RU90334U1 - DEVICE FOR TRANSMISSION ELECTRON NEURO-STIMULATION (OPTIONS) - Google Patents

Abstract

1. Device for percutaneous electroneurostimulation, containing a source of electrical impulses, a control panel with an indication unit and an external therapeutic element, divided into anatomical zones and having a longitudinal axis, on which electrodes are mounted, made in the form of active and passive coaxial contact plates having a convex surface and located symmetrically relative to the longitudinal axis of the remote therapeutic element, with one group of electrodes located at the end of the remote therapeutic element about the element in the zone of projection of the cervical spine onto it, the second group of electrodes is located along the longitudinal axis of the external therapeutic element along its entire length, and the third group of electrodes is located in the central part of the external therapeutic element in the zone of projection of the thoracic spine on it parallel to the second group of electrodes, located along the longitudinal axis of the remote therapeutic element, the external therapeutic element is connected to the source of electrical impulses through the switching unit and electrodes, characterized in that the external therapeutic element is additionally equipped with a fourth group of active and passive electrodes placed pairwise on its longitudinal axis along its entire length, the electrode switching unit is placed in the external therapeutic element, the electrode switching unit comprising an electric pulse analyzer, a power regulator , a multiplexer, a control device, program memory and a shaper of the feedback signal, while the source of electrical pulses is connected in series

Description

A group of utility models relates to medical equipment and can be used in physiotherapy for rehabilitation treatment at all stages of various diseases using electroneurostimulating effects.

Known multi-channel electrical stimulator containing electrodes connected to the corresponding outputs of the switching unit, as well as a synchronization unit, the first input of which is connected to an external source of sinusoidal modulated current, the second output to the first output of the control unit, the first output to the first input of the timer, the second output to the first input of the control unit, the second output of which is connected to the second input of the timer, the third output - with the first input of the program setting unit, and the fourth output - with the control input of the switching unit the output of which is connected to the second input of the program setting unit, while the timer output is connected to the second input of the control unit, the third input of which is connected to the output of the program setting unit. A pseudo-random binary sequence of signals and a polarity switch are introduced into the program setting unit, and the third output of the synchronization unit is connected to the input of the pseudo-random binary sequence of signals, the output of which is connected to the first input of the polarity switch, the second input of which is connected to the first input of the switch of the synchronization unit, and the output connected to the input of the switching unit (see patent for invention of the Russian Federation No. 2017508, IPC (5) A61N 1/36, application filing date 10/12/1992, published on 08/15/1994 "A lot Anal pacemaker ").

A disadvantage of the known device is the inability to change the power and frequency of electrical pulses in accordance with the feedback signal received from the patient, as well as the inability to selectively supply electrical pulses to the electrodes depending on the exposure program, which reduces the effectiveness of electroneurostimulation.

In addition, the disadvantages include the presence of separate electrodes connected by wires, requiring their fixation with an elastic bandage on the patient’s body and assistance when changing the exposure zone, as well as direct contact of the wires with the patient’s body, which reduces the safety of the device and complicates its operation.

Known electron-adaptive stimulator (options) with an electrode device, in which the electron-neuroadaptive stimulator contains a direct current source, a key amplifier, a control unit for generating triggering pulses, the signal output of which is connected to the signal input of the key amplifier, an electrode device including N electrodes, N electronic controlled keys turning on the electrodes of the electrode device in the "active electrode" mode and a two-section high-quality inductor, sections of which oh included according to, the connection point of the sections is connected to the first pole of the DC source, the second end of the section with fewer turns through the key amplifier is connected to the second pole of the DC source, and the second end of the section with more turns is connected to the input of the feedback signal of the control unit and generating triggering pulses and a switched input of each of the N electronic controlled keys to turn on the electrodes of the electrode device in the "active electrode" mode.

Moreover, in the first embodiment, the electro-neuroadaptive stimulator additionally contains N electronic controlled keys for turning on the electrodes of the electrode device in the “passive electrode” mode and an electrode assignment setting unit, the code input of which is connected to the code output of the control unit and generating triggering pulses, and the control input with the control output of the block control and formation of triggering pulses, a 2N outputs - with the corresponding control inputs of N electronic controlled keys to turn on the electrodes the electrode device to the "active electrode" mode and N electronic controlled keys to turn on the electrodes of the electrode device to the "passive electrode" mode, the switched input of each of the N electronic keys to turn on the electrodes of the electrode device to the "passive electrode" mode is connected to the first pole of the DC source, output of each of the N electronic controlled keys for turning on the electrodes of the electrode device in the "active electrode" mode is combined with the output of the corresponding electronic controlled key turning on the electrodes of the electrode device in the "passive electrode" mode and connected to the corresponding input of the electrode device.

In a second embodiment, the trigger pulse generating unit comprises an operation mode setting unit, including at least stimulus energy level control elements and a power-on element, an indication unit, and pulse analysis, control and pulse generation unit made in the form of an ultra-large integrated circuit (VLSI), VLSI installation inputs are connected to the outputs of the operation mode setting node, the indication node inputs are connected to the VLSI information outputs, the VLSI signal output is the signal output of the control unit and start pulse generation, the VLSI code output is the code output of the control unit and the formation of start pulses, the VLSI control output is the control output of the control unit and the formation of start pulses, the VLSI signal input is the input of the feedback signal of the control unit and the formation of start pulses, and the VLSI has at least two operating modes, in the first of which at the pulse output of the control unit and the formation of trigger pulses there are a series of trigger pulses a fixed number of pulses in a series, and at the code output a sequence of codes from 1 to N, where N is the number of controlled electronic keys, the code change in which occurs with each series of triggering pulses, and in the second - at the pulse output a continuous sequence or sequence of series of triggering pulses , on code output - immutable code. In this case, the electrode device for the electro-adaptive stimulator contains a connector for connecting an electro-adaptive stimulator, current-conducting conductors and electrodes, further comprises an elastic substrate with contact slots fixed to it for connecting electrodes, each contact of the connector for connecting an electro-adaptive stimulator with a current-conducting conductor is connected to a corresponding contact socket, and electrodes and contact sockets for their connection are located on the reverse side x elastic substrate (see patent for the invention of the Russian Federation No. 2262957, IPC (7) A61N 1/36, A61N 1/04, application filing date 09.03.2004, published on 10.27.2005 "Electroneuroadaptive stimulator (options) and electrode device").

A disadvantage of the known device is the inability to change the power and frequency of electrical pulses in accordance with the feedback signal received from the patient, as well as the inability to selectively supply electrical pulses to the electrodes, which reduces the effectiveness of electroneurostimulation.

In addition, the electrode device, in which a single active electrode is surrounded by six passive electrodes, does not allow predicting the zone of influence of electric pulses, which also reduces the efficiency of electroneurostimulation.

A disadvantage of the known device is that the electrode device is applied and fixed on the back of a person with an elastic bandage or adhesive plaster, which complicates the operation of the electrode device, as it requires outside help, including when changing the exposure zone.

In addition, the switching of the electrodes of the electrode device with the electric stimulator, provided due to the galvanic connection between the power source and the electrodes of the electrode device, leads to a decrease in the safety of the electrode device.

Closest to the claimed utility model is a device for percutaneous electroneurostimulation containing a power source, a unit for generating bipolar electrical impulses and an integrated and external therapeutic electrodes. In this case, the remote electrode is connected to the bipolar electric pulse generation unit through an electronic controller and is made in the form of a multi-electrode patch plate (mat), on which pairwise connected electrodes are located in the form of round coaxially arranged plates, and the contact plates are arranged in two rows with the formation of a multi-electrode track. The outer contact plate of the electrode has a convex surface. Two multi-electrode tracks are located symmetrically relative to the longitudinal axis of the patch plate, and the distal end of the patch plate on both sides parallel to the main multi-electrode tracks at the gap between 13 and 14, 14 and 15 pairs of electrodes are located and connected to them by two additional electrodes, and at the proximal end in the center of the patch plate in front of the first pair of electrodes is a coccygeal electrode protruding above the plate surface to a height greater than the other electrodes. The distance between the contact plates is 3 mm, and the radius of the convex surface of the external contact plate of the electrode is 5 mm (see patent for utility model of the Russian Federation No. 51505, IPC (8) A61N 1/32, application date 08/17/2005, published 02/27/2006 "Device for percutaneous electroneurostimulation").

A disadvantage of the known device is the inability to change the power and frequency of electrical pulses in accordance with the feedback signal received from the patient, as well as the inability to selectively supply electrical pulses to the electrodes, which reduces the effectiveness of electroneurostimulation.

In addition, a multi-electrode patch plate is applied and fixed to the person’s back with a bandage of elastic fabric, and a more snug fit to the person’s body is achieved using elastic rollers, which complicates the operation of the device, as it requires outside help, including when changing the exposure zone.

The disadvantages of the known device include the use of an external multicore cable connecting the electronic controller and the external therapeutic electrode (element), which reduces the safety of the device.

The technical result of the claimed group of utility models is to increase the efficiency of electroneurostimulation by changing the power and frequency of electrical pulses in accordance with the feedback signal from the patient, as well as to increase the ease of operation and safety of the device.

According to the first embodiment, the claimed technical result is achieved by the fact that in the inventive device for percutaneous electroneurostimulation containing a source of electrical impulses, a control panel with an indication unit and an external therapeutic element, divided into anatomical zones and having a longitudinal axis, on which electrodes are made, made in the form of the convex surface of the active and passive coaxial contact plates and located symmetrically relative to the longitudinal axis of the external therapeutic e element, and one group of electrodes is located at the end of the external therapeutic element in the projection zone of the cervical spine, the second group of electrodes is located along the longitudinal axis of the external therapeutic element along its entire length, and the third group of electrodes is located in the central part of the external therapeutic element in the projection zone on it the thoracic spine parallel to the second group of electrodes located along the longitudinal axis of the external therapeutic element, external therapist the optical element is connected to the source of electrical impulses through the electrode switching unit, according to the first embodiment of the group of utility models, the external therapeutic element is additionally equipped with a fourth group of active and passive electrodes placed in pairs along its longitudinal axis along its entire length, the electrode switching unit is placed in the external therapeutic element moreover, the electrode switching unit comprises an electric pulse analyzer, a power regulator, a multiplexer, a control device, memory a program and a shaper of the feedback signal, while the source of electrical pulses is connected in series with the analyzer of electric pulses, a power regulator, and a multiplexer, the output-input of the multiplexer is connected to the electrodes of all groups of the external therapeutic element, the output of the multiplexer is connected to the input of the shaper of the feedback signal the device contains three inputs, two outputs and one output-input, and one input of the control device is connected to the analyzer of electrical impulses x, the second input of the control device is connected to the program memory, the third input of the control device is connected to the feedback driver, one output of the control device is connected to the power regulator, the second output of the control device is connected to the multiplexer, and the output-input of the control device is connected to the control panel.

In this case, the display unit of the control panel is made of liquid crystal, and the external therapeutic element is made in the form of a multi-electrode anatomical mat.

In the second embodiment, the claimed technical result is achieved by the fact that in the inventive device for percutaneous electroneurostimulation containing a source of electrical impulses, a control panel with an indication unit and an external therapeutic element, divided into anatomical zones and having a longitudinal axis, on which electrodes are made, made in the form of the convex surface of the active and passive coaxial contact plates and located symmetrically relative to the longitudinal axis of the external therapeutic e element, and one group of electrodes is located at the end of the external therapeutic element in the projection zone of the cervical spine, the second group of electrodes is located along the longitudinal axis of the external therapeutic element along its entire length, and the third group of electrodes is located in the central part of the external therapeutic element in the projection zone on it the thoracic spine parallel to the second group of electrodes located along the longitudinal axis of the external therapeutic element, external therapist the optical element is connected to the source of electrical impulses through the electrode switching unit, according to the second variant of the group of utility models, the external therapeutic element is additionally equipped with a fourth group of active and passive electrodes placed in pairs along its longitudinal axis along its entire length, the electrical pulse source and the electrode switching unit are placed in an external therapeutic element, wherein the electrode switching unit comprises a multiplexer, a control device, program memory and the feedback signal, while the output of the source of electrical pulses is connected to the input of the multiplexer, the output-input of the multiplexer is connected to the electrodes of all groups of the external therapeutic element, the output of the multiplexer is connected to the input of the driver of the feedback signal, while the control device contains two inputs, two outputs, and one output-input, with one input of the control device connected to the program memory, the second input of the control device connected to the driver of the feedback signal, one output The control unit is connected to a source of electrical pulses, the second output of the control device is connected to a multiplexer and the output of input control device is connected to the control unit.

In this case, the display unit of the control panel is made of liquid crystal, and the external therapeutic element is made in the form of a multi-electrode anatomical mat.

In both the first and second versions of the group of claimed utility models, the supply of an external therapeutic element with an additional fourth group of active and passive electrodes placed pairwise on its longitudinal axis along its entire length, in combination with electrodes of the first, second and third groups and the possibility of changing power and frequency of electrical pulses in accordance with the feedback signal received from the patient, which is achieved by using a feedback shaper that interacts with other elements s of the inventive flowchart allows efficient electroneurostimulation all areas of biological man.

According to the first option, the placement of the electrode switching unit in the external therapeutic element, which allows to refuse to use an external multicore cable to connect the electrode switching unit to the external therapeutic element, and the presence of an electric pulse analyzer, power regulator, multiplexer, control device, program memory in the electrode switching unit and a feedback driver, while the source of electrical pulses is connected in series with the analyzer m of electrical pulses, a power regulator and a multiplexer, the multiplexer output-input is connected to the electrodes of all groups of the external therapeutic element, the multiplexer output is connected to the input of the feedback shaper, while the control device contains three inputs, two outputs and one output-input, and one the input of the control device is connected to the analyzer of electrical pulses, the second input of the control device is connected to the program memory, the third input of the control device is connected to the driver with feedback, one output of the control device is connected to the power regulator, the second output of the control device is connected to the multiplexer, and the output-input of the control device is connected to the control panel, allows you to provide the function of choosing one of the possible options for the program of exposure, transmission of electrical impulses with given characteristics in in accordance with this program of exposure from the source of electrical impulses to the electrodes of all groups of the external therapeutic element, and the function after ovatelnogo changes in power and frequency of electrical pulses, including smooth, or fixed step change input to the electrodes in accordance with the exposure program electroneurostimulation increases efficiency and makes it easy and secure.

According to the second option, the placement of the source of electrical pulses and the switching unit of the electrodes in the external therapeutic element, which allows you to abandon the use of an external multicore cable to connect the electrode switching unit to the external therapeutic element, and the presence of a multiplexer, a control device, program memory and a signal conditioner in the electrode switching unit feedback, despite the fact that the output of the source of electrical pulses is connected to the input of the multiplexer, the output is the input of the multiplex the xor is connected to the electrodes of all groups of the external therapeutic element, the output of the multiplexer is connected to the input of the feedback driver, and the control device contains two inputs, two outputs and one output-input, with one input of the control device connected to the program memory, the second input of the control device connected with a feedback driver, one output of the control device is connected to a source of electrical pulses, the second output of the control device is connected to a multiplexer, and the output one input of the control device is connected to the control panel, it provides the function of selecting one of the possible options for the exposure program, the transmission of electrical impulses with the characteristics in accordance with this program of exposure from the source of electrical impulses to the electrodes of all groups of the external therapeutic element, and the function of sequential change of power and frequency of electrical pulses, including smooth, fixed or step change, arriving at the electrodes in accordance program impact increases electroneurostimulation efficiency and makes it easy to operate and safe.

In addition, the inventive device according to the first and second option allows the process of electroneurostimulation to monitor the dynamics of changes in the characteristics of the patient’s skin surface, take these characteristics into account and adjust the power and frequency of electrical impulses when they are applied to the electrodes of all groups of the external therapeutic element in accordance with the feedback signal coming from the patient, which also increases the effectiveness of electroneurostimulation and makes it easy to operate and safe.

The possibility of using a multi-electrode anatomical mat as an external therapeutic element allows for close contact of the electrodes with the human body in the supine position, which does not require special fixing of the electrodes on the human body and their rearrangement during exposure, which, in turn, simplifies the operation of the device and makes the electroneurostimulation procedure comfortable and safe.

The inventive group of utility models (options) forms a single creative concept, as it relates to objects of the same type, of the same purpose and ensures the receipt of the same technical result.

No technical solutions matching the totality of essential features of the utility model have been identified, which allows us to conclude that the utility model meets the patentability criterion of “novelty”.

The patentability condition “industrial applicability” is confirmed by examples of a specific embodiment of a device for percutaneous electroneurostimulation with respect to each variant of the claimed group of utility models.

Figure 1 presents a General view of a device for percutaneous electroneurostimulation in a perspective view (first option);

Figure 2 presents a block diagram of a device for percutaneous electroneurostimulation (first option);

Figure 3 presents a General view of a device for percutaneous electroneurostimulation in axonometry (second option);

Figure 4 presents a block diagram of a device for percutaneous electroneurostimulation (second option).

The device for percutaneous electroneurostimulation, according to the first embodiment (see Fig. 1), contains an electric pulse source 1, a control panel 2 with an indication unit 3 and an external therapeutic element 4 divided into anatomical zones (projection zone of the cervical spine, thoracic projection zone spine, projection area of the spine) and having a longitudinal axis 5.

Four groups of electrodes 6, 7, 8 and 9 are installed on the external therapeutic element 4 in the corresponding anatomical zones, made in the form of active and passive coaxial contact plates having a convex surface and located symmetrically relative to the longitudinal axis 5 of the external therapeutic element 4.

The first group of electrodes 6 is located at the end of the external therapeutic element 4 in the zone of projection of the cervical spine onto it.

The second group of electrodes 7 is located along the longitudinal axis 5 of the external therapeutic element 4 along its entire length.

The third group of electrodes 8 is located in the central part of the external therapeutic element 4 in the area of projection onto it of the thoracic spine parallel to the second group of electrodes 7.

The fourth group of electrodes 9 is placed in pairs on the longitudinal axis 5 of the external therapeutic element 4 along its entire length.

The external therapeutic element 4 is connected to a source of electrical impulses 1 through an electrode switching unit 10.

The electrode switching unit 10 is located in the external therapeutic element 4 in the projection zone of the cervical spine.

The electrode switching unit 10 (see Fig. 2) contains an electric pulse analyzer 11, a power regulator 12, a multiplexer 13, a control device 14, program memory 15 and a feedback signal generator 16.

The source of electrical pulses 1 is connected in series with the analyzer of electrical pulses 11, a power regulator 12 and a multiplexer 13.

The output-input of the multiplexer 13 is connected to the electrode group 17, which includes the electrodes of the first 6, second 7, third 8 and fourth group 9.

The output of the multiplexer 13 is connected to the input of the shaper feedback signal 16.

The control device 14 contains three inputs, two outputs and one output-input.

One input of the control device 14 is connected to the electric pulse analyzer 11, the second input of the control device 14 is connected to the program memory 15, the third input of the control device 14 is connected to the feedback driver 16.

One output of the control device 14 is connected to the power controller 12, the second output of the control device 14 is connected to the multiplexer 13, and the output-input of the control device 14 is connected to the control panel 2.

The display unit 3 of the control panel 2 is made of liquid crystal, and the external therapeutic element 4 is made in the form of a multi-electrode anatomical mat.

The device for percutaneous electroneurostimulation according to the second embodiment (see Fig. 3), contains an electric pulse source 1, a control panel 2 with an indication unit 3 and an external therapeutic element 4, divided into anatomical zones (projection zone of the cervical spine, projection zone of the thoracic spine , projection area of the spine) and having a longitudinal axis 5.

Four groups of electrodes 6, 7, 8 and 9 are installed on the external therapeutic element 4 in the corresponding anatomical zones, made in the form of active and passive coaxial contact plates having a convex surface and located symmetrically relative to the longitudinal axis 5 of the external therapeutic element 4.

The first group of electrodes 6 is located at the end of the external therapeutic element 4 in the zone of projection of the cervical spine onto it.

The second group of electrodes 7 is located along the longitudinal axis 5 of the external therapeutic element 4 along its entire length.

The third group of electrodes 8 is located in the central part of the external therapeutic element 4 in the area of projection onto it of the thoracic spine parallel to the second group of electrodes 7.

The fourth group of electrodes 9 is placed in pairs on the longitudinal axis 5 of the external therapeutic element 4 along its entire length.

The external therapeutic element 4 is connected to a source of electrical impulses 1 through an electrode switching unit 10.

The source of electrical pulses 1 and the switching unit of the electrodes 10 are located in the external therapeutic element 4 in the projection zone of the cervical spine.

The electrode switching unit 10 (see Fig. 4) contains a multiplexer 13, a control device 14, a program memory 15 and a feedback driver 16.

The output of the source of electrical pulses 1 is connected to the input of the multiplexer 13.

The output-input of the multiplexer 13 is connected to the electrode group 17, which includes the electrodes of the first 6, second 7, third 8 and fourth group 9.

The output of the multiplexer 13 is connected to the input of the shaper feedback signal 16.

The control device 14 contains two inputs, two outputs and one output-input.

One input of the control device 14 is connected to the program memory 15, the second input of the control device 14 is connected to the driver of the feedback signal 16.

One output of the control device 14 is connected to the source of electrical pulses 1, the second output of the control device 14 is connected to the multiplexer 13, and the output-input of the control device 14 is connected to the control panel 2.

The display unit 3 of the control panel 2 is made of liquid crystal, and the external therapeutic element 4 is made in the form of a multi-electrode anatomical mat.

The device for ease of operation and storage is equipped with two technological holes 18 located on the sides of the external therapeutic element 4 symmetrically relative to each other, and a loop 19 located at its end.

Device for percutaneous electroneurostimulation works as follows.

Both in the first and in the second variant, before the procedure of electroneurostimulation, the external therapeutic element 4, made in the form of a multi-electrode anatomical mat, and the electrodes of the first, 6, second 7, third 8 and fourth 9 groups are treated with a disinfectant.

The procedure is performed in the supine position with the natural position of the spine.

The external therapeutic element 4 in the form of a multi-electrode anatomical mat is made of three layers: the lower one is a hard, rubber-like material (for example, hard bergaflex), the inner one is made of soft porous material (for example, foam rubber), and the upper one is made of soft rubber-like material (for example, silicone )

In the projection zone of the cervical spine, the external therapeutic element 4 is made taking into account the anatomical structure of the human neck.

The electrodes of the first 6, second 7, third 8 and fourth 9 groups are made of stainless steel and are installed with different heights and at different angles to the surface of the external therapeutic element 4 in accordance with the anatomical features of the structure of the spine and back of a person.

The electrodes of the first 6, second 7 and third 8 groups are made oval.

The electrodes of the fourth 9 groups are rectangular.

According to the first embodiment, electric stimulators are used as a source of electrical impulses 1, for example, Diadens-T, Diadens-DT, Diadens-PK, Diadens-PKM.

The source of electrical pulses 1 generates electrical pulses with a frequency in the range of 140 Hz ± 5 Hz with a duration of the first phase of the electrical pulse in the range from 300 μs to 530 μs.

Electrical pulses from the source of electrical pulses 1 are fed to the input of the analyzer of electrical pulses 12, in which the compliance of the main parameters (power, frequency) of electrical pulses with the required values is monitored.

If the parameters of the electrical pulses do not meet the required values, the corresponding signal is supplied to the control device 14, where a message is generated for the user, which is displayed on the liquid crystal display unit 3 of the control panel 2.

If the parameters of the electrical pulses correspond to the required values, the device for percutaneous electroneurostimulation switches to the main mode of electroneurostimulation, which is determined by the user by selecting the exposure program and the maximum level of the power value of the electrical pulses.

Electrical pulses from the output of the analyzer of electrical pulses 11 are fed to the input of the power controller 12, and the first input of the control device 14 receives an information signal about the parameters of the electrical pulses.

Through the second input of the control device 14 from the program memory 15 is read the impact program.

From the first output of the control device 14 to the input of the power regulator 13 receives a control signal, in accordance with which the power of the electrical pulses is changed in accordance with the exposure program.

From the output of the power regulator 12, electrical pulses are fed to the input of the multiplexer 13 with a power that varies in accordance with the exposure program.

From the second output of the control device 14 to the input of the multiplexer 13 receives a control signal, in accordance with which the frequency of the electrical pulses is changed by skipping individual electrical pulses.

From the output of the multiplexer 13, electrical pulses with power and frequency in accordance with the exposure program are supplied to the selected electrodes of the first 6, second 7, third 8 and fourth 9 groups of the external therapeutic element 4 in accordance with the exposure program.

During electrical neurostimulation, electrical pulses from the source of electrical pulses 1 through the multiplexer 13 are fed in parallel to the electrode group 17 of the external therapeutic element 4 and to the feedback shaper 16.

In this case, the parameters of the electric pulse coming from the multiplexer 13 to the electrode group 17 are changed in accordance with the characteristics of the skin surface of the patient, which serves as information for the feedback shaper 16.

The feedback signal generator 16 provides control over the dynamics of changes in the characteristics of the skin surface, which allows for exposure as long as there is a change in the characteristics of the skin surface, as well as load control. In the absence of load, electroneurostimulation stops.

According to the second option, the parameters of the electrical pulses are independent of the source of electrical pulses 1, which extends the frequency range of electrical pulses from 0.1 Hz to 200 Hz, which is set by the control device 14 in accordance with the exposure program.

The device for percutaneous electroneurostimulation goes into the main mode of electroneurostimulation, which is determined by the user by selecting the exposure program and the maximum power level using the keyboard on the control panel 2.

Through the first input of the control device 14 from the program memory 15 is read the impact program.

The control signal is supplied from the first output of the control device 14 to the input of the source of electrical pulses 1, in which there is a change in the power and frequency of electrical pulses in accordance with the control signal.

Electrical pulses from the output of the source of electrical pulses 1 are fed to the input of the multiplexer 13.

From the output of the multiplexer 13, electrical pulses with power and frequency in accordance with the control signal are supplied to the electrode group 17 of the remote therapeutic element 4.

During electrical neurostimulation, electrical pulses from the source of electrical pulses 1 through the multiplexer 13 are fed in parallel to the electrode group 17 of the external therapeutic element 4 and to the feedback shaper 16.

In this case, the parameters of the electric pulse coming from the multiplexer 13 to the electrode group 17 are changed in accordance with the characteristics of the skin surface of the patient, which serves as information for the feedback shaper 16.

The feedback signal generator 16 provides control over the dynamics of changes in the characteristics of the skin surface, which allows for exposure as long as there is a change in the characteristics of the skin surface, as well as load control. In the absence of load, electroneurostimulation stops.

The control device 14 according to the first and second embodiment can be performed on the basis of a microprocessor.

During electroneurostimulation, according to the first and second options, the power of individual electrical pulses, their frequency, exposure time and electrode groups selected for electroneurostimulation in accordance with the exposure program are changed.

During the operation of the device for percutaneous electroneurostimulation, according to the first and second embodiment, the patient can independently change the magnitude of the electric pulse power in accordance with the individual sensitivity of the body.

Both in the first and in the second embodiment, the inventive device for percutaneous electroneurostimulation provides an increase in the efficiency of electroneurostimulation by changing the power and frequency of electrical pulses in accordance with the feedback signal from the patient, as well as increasing ease of use and safety.

Claims (6)

1. Device for percutaneous electroneurostimulation, containing a source of electrical impulses, a control panel with an indication unit and an external therapeutic element, divided into anatomical zones and having a longitudinal axis, on which electrodes are mounted, made in the form of active and passive coaxial contact plates having a convex surface and located symmetrically relative to the longitudinal axis of the remote therapeutic element, with one group of electrodes located at the end of the remote therapeutic element about the element in the zone of projection of the cervical spine onto it, the second group of electrodes is located along the longitudinal axis of the external therapeutic element along its entire length, and the third group of electrodes is located in the central part of the external therapeutic element in the zone of projection of the thoracic spine on it parallel to the second group of electrodes, located along the longitudinal axis of the remote therapeutic element, the external therapeutic element is connected to the source of electrical impulses through the switching unit and electrodes, characterized in that the external therapeutic element is additionally equipped with a fourth group of active and passive electrodes placed pairwise on its longitudinal axis along its entire length, the electrode switching unit is placed in the external therapeutic element, the electrode switching unit comprising an electric pulse analyzer, a power regulator , a multiplexer, a control device, program memory and a shaper of the feedback signal, while the source of electrical pulses is connected in series with an analyzer of electrical impulses, a power regulator and a multiplexer, the output-input of the multiplexer is connected to the electrodes of all groups of the external therapeutic element, the output of the multiplexer is connected to the input of the feedback shaper, while the control device contains three inputs, two outputs and one output-input, one input of the control device is connected to the analyzer of electrical pulses, the second input of the control device is connected to the program memory, the third input of the control device is connected a feedback signal generator, one output control device coupled with a power regulator, the second output of the control device is connected to a multiplexer and the output of input control device is connected to the control unit. 2. The device for percutaneous electroneurostimulation according to claim 1, characterized in that the display unit of the control panel is made of liquid crystal. 3. The device for percutaneous electroneurostimulation according to claim 1, characterized in that the external therapeutic element is made in the form of a multi-electrode anatomical mat. 4. Device for percutaneous electroneurostimulation, containing a source of electrical impulses, a control panel with an indication unit and an external therapeutic element, divided into anatomical zones and having a longitudinal axis, on which electrodes are mounted, made in the form of active and passive coaxial contact plates having a convex surface and located symmetrically relative to the longitudinal axis of the remote therapeutic element, with one group of electrodes located at the end of the remote therapeutic element about the element in the zone of projection of the cervical spine onto it, the second group of electrodes is located along the longitudinal axis of the external therapeutic element along its entire length, and the third group of electrodes is located in the central part of the external therapeutic element in the zone of projection of the thoracic spine on it parallel to the second group of electrodes, located along the longitudinal axis of the remote therapeutic element, the external therapeutic element is connected to the source of electrical impulses through the switching unit and electrodes, characterized in that the external therapeutic element is additionally equipped with a fourth group of active and passive electrodes placed in pairs on its longitudinal axis along its entire length, the source of electrical pulses and the electrode switching unit are placed in the external therapeutic element, the electrode switching unit comprising a multiplexer, a control device, program memory and a shaper of the feedback signal, while the output of the source of electrical pulses is connected to the input of the multiplexer, the output the d-input of the multiplexer is connected to the electrodes of all groups of the external therapeutic element, the output of the multiplexer is connected to the input of the feedback shaper, while the control device contains two inputs, two outputs and one output-input, and one input of the control device is connected to the program memory, the second the input of the control device is connected to the feedback driver, one output of the control device is connected to a source of electrical pulses, the second output of the control device is connected with a multiplexer, and the output-input of the control device is connected to the control panel. 5. The device for percutaneous electroneurostimulation according to claim 4, characterized in that the display unit of the control panel is made of liquid crystal. 6. The device for percutaneous electroneurostimulation according to claim 1, characterized in that the external therapeutic element is made in the form of a multi-electrode anatomical mat.