical pulses and infrared radiation.

 The problem is solved in that in a physiotherapeutic device for exposure to living cells of the body by percutaneous electroneurostimulation and infrared radiation containing a control panel, in which there is an electronic unit that generates electrical pulses in the form of a bipolar asymmetric electric pulse with a rectangular positive part and a negative part, close to triangular with a steep leading edge and exponential trailing edge, and the amplitude of the positive part of the imp of ice is equal to 25 V, and the amplitude of the negative part is continuously adjustable from 0 to 185 B, and the electrode connected to the control panel in the form of a multi-electrode head, on which multi-electrodes are located in the form of contact pins, for exposure to electric pulses on the skin, according to the invention, the control panel has a source of infrared radiation, and that the electrode leading to the skin areas in different predetermined sequence, electrical pulses and infrared signals generated in the electronic unit the red radiation from the infrared radiation source is made in the form of a multi-electrode patch plate, on which there are multi-electrodes in the form of contact pins for supplying electrical pulses and infrared emitters, the contact pins being arranged in three rows to form a multi-electrode track, and the distance between adjacent contact pins is each row and the distance between adjacent rows is equal.

 The multi-electrode patch plate can be in the form of a rectangle, with two multi-electrode tracks symmetrically relative to the longitudinal axis of the plate, and the emitters are located between the inner rows of contact pins of two multi-electrode tracks symmetrically with respect to the longitudinal axis of the plate in one row on each side, and the distances between the radiators in each row are equal.

 The multi-electrode patch plate may be in the form of an oval, along the edge of which there is a closed multi-electrode track, and four emitters are located symmetrically with respect to the center of the oval.

 The problem is also solved by the fact that in the method of exposure to living cells of the body by percutaneous electroneurostimulation and infrared radiation, in which parts of the skin are exposed to electric pulses in the form of a bipolar asymmetric electric pulse with a rectangular positive part and a negative part close to triangular with a steep leading edge and exponential trailing edge, and the amplitude of the positive part of the pulse is 25 B, and the amplitude of the negative hour These infinitely adjustable from 0 to 185 B, according to the invention, the skin areas are affected by electric pulses in different predetermined sequences and at the same time continuously supply infrared radiation for a predetermined period of time.

 It is advisable to implement the method according to the invention to use a physiotherapeutic device of the above type.

 It is advisable that in the method according to the invention, in a rectangular multi-electrode patch plate, electrical pulses are applied sequentially to each pair of contact pins of one multi-electrode track from one end to the other, and then in the same sequence to the contact pins of another multi-electrode track.

 It is advisable that in the method according to the invention, in a rectangular multi-electrode patch plate, electrical pulses are applied to each pair of contact pins of one multi-electrode track sequentially from one end to the other, and then in the opposite direction to the beginning of the multi-electrode track, after which the electrical pulses are applied in the same sequence to the contact pins of another multi-electrode track.

 It is advisable that in the method according to the invention, in a rectangular multi-electrode patch plate, electrical pulses are applied sequentially to each pair of contact pins of both multi-electrode tracks from one end to the other simultaneously and in one direction.

 It is advisable that in the method according to the invention, in a rectangular multi-electrode patch plate, electrical pulses are applied sequentially to each pair of contact pins of both multi-electrode tracks simultaneously from opposite ends of the tracks towards each other.

 It is advisable that in the method according to the invention, in an oval multi-electrode patch plate, electrical pulses are applied in a clockwise direction to each pair of contact pins of the multi-electrode track.

 It is advisable that in the method according to the invention in an oval multi-electrode patch plate, electrical pulses are applied to each pair of contact pins of the multi-electrode track in a counterclockwise direction.

 It is advisable that in the method according to the invention, in an oval multi-electrode patch plate, electrical pulses are applied alternately in a clockwise and counterclockwise direction to each pair of contact pins of the multi-electrode track.

 Due to the combination of the two methods of applying electric pulses and infrared radiation to living cells of the body and the use of a bipolar asymmetric pulse with a rectangular positive part and a negative part close to triangular, with a steep leading edge and exponential trailing edge, in which the amplitude of the positive part is 25 V, and the amplitude of the negative part varies from 0 to 185 V, the output current of the device can be reduced to 5 mA instead of 50 mA in known devices. The distance between the multi-electrodes in the form of contact pins on the laid on multi-electrode plate is small and can be approximately 2-3 mm, so that the current does not flow through the vital organs. The infrared emitters in the patch multi-electrode plate are directed to the region of sensitive reflex zones.

 The supply of electrical pulses to the multi-electrodes in a different predetermined sequence in combination with infrared radiation, as well as the ability to control the amplitude of the electrical pulse, allows you to get a positive effect in a shorter time and fewer procedures than when using known devices. Small current parameters allow the device to be used to treat patients with acute pathology, including after operations.

 In FIG. 1 shows a rectangular invoice multi-electrode plate, General view; in FIG. 2 oval overhead multi-electrode plate, general view.

 The physiotherapeutic device consists of a control panel (not shown) and two types of overhead multi-electrode plates rectangular 1 (Fig. 1) and oval 2 (Fig. 2), which are connected to the control panel depending on the part of the body on which the plate should be applied.

 A rectangular multi-electrode patch plate 1 is made of a soft material, for example, leather. On it are located multi-electrodes in the form of contact pins 3 symmetrically with respect to the longitudinal axis 4 of the plate. On each side of the axis 4, the contact pins 3 are arranged in three rows that form the multi-electrode tracks 5.6. The distance between adjacent contact pins in each row and the distance between adjacent rows are equal. Between the inner rows of contact pins 3 of the multi-electrode tracks 5.6 symmetrically relative to the longitudinal axis 4 of the plate are infrared emitters 7. In this embodiment, five pairs of LEDs are used as infrared emitters.

 The oval multi-electrode patch plate 2 is also made of a flexible material, such as leather. On the edge of the oval are the contact pins 3 of the multi-electrodes in three rows, which form a closed multi-electrode track 8. The emitters 7 of infrared radiation are located in the center of the plate symmetrically relative to the center 9 of the oval. In this embodiment, four LEDs are located on an oval patch plate.

 The control panel contains an electronic unit that generates electrical impulses, an infrared radiation source, a program unit that supplies electrical impulses to overhead multi-electrode plates in a different predetermined sequence.

 Using the control panel, the amplitude of the electrical pulses is regulated, the operating modes are switched, i.e. the desired sequence of supplying electrical pulses to the patch plates is set, a separate command is given to start supplying electrical pulses and infrared radiation to the multi-electrode patch plates, the infrared radiation is monitored, each multi-electrode track is monitored on the rectangular patch plate and the multi-electrode track is on the oval patch plate, s using the timer, the time is set from 1 to 15 minutes, and the end of the set time is signaled separately to infrared radiation and electrical impulses.

Physiotherapeutic device operates as follows. One of the overhead multi-electrode plates 1 or 2 is connected to the control panel depending on the part of the body on which it is necessary to apply the plate for treatment. The rectangular patch plate 1 is conveniently used for laying on the back, and oval 2 on the stomach. Set the exposure time of infrared radiation in the range from 1 to 15 minutes At the same time, the mode of exposure to electric pulses is selected. For a rectangular patch plate, the following modes of supplying electrical pulses are possible:
1. Electrical pulses are applied sequentially to each pair of contact pins 3 of one multi-electrode track 5 from one end to the other, then in the same sequence to the contact pins of another multi-electrode track 6.

 2. Electric pulses are supplied to each pair of contact pins 3 of one multi-electrode track 5 sequentially from one end to the other, and then in the opposite direction to the beginning of multi-electrode track 5, after which electric pulses are fed in the same sequence to contact pins 3 of another multi-electrode track 6.

 3. Electrical pulses are applied sequentially to each pair of contact pins 3 of both multi-electrode tracks 5 and 6 from one end to the other simultaneously and in one direction.

 4. Electrical pulses are applied sequentially to each pair of contact pins 3 from both multi-electrode tracks 5 and 6 simultaneously from opposite ends of the tracks towards each other.

For an oval patch plate, the following modes of supplying electrical pulses are possible:
1. Electrical pulses are applied to each pair of contact pins 3 of the multi-electrode track 8 in a clockwise direction.

 2. Electrical pulses are applied to each pair of contact pins 3 of the multi-electrode track 8 in a counterclockwise direction.

 3. Electric pulses are applied to each pair of contact pins 3 of the multi-electrode track 8 alternately in a clockwise and counterclockwise direction.

 The use of a physiotherapeutic device of the claimed type is accompanied by an effect on a strictly defined surface of the body, resulting in a vasodilating effect, a marked improvement in microcirculation, pronounced analgesia, anti-inflammatory effect, a decrease in local muscle hypertension, an increase in the level of beta-endorphins in the cerebrospinal fluid, activation of the antinociceptive system of the brain, pronounced stimulation of reparative processes in internal organs, stimulation of immunity.

Claims (12)

 1. Physiotherapeutic device for influencing living cells of the body, comprising a control panel in which an electronic unit is located that generates electrical pulses in the form of a bipolar asymmetric electric pulse with a rectangular positive part and a negative part close to triangular with a steep leading edge and exponential trailing edge moreover, the amplitude of the positive part of the pulses is 25 V, and the amplitude of the negative part is continuously adjustable from 0 to 185 V, and the control unit connected to the panel an electrode in the form of a multi-electrode head, on which multi-electrodes are located in the form of contact pins, for applying electric pulses to areas of the skin, characterized in that the control panel has an infrared radiation source, an electrode that leads to the areas of the skin in a predetermined sequence formed in electronic block electrical pulses and infrared radiation from a source of infrared radiation, made in the form of a multi-electrode patch plate, on which th are multi-electrodes in the form of contact pins for supplying electrical pulses and infrared emitters, the contact pins being arranged in three rows to form a multi-electrode track, and the distance between adjacent contact pins in each row and the distance between adjacent rows are equal.  2. The device according to p. 1, characterized in that the multi-electrode patch plate has a rectangular shape, while two multi-electrode tracks are located symmetrically relative to the longitudinal axis of the plate, and the emitters are located between the inner rows of contact pins of the multi-electrode tracks symmetrically relative to the longitudinal axis of the plate in one row with each side, and the distances between the emitters in each row are equal.  3. The device according to p. 1, characterized in that the multi-electrode patch plate has an oval shape, on the edge of which there is a closed multi-electrode track, and four emitters are located symmetrically with respect to the center of the oval.  4. The method of exposure to living cells of the body, in which parts of the skin are affected by electric pulses in the form of a bipolar asymmetric electric pulse with a rectangular positive part and a negative part close to triangular with a steep leading edge and exponential trailing edge, and the amplitude of the positive part of the pulse equal to 25 V, and the amplitude of the negative part is smoothly regulated from 0 to 185 V, characterized in that the areas of the skin are affected by electric Pulse in different predetermined sequence and simultaneously continuously fed to the infrared radiation for a predetermined period of time.  5. The method according to p. 4, characterized in that for its implementation using a physiotherapeutic device according to paragraphs. thirteen.  6. The method according to PP. 4 and 5, characterized in that in a rectangular multi-electrode patch plate, electrical pulses are applied sequentially to each pair of contact pins of one multi-electrode track from one end to the other, and then in the same sequence to the contact pins of another multi-electrode track.  7. The method according to PP. 4 and 5, characterized in that in a rectangular multi-electrode patch plate, electrical pulses are applied to each pair of contact pins of one multi-electrode track sequentially from one end to the other, and then in the opposite direction to the beginning of the multi-electrode track, after which the electrical pulses are supplied in the same sequences on the contact pins of another multi-electrode track.  8. The method according to PP. 4 and 5, characterized in that in a rectangular multi-electrode patch plate, electrical pulses are applied sequentially to each pair of contact pins of both multi-electrode tracks from one end to the other simultaneously and in one direction.  9. The method according to PP. 4 and 5, characterized in that in a rectangular multi-electrode patch plate, electrical pulses are applied sequentially to each pair of contact pins of both multi-electrode tracks simultaneously from opposite ends of the tracks towards each other.  10. The method according to PP. 4 and 5, characterized in that in the oval multi-electrode patch plate, electrical pulses are supplied in a clockwise direction to each pair of contact pins of the multi-electrode track.  11. The method according to PP. 4 and 5, characterized in that in an oval multi-electrode patch plate, electrical pulses are applied to each pair of contact pins of the multi-electrode track in a counterclockwise direction.  12. The method according to PP. 4 and 5, characterized in that in the oval multi-electrode patch plate, electrical pulses are applied alternately in a clockwise and counterclockwise direction to each pair of contact pins of the multi-electrode track.

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