RU2336104C1 - Electroneuroadaptive stimulator (versions), electrode assembly and electrode module - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: electroneuroadaptive stimulator contains power supply, electrode assembly, start pulse shaping unit including master microcontroller in the first version and connected display and control panel. Electrode assembly consists of electrode modules, one of which is demountable connected through serial two-wire command and data interface unit and address bus to master microcontroller and through two power buses to power supply, and other electrode modules are demountable integrated in 2D array. Demountable connection between electrode modules includes two-wire command and data interface unit, address bus and two power buses, and each electrode module contains key cascade with the two-section inductance coil. In the second version electroneuroadaptive stimulator in addition contains the second power supply, the second microcontroller and radio channel containing the first and second transceivers with first and second scanners, connected between two-wire interface units of the first and second microcontrollers. The electrode assembly contains number of electrode modules demountable connected in 2D array. Each electrode module contains microcontroller, key cascade with two-section inductance coil and two electronic key outputs of which are integrated and connected to electrode.

EFFECT: lowered effect of electrodes on electrostimulating signal parameters and possibility of any configuration of electrode assembly affecting any body region.

5 cl, 5 dwg

Description

The invention relates to medical equipment, namely to electrical stimulants, and can be used for general regulatory healing effect on the physiological systems of the human body.

From the description of the patent of the Russian Federation No. 2017508, IPC5 A61N 1/36, publ. 1994, an electric stimulator is known that contains N pairs of electrodes connected to the corresponding inputs of the switching unit, a synchronization unit, the first input of which is connected to an external source of sinusoidal modulated current, the second input to the first output of the control unit, the first output to the first input of the timer, the second output is 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 is to the first input of the program setting unit, and the fourth output is to the control input of the switching unit, output One of which is connected to the second input of the program unit, 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 unit, characterized in that a pseudo-random binary sequence generator and a polarity switch are inserted into it, the third output of the synchronization unit is connected to the input of the generator of a 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 lyuchatelya sync block, and an output connected to the input switching unit. The disadvantage of this electric stimulator is the inability to automatically dose electrical stimulation depending on the individual characteristics of the patient’s body, which not only reduces the effectiveness of the therapeutic effect, but can also lead to undesirable consequences. In addition, the fixation of the electrodes with elastic bandages due to non-comfort negatively affects the psychological state of the patient, which also reduces the effectiveness of the treatment.

From the description of the patent of the Russian Federation No. 2135226, IPC6 A61N 1/36, publ. In 1999, a neuro-adaptive electrical stimulator is known, which contains a block for generating active pulses, a block for generating modulation control signals, a block for analyzing adaptive processes, a controlled generator, N pairs of electrodes, a block for switching stimulation channels, a generator for the frequency of exposure to electrodes, and a channel code generator. In comparison with the previously described, such an electrical stimulator provides the possibility of individually dosed, determined by the group of selected zones and cyclic in time exposure to electric pulses on the skin of a person. The disadvantage of this electric stimulator is the impossibility of affecting the extended innervation zone.

From the description of the patent of the Russian Federation No. 2198695, IPC7 A61N 1/36, publ. 2003, an adaptive stimulator with a virtual electrode is known, which contains a block of rectangular pulses, a block of pulse train generation, a control block, an energy control unit, an output block, a feedback pulse analysis block, an individual norm memory block, a probe signal memory block, the first control the input of the adaptive electric stimulator with a virtual electrode is connected to the control input of the block of rectangular pulses, the installation input of which is connected to the first installation the input of the adaptive pacemaker with a virtual electrode, the signal output of the block of rectangular pulses is connected to the signal input of the block of formation of bursts of pulses and the first signal input of the control unit, the second, third and fourth installation inputs of the adaptive pacemaker with a virtual electrode are connected respectively to the first, second and third installation inputs unit of formation of bursts of pulses, the signal output of which is connected to the second signal input of the control unit, the second and third control The corresponding inputs of the adaptive electrical stimulator with a virtual electrode are connected respectively to the first and second control inputs of the control unit, the fifth and sixth installation inputs of the adaptive electrical stimulator with a virtual electrode are connected respectively to the first and second installation inputs of the control unit, the first signal output of which is connected to the signal input of the energy control unit action, the first and second control inputs of which are connected respectively to the fourth and fifth control the inputs of an adaptive electrical stimulator with a virtual electrode, the seventh and eighth installation inputs of which are connected respectively to the first and second installation inputs of the energy impact control unit, the signal output of which is connected to the signal input of the output unit, the first control input of which is connected to the sixth control input of the adaptive electric stimulator with a virtual an electrode, the ninth and tenth installation inputs of which are connected respectively to the first and second installation inputs and an output unit, the first signal output of which is connected to the third signal input of the control unit, the first control output of which is connected to the control input of the feedback pulse analysis unit, the first and second installation inputs of which are connected respectively to the eleventh and twelfth installation inputs of the adaptive electric stimulator with a virtual electrode, 2N inputs of the group of installation inputs of which are connected to 2N inputs of the group of installation inputs of the feedback pulse analysis unit, the signal the path of which is connected to the fourth signal input of the control unit, (N + 1) groups of the first information inputs of the feedback pulse analysis unit are connected respectively to the outputs (N + 1) of the groups of information outputs of the individual norm memory block, the inputs (N + 1) of the groups of second information the inputs of the feedback pulse analysis block are connected respectively to the outputs (N + 1) of the information output groups of the probe signal parameter recording block, the clock inputs of the individual norm memory block and the feedback pulse analysis block with monitors are combined with the clock output of the control unit, the second control output of which is connected to the control input of the individual norm memory unit, the third control output is connected to the control input of the probe parameter recording unit, the second signal output of the output unit is connected to the signal inputs of the individual norm memory unit and recording unit parameters of the probe signal, characterized in that it is additionally introduced a block of controlled electrodes and a block for setting a virtual electrode, the first signal the lane input of the block of controlled electrodes is connected to the second signal output of the block of control, and the second signal input of the block of controlled electrodes is connected to the second signal output of the block and signal inputs of the memory block of the probe signal and the memory block of the individual norm, the inputs of the first and second groups of control inputs of the block of controlled electrodes connected respectively to the outputs of the first and second groups of control outputs of the virtual electrode job unit. The disadvantage of an adaptive electrostimulator with a virtual electrode is that when exposed to extended zones of innervation, the areas under the passive electrodes are not affected, which reduces the efficiency of electrical stimulation and also makes it impossible to predict the number of electrical stimulation sessions.

As the closest technical solution (prototype) to the claimed electro-neuro-adaptive stimulator, an electro-neuro-adaptive stimulator, protected by paragraph 1 of the claims of the Russian Federation patent No. 2262957, IPC7 A61B 1/36, 1/04, publ. 2005. This electroneuroadaptive stimulator contains a direct current source, a triggering pulse generating unit, an electrode device, a two-section high-quality inductance coil, the sections of which are included according to, the connection point of the sections of a two-section high-quality inductance coil is connected to the first pole of the direct current source, the second end of the section with less turns through a key amplifier connected to the second pole of the DC source, the second end of the section with a large number of ohm of turns is connected to the feedback signal input of the triggering pulse generating unit and through N electronic controlled switching keys to the “active electrode” mode with N electrodes of the electrode device, the signal output of the triggering pulse generating unit is connected to the signal input of the key amplifier, and is characterized in that additionally contains N electronic controlled keys for switching to 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 generation and generation of triggering pulses, a control input with a control output of the control unit and generating triggering pulses, a 2N outputs with corresponding control inputs of N electronic controlled keys for switching on to the "active electrode" mode and N electronic controlled keys for switching on to the "passive electrode" mode, In this case, the electrodes of the electrode device are additionally connected to the first pole of the direct current source through additional electronic switches for switching to the “passive electrode” mode. The unit for generating triggering pulses in this electroneuroadaptive stimulator contains an operation mode setting unit including at least stimulus energy level control elements and a power-on element, an indication unit and a pulse analysis, control and formation 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 indications of the indication node are connected to the VLSI information outputs, the VLSI signal output is a signal output m of the trigger pulse generation block, the VLSI code output is the code output of the trigger pulse generation block, the VLSI control output is the control output of the control and trigger pulse generation block, the VLSI signal input is the feedback signal input of the trigger pulse generation block, and the VLSI has at least two modes works, in the first of which on the pulse output of the control unit there are a series of triggering pulses with a fixed number of pulses in the series, and on ovom output code sequence from 1 to N, where N - number of controllable electronic switches, changing the code which happens to each series of trigger pulses, while the second - the pulse output a continuous sequence or series of firing pulses, seven output - unmodifiable code. The disadvantage of the prototype is the change in the load impedance of the inductor when changing the number of electrodes included in the "active electrode" mode, which affects the parameters of the electrostimulating signal, the inability to adapt the electrode device to the configuration of the exposure zone, which leads to hardware redundancy, since each exposure zone requires your electrode device.

Common signs of the claimed electroneuroadaptive stimulator and prototype are:

- the presence of a power supply;

- the presence of a unit for generating triggering pulses, including an indicator device (in the prototype it is an indication unit), a control panel (in the prototype it is a unit for specifying operating modes), a control microcontroller (in the prototype it is an analysis, control and pulse generation unit made in the form of an ultra-large integrated circuit );

- the presence of a key stage with a two-section inductor (in the prototype it is a two-section inductor with a key amplifier);

- connection of the signal input of the key cascade with a two-section inductor with the output of the control microcontroller, and the output of the key cascade with the signal input of the control microcontroller;

- the presence of an electrode device.

The technical result achieved by using the inventive electro-adaptive stimulator is to reduce the influence of the number of electrodes included in the “active electrode” mode on the parameters of the electrostimulating signal and to enable arbitrary configuration of the electrode device with the possibility of affecting any local area of the body blocked by the electrode device.

The specified technical result in the first embodiment of the inventive electro-adaptive stimulator is achieved by the fact that in the electro-adaptive stimulator containing a power source, an electrode device, a trigger pulse generating unit including a control microcontroller and an indicator device and a control panel connected to it, the electrode device consists of electrode modules, one of which a detachable connection is connected by a serial two-wire interface for transmitting commands and information data and an addressing bus with a control microcontroller and two power buses with a power source, and other detachable connections are combined in a two-coordinate matrix, while the detachable connection between the electrode modules includes a two-wire interface for transmitting commands and information data, an addressing bus and two power buses, and each The electrode module contains a key stage with a two-section inductor.

The specified technical result in the second embodiment of the inventive electro-adaptive stimulator is achieved by the fact that the electro-adaptive stimulator containing a power source, an electrode device, a first microcontroller and an indicator device and a control panel connected thereto, further comprises a second power source, a second microcontroller and a radio channel including two transceivers with antenna devices connected between serial two-wire interfaces of the first and second microco trolleys, the electrode device consists of electrode modules, one of which is connected via a detachable serial interface with a two-wire command and information transmission interface and an addressing bus with a second microcontroller and two power buses with a power source, and the other by detachable connections are combined into a two-coordinate matrix, with a detachable connection between the electrode modules includes a two-wire interface for transmitting commands and information data, an addressing bus and two power buses, and each The electrode module contains a key stage with a two-section inductor.

The electrode device used in the inventive electro-adaptive stimulator is an independent object of protection as an invention.

From the description of the patent of the Russian Federation No. 2083236, IPC6 A61N 1/04, A61H 39/00, publ. 1997, an electrode device is known that is used in medical technology in combination with an electrostimulator for non-pharmacological treatment of a wide class of diencephalic disorders. It is a frame consisting of three electrically conductive elastic arcs interconnected by hinged elements, each of the arcs consists of two halves interconnected in the middle part by a dielectric element, one electrode is located on each of the halves, the ends of the electrically conductive elastic arcs made in the form of electrical contacts.

This electrode device is designed to relieve pain in diseases of the temporomandibular joint, i.e. is highly specialized.

The electrode device for electrical stimulation of the neuromuscular apparatus, protected by the patent of the Russian Federation No. 2124344, MPK6 A61H 39/00, A61B 5/05, publ. 1999, intended for restorative treatment in case of traumatic injuries in conditions of impaired innervation, contains a fixed electrode made in the form of an electrically conductive plate and a movable electrode. The movable electrode is made of two layers, with one layer made of elastic electrically conductive material, and the second layer of electrically insulating elastic material and equipped with fasteners to the palm of the operator. By attaching the electrode device to the operator’s hand, palpation control of the effectiveness of electrical stimulation is provided. The disadvantage of such an electrode device is that it is unsuitable for use with electro-adaptive stimulators due to the lack of fixing the distance between the passive and active electrodes.

As a prototype adopted an electrode device protected by paragraph 13 of the claims according to the patent of the Russian Federation No. 2262957, IPC7 A61B 1/36, 1/04, publ. 2005. This electrode device contains a connector for connecting an electro-adaptive stimulator, current-conducting conductors and electrodes, as well as an elastic substrate with contact slots attached to it for connecting electrodes, each contact of a connector for connecting an electro-adaptive stimulator, a current-conducting conductor is connected to a corresponding contact socket, and electrodes and contact slots for connecting them are located on the reverse sides of the elastic substrate. The use of such an electrode device requires the presence of a connector on the electro-neuroadaptive stimulator with the number of contacts equal to the number of electrodes, which limits the possibility of miniaturization of the electro-neuroadaptive stimulator and adaptation of the electrode device to the configuration of the body portion selected for electro-stimulating effect.

The technical result achieved by using the inventive electrode device is to reduce the influence of the number of electrodes included in the "active electrode" mode on the parameters of the electrostimulating signal and ensuring that the configuration of the electrode device is adapted to the configuration of the body portion selected for the electrostimulating effect.

The specified technical result is achieved in that in an electrode device containing several electrodes for electro-stimulating effect, each electrode is placed on an electrode module containing a microcontroller, a key stage with a two-section inductor, the input of which is connected to the output of the microcontroller, and two electronic keys, the control inputs of which connected to the outputs of the microcontroller, the signal input of the first electronic key is connected to the output of the key stage with a two-section inductor coil of activity and through the damping element with the signal output of the microcontroller, the signal input of the second electronic key is connected to the zero bus of the electrode module, the outputs of the electrode keys are combined and connected to the electrode located on the electrode module, while the electrode modules are combined in a two-coordinate matrix and adjacent modules are connected to each other another detachable connection, including a two-wire interface for transmitting commands and information data, an addressing bus and two power buses.

The electrode module for the inventive electrode device is an independent invention.

The inventive electrode module comprising an electrode mounted on a substrate further comprises a microcontroller, a key stage with a two-section inductor, an input of which is connected to the output of the microcontroller, two electronic keys, a signal input of the first electronic key connected to the output of the key stage with a two-section inductor and through a damping element with the signal input of the microcontroller, the signal input of the second electronic key is connected to the housing of the microcontroller, control inputs The first and second electronic keys are connected to the microcontroller, and the outputs are combined and connected to the electrode, and four orthogonally located relative to the center of the substrate, connectors, each of which has two elements for connecting to the two-wire interface for transmitting information data commands, one element for connecting to the bus addressing and two elements for connecting to power buses, while elements for connecting to a two-wire interface for transmitting commands and information data are connected to each other and the input m of the microcontroller, the elements for connecting to the addressing bus are connected each to a separate input of the microcontroller, the elements for connecting to the power buses are connected to each other and the corresponding power terminals of the microcontroller and the key stage with a two-section inductor, the key stage with a two-section inductor contains a two-section inductor, sections of which are included according to, the connection point of the sections of a two-section high-quality inductor is connected to the first field som of the power source, the second end of the section with fewer turns through the key amplifier, including, for example, a semiconductor triode and a damping diode, is connected to the second pole of the power source, the second end of the section with more turns through the damping element is connected to the input of the microcontroller, the input of the key amplifier connected to the output of the microcontroller.

According to the authors, the proposed technical solutions meet the patentability criterion of “novelty”, as the patent studies showed the absence of sources of information from which technical solutions with the claimed sets of essential features would be known. The claimed technical solutions meet the patentability criterion of "inventive step", since technical solutions are not known, including the distinguishing features of the independent claims. The materials of this application contain enough information to implement the claimed technical solutions, therefore, the claimed technical solutions meet the patentability criterion of "industrial applicability".

The invention is illustrated by drawings. Figure 1 shows a block diagram of a first embodiment of the inventive electro-adaptive stimulator, figure 2 - block diagram of a second variant of the inventive electron-adaptive stimulator, figure 3 is a structural diagram of an electrode device, figure 4 is a functional diagram of an electrode module, figure 5 an example of the implementation of the electrode module of the key stage with a two-section inductance coil and electronic keys on microelectronic relays is given.

In figure 1 ... 4 in numbers and letters denote:

1 - control microcontroller;

2 - power source;

3 - indicator device;

4 - control panel;

5 - electrode device;

6 - detachable connection;

7 - the second microcontroller;

8 - a second power source;

9 - the first transceiver;

10 - the first antenna device;

11 - a second antenna device;

12 - second transceiver;

13 - electrode module;

14 - microcontroller of the electrode module;

15 - the first electronic key;

16 - second electronic key;

17 - electrode;

18 is a key stage with a two-section inductor;

19 is a key cascade.

AP - hardware device;

A - addressing bus;

P / I - two-wire interface for transmitting commands and information data;

C / V - bus signal exposure;

“U”, “0” - power buses.

The electron-adaptive stimulator, the first option (Fig. 1), contains a control microcontroller 1, a power source 2, an indicator device 3, a control panel 4 and an electrode device 5 connected to a hardware device of the electron-adaptive stimulator with a detachable connection 6, including a two-wire P / I interface for transmitting commands and information data, the addressing bus A, the signal C / V bus and two power buses “U” and “0”. The concept of a hardware device (AP) includes all the structural elements of an electro-adaptive stimulator, excluding the electrode device 5 and the plug-in connection 6. The control microcontroller 1 is connected to the indicator port 3 by the first port, the signal output from the plug-in connection signal C / V bus 6, and the second port with control panel output 4, a serial port with a two-wire P / I interface for transmitting commands and information data of a plug-in connection 6 and a serial port with a bus address A connection 6. Power supply 2 is connected to the power circuits of the control microcontroller 1, indicator device 3, control panel 4 and to the power buses “U” and “0” of the plug-in connection 6. Indicator device 3 includes at least a graphic display, for example, on OLED organic light emitting diodes and is intended to display the settings menu of an electro-neuroadaptive stimulator, exposure modes, results of medical procedures, the body's response to exposure, the state of the power source, and also a reference x data comprising a list of entities that the list of diseases for each nosological entity, a set of drawings indicating the area for exposure and configuration of the electrode device. The indicator device 3 may contain light indicators that provide additional control of the processes of exposure, and an audio indicator to control the processes of exposure to poorly visible. The control panel 4 is designed to select the operating mode through the menu and control the energy level in manual mode and can be implemented using, for example, multifunctional touch controls. Operation is controlled through the control microcontroller 1. Built-in online help with explanatory drawings allows you to quickly and accurately determine the necessary zones for exposure. The operating system allows you to simultaneously carry out the treatment procedure and view online help. The software of the control microcontroller 1 allows you to automatically control stimulation during prolonged exposure and implement all exposure modes. The timer for the impact on the zone, the timer for the entire procedure, and the timer for the device’s resource are also implemented in software. The control panel 4 provides control of the operation of the electro-adaptive stimulator through the menu displayed on the display of the indicator device 3. The menu includes general and typical observations and explanations that help novice users to understand the display symbols of the indicator device 3 and learn how to work with it, conduct a preliminary analysis of the treated area, determine the exposure time, choose the optimal energy level of the acting signal, control the duration of treatment procedures, adjust ivat menu language, etc.

The second variant of the inventive electro-adaptive stimulator (Fig. 2) contains a first power supply 2, a first (control) microcontroller 1, an indicator device 3 and a control panel 4, an electrode device 5, a detachable connection 6, a second microcontroller 7, a second source connected to the first microcontroller 1 power supply 8 and a radio channel including a first transceiver 9, a first antenna device 10, a second antenna device 11, and a second transceiver 12. A radio channel is connected between the ports of the two-wire P / I interface sending commands and information data of the first microcontroller 1 and the second microcontroller 7. The electrode device 5 is connected via a plug-in connection 6 with a two-wire P / I interface for transmitting commands and information data to the first serial port of the second microcontroller 7, the addressing bus A with the second serial port of the second microcontroller 7, bus C / V signal of influence with the signal output of the second microcontroller 7 and buses "U" and "0" with the first power supply 2. The first power supply 2 is connected to the circuits pi the second microcontroller 7 and the second transceiver 12. The second power source 8 is connected to the power supply circuits of the control microcontroller 1, indicator device 3, control panel 4 and the first transceiver 9. The purposes of the first (control) microcontroller 1, indicator device 3 and control panel 4 are the same , as well as the first version of the electron-adaptive stimulator. The radio channel, including transceivers 9 and 12 with antenna devices 10 and 11, provides the exchange of commands and information data between microcontrollers 1 and 7.

The claimed variants of the electro-adaptive stimulator are a means of implementing modern technology of highly effective non-drug recovery of human health, called "SCENAR" - self-controlled electro-adaptive regulation. A characteristic feature of the operation of the electroneurostimulator is that the stimulating effect is carried out by electrical vibrations arising in the resonant circuit formed by the inductance of the || section with a large number of turns of a two-section inductor L (Fig. 5) and the capacitive component of the interelectrode tissue impedance between the active (connected to section “||”) and passive (connected to the zero bus) electrodes, while the stimulus energy is set by the duration of the control signal that unlocks the key second stage 19 - saturation time of the electromagnetic energy of the inductor L by passing current through this section of the «|» with fewer turns. The active component of the interelectrode tissue impedance affects the quality factor of the circuit and affects the rate of damping of oscillations in the resonant circuit. The capacitive component of the impedance that changes during electrical stimulation affects the frequency of these oscillations. The rate of change of the capacitive component of the impedance reflects the body's response to the electrostimulating effect. The rate of change of the capacitive component is calculated in the microcontroller 14 by the change in the duration of the first half-wave of oscillations of the electrostimulating signal at the output of the key stage 19. Zero impedance change rate indicates the absence of an organism reaction and the need for electrostimulation to end. Electro-adaptive stimulants are designed to prevent diseases and increase the reserve capacity of the body. Provide resistance to diseases and harmful environmental influences. The impact is carried out by short-pulse signals upon contact of the electrodes 17 with the skin. The parameters of the exposure signal and the duration of the procedure are set automatically.

When the electrodes of the electrode device 5 are in contact, the electro-neuroadaptive stimulator automatically switches to the exposure mode that is most suitable for the body at the moment (the electrodes connected to the C / B bus and the electrodes connected to the 0 bus are automatically selected, the energy level of the acting signal is automatically set determined by the pulse duration at the input of the key stage 19 and its quantity). This is very convenient when urgent care is required - for pain, bleeding, edema, shock conditions, heart attacks, etc. Then the mode can be changed. At the command of the microcontroller 1, under the control of a program stored in its memory, a menu is displayed on the display of the indicator device 3. Using the control panel 4, the patient or doctor, using the menu operands, finds the zone for exposure according to the express analysis, determines the priorities of the areas of the exposure zone, among the areas with the highest priority, finds the area with the highest degree of activity, selects the exposure mode and starts the electrical stimulation procedure. The display of the indicator device 3 in graphical and digital form displays the main operating modes, exposure energy, condition of the exposure zone, its activity during the procedure and the degree of change, the exact progress of the exposure dose, the exposure time for a separate area and the total time of the procedure, as well as the status power source 2. This allows you to evaluate the correct choice of the exposure zone, the full dose, the inclusion of dynamic adaptation and the reliability of contact with the skin. Electrical stimulation of the selected area of the exposure zone stops automatically as soon as the body stops responding to the effect and at the output of the key stage 19, the duration of the first half-wave ceases to change. The presence in the indicator device 3 of a graphic display allows the consumer to specify the diagnostic signs and select a mode of electrical stimulation close to optimal, to promptly and objectively monitor the treatment results.

The main blocks and nodes in the program of the microcontroller 1 for controlling an electron-adaptive stimulator, displayed on the display of the indicator device 3.

Biopassport block - allows you to automatically set up an electron-adaptive stimulator individually for the patient to whom the procedure is performed at the first touch. In addition, this is a great opportunity to get a high impact effect with self-help.

Dynamic adaptation block - allows you to control stimulation during long-term exposure, adjusting the effect and pauses between actions by feedback. It turns on automatically.

Block professional - specializes in tuning an electron-adaptive stimulator for professional use. During the procedures, the statistical information of the user's “work style” is recorded in the memory of microcontroller 1, remembering which zones are most often affected. There are 4 main areas of application of the electro-adaptive stimulator: the peripheral zone, the abdomen and chest in the front, the back and the face. Separate setting - to restore the health of children from 0 to 1-2 years. Based on this information, the internal functions of the electroneuroadaptive stimulator are adjusted.

Age Corrector - adjusts the initial setting of the electro-adaptive stimulator according to the "age qualification" - high-speed integrated response characteristics to exposure. Automatically provides dose adjustment in accordance with the age of the patient - a large dose for adults and a lower dose for children.

Module of quick help effect - forms an additional fast help package of impulses for impact in the area with expanded capillary network. It allows you to speed up the removal of puffiness and increase the rate of tissue regeneration. The module is activated at the same time as the electro-adaptive stimulator is turned on, when the electrodes come into contact with the skin, and it turns off automatically.

Corrector of aging - monitors and corrects the detuning of the control circuits and the effects of the electro-adaptive stimulator associated with the aging of radioelements, which allows to maintain its effectiveness in the process of long-term operation.

Reliability controller - provides short-term protection of the electro-adaptive stimulator from possible overloads, short circuits of electrodes, improper installation of batteries, etc.

The electrode device 5 (figure 3) contains several electrodes 17 for electrical stimulation. Each electrode 17 is placed on an electrode module 13 containing a microcontroller 14 and two electronic keys 15 and 16, the control inputs of which are connected to the outputs of the microcontroller 14, the signal input of the first electronic key 15 is connected through a damping element to the signal input of the microcontroller 14 and to the output of the key stage 19 with a two-section inductor, the signal input of which is connected to the output of the microcontroller 14, the signal input of the second electronic key 16 is connected to the connector element for connection to the bus "0" pita electrode module 13. Electrode modules 13 with detachable connections 6 are combined in a two-coordinate matrix, while neighboring modules 13 are connected with each other by detachable connection 6, including a two-wire P / I interface for transmitting commands and information data, addressing bus A, signal C / B bus exposure and two power buses "U" and "0", the outputs of the electrode keys 15 and 16 are combined and connected to the electrode 17 located on the electrode module 13.

The electrode module 13 (Fig. 4) contains an electrode 17 mounted on a substrate, a microcontroller 14, a key stage 19 with a two-section inductor and two electronic switches 15 and 16, the control inputs of which are connected to the microcontroller 14, and four orthogonally located relative to the center of the substrate, the connector , in each of which there are two elements for connecting to the two-wire P / I interface of transmitting information data commands, one element for connecting to the address relay bus A, one element for connecting the C / V bus influence and two elements for connecting to the buses “U” and “0” power supply, while elements for connecting to a two-wire interface P / And the transmission of commands and information data are connected to each other and the first port of the microcontroller 14, elements for connecting to bus A the addressing is connected each to a separate input of the microcontroller 14, the elements for connecting to the power bus "U" and "0" are connected to each other and the corresponding power terminals of the microcontroller 14 and the key stage 19, the signal input of the second electronic key 16 is connected en the bus "0" power.

An example implementation of the key stage 19 with a two-section inductor and electronic keys 15 and 16 on the PVT322A microelectronic relay is shown in FIG. When applying a control signal to the input of the electronic key 15, the electrode 17 is included in the "active electrode" mode. When applying a control signal to the input of the electronic key 16, the electrode 17 is included in the passive electrode mode. In the absence of control signals at the inputs of electronic keys 15 and 16, the electrode 17 is excluded from electrical stimulation.

The claimed electroneuroadaptive stimulators, in comparison with the known ones, are distinguished by the fact that the electrode device 5 consists of identical electrode modules 13 assembled into a two-coordinate matrix, which makes it possible to adapt the configuration of the electrode device 5 to the configuration of each of the exposure zones during one treatment session. 4, the addressing algorithm is viewed (assigning numbers to the electrode module 13 in the electrode device). The number of the electrode module 13 is indicated in parentheses. The electrode module 13, connected via a plug-in connection 6 to a hardware device (AP), is automatically assigned the number 00, then for each electrode module 13 connected along the “+ X” axis, the number is increased by one in the low order (0,1; 0, 2, etc.), connected along the "+ Y" axis increases by one in the high order (1.0; 2.0, etc.), when connected along the "-X" axis, the number decreases by one in the low digit (1, -1; 1, -2, etc.), when connected along the "-Y" axis, the number decreases by one in the highest digit (-1.0; -2.0, etc.). Such numbering is carried out as follows. The addressing bus A is connected to the single-bit bidirectional port of the microcontroller 14. In the initial state for all electrode modules, this port is in the receiving state. When 1 is set from the control microcontroller 1 on bus A, and a command is received via the two-wire P / I interface to receive the signal on bus A, the first electrode module 13 assigns itself 00 and then sends 1 in turn to the other three elements for connection to buses A. Each from the microcontrollers 14 of the adjacent electrode modules 13 receives the corresponding addresses. As soon as all the microcontrollers 14 have been addressed via the two-wire P / I interface, the addresses of all the involved electrode modules 13 are sent to the control microcontroller 1. Since the electronic modules are combined into a two-coordinate matrix, visualization of the constructed network of electrode modules on the display of the indicator device 3 is not difficult and automatically updated when changing the configuration of the electrode device.

Since each key stage 19 is connected to only one electrode 17 of the electrode device 5, a change in the number of electrodes 17 included in the “active electrode” mode does not affect the parameters of the electrostimulating signal.

The presence of a radio channel in the electron-adaptive stimulator in the second embodiment makes the work of the attending physician much easier, since it becomes possible to control the treatment procedure for several patients from one workstation with radio channel control. The radio channel can be implemented on the basis of Bluetooth or ZigBee modules.

As microcontrollers are used processors STR910FM32X6.

The power source can be implemented on two AAA elements.

Claims (5)

1. An electro-adaptive stimulator comprising a power source, an electrode device, a trigger pulse generating unit, including a control microcontroller and an indicator device and a control panel connected to it, characterized in that the electrode device consists of electrode modules, one of which is connected by a detachable connection to a serial two-wire interface transmitting commands and information data and an addressing bus with a control microcontroller and two power buses with a power supply and other detachable connections are combined in a two-coordinate matrix, while the detachable connection between the electrode modules includes a two-wire interface for transmitting commands and information data, an addressing bus and two power buses, and each electrode module contains a key stage with a two-section inductor. 2. An electro-adaptive stimulator comprising a power source, an electrode device, a first microcontroller and an indicator device and a control panel connected to it, characterized in that it further comprises a second power source, a second microcontroller and a radio channel including two transceivers with antenna devices connected between serial two-wire interfaces of the first and second microcontrollers, the electrode device consists of electrode modules, one of which is detachable connected by a serial two-wire interface for transmitting commands and information data and an addressing bus with a second microcontroller and two power buses with a power source, and other detachable connections are combined in a two-coordinate matrix, while the detachable connection between the electrode modules includes a two-wire interface for transmitting commands and information data, a bus addressing and two power buses, and each electrode module contains a key stage with a two-section inductor. 3. An electrode device containing several electrodes for electrical stimulation, characterized in that each electrode is placed on an electrode module containing a microcontroller, a key stage with a two-section inductor, the input of which is connected to the output of the microcontroller, and two electronic keys, the control inputs of which are connected to the outputs of the microcontroller, the signal input of the first electronic key is connected to the output of the key stage with a two-section inductor and through a damping an element with the signal output of the microcontroller, the signal input of the second electronic key is connected to the zero bus of the electrode module, the outputs of the electrode keys are combined and connected to the electrode located on the electrode module, while the electrode modules are combined in a two-coordinate matrix and adjacent modules are connected to each other by a detachable connection, including a two-wire interface for transmitting commands and information data, an addressing bus and two power buses. 4. An electrode module comprising an electrode fixed to a substrate, characterized in that it further comprises a microcontroller, a key stage with a two-section inductor, the input of which is connected to the output of the microcontroller, two electronic keys, the signal input of the first electronic key is connected to the output of the key stage with a two-section the inductor and through the damping element with the signal input of the microcontroller, the signal input of the second electronic key is connected to the zero bus microcontroller , the control inputs of the first and second electronic keys are connected to the microcontroller, and the outputs are combined and connected to the electrode, and four orthogonally located relative to the center of the connector substrate, each of which has two elements for connecting to the two-wire interface for transmitting information data commands, one element for connections to the addressing bus and two elements for connecting to power buses, while elements for connecting to a two-wire interface for transmitting commands and information data are connected pyr other and microcontroller input elements for connection to the bus addressing each connected to a separate input of the microcontroller, the elements for connection to the power supply buses connected to each other and the respective power supply terminals of the microcontroller and a key with a two-stage coil inductor. 5. The electrode module according to claim 4, characterized in that the key stage with a two-section inductor contains a two-section inductor, the sections of which are included according to, the connection point of the sections of the two-section high-quality inductor is connected to the first pole of the power source, the second end of the section with fewer turns through a key amplifier, including, for example, a semiconductor triode and a damping diode, connected to the second pole of the power source, the second end of the section with a large number of th turns through a damping element connected to the input of the microcontroller, a key input of the amplifier connected to the output of the microcontroller.

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