RU33006U1 - ELECTRONEUROADAPTIVE STIMULANT "COSMODIC" (OPTIONS) AND ELECTRODE DEVICE FOR ELECTRICAL STIMULATION (OPTIONS) - Google Patents

Abstract

1. An electro-adaptive stimulator designed primarily for rejuvenating the skin of the face and / or neck, containing a direct current source, a trigger pulse generating unit and an electrode device including passive and active electrodes, characterized in that it contains a two-section high-quality inductor and a demultiplexer, a signal input which are connected to the pulse output of the trigger generation block, and the control input with the code output of the trigger pulse generation block, the dyne from the poles of the direct current source is connected to the passive electrode of the electrode device and the connection point of the sections of a two-section high-quality inductor, the sections of which are connected according to, the second end of the section with a large number of turns is connected to the active electrode and the feedback signal input of the triggering pulse generating unit, section with a smaller the number of turns is made with taps, each tap of this section through a key amplifier is connected to the second pole of the DC source, input the control of each key amplifier is connected to the corresponding output of the demultiplexer. 2. The electron-adaptive stimulator according to claim 1, characterized in that the triggering 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 triggering pulse analysis, control and generation unit, made in form of an extra-large integrated circuit (VLSI), while the installation inputs of the VLSI are connected to the outputs of the node

Description

ELECTRONEUROADAPTIVE STIMULATOR “COSMODIC (OPTIONS) AND ELECTRODE DEVICE FOR ELECTRIC STIMULATION

Utility models relate to medicine and can be used in cosmetology and physiotherapy.

Known electrical stimulator containing a pulse generator, modulator, amplifier, indicator, electrodes, period generator, envelope shaper, multiplier, stimulus energy adjuster and differentiating element (see description of copyright certificate No. 1817335, IPC A61N 1/36, publ. 1995) . Depending on the quality of the transition process on

The output of the electric stimulator by the signal after the differentiating element controls the duration of the series of pulses set by the period generator, which allows dose exposure in accordance with the reaction of the body. The disadvantage of such an electric stimulator is low diagnostic abilities and the lack of the ability to choose parameters of stimulating pulses, which does not allow its use in cosmetology.

From the description of the patent of the Russian Federation JVo2068277, IPC A61N 1/36, A61H 39/00,

publ. 1996 the bioelectric regulator of psychosomatic homeostasis (electron-adaptive stimulator) is known, containing a rectangular pulse generator, a stimulating signal generating unit, a key amplifier with a transformer output, to which active and passive electrodes are connected, and a stimulating signal parameter setting unit connected to the stimulating signal generating unit and connected to the active electrode in series connected half-wave rectifier, b lock measuring the duration of the first half-wave of forced oscillations and an indication and control unit. The disadvantage of this electron-adaptive stimulator is the inability to change the frequency characteristics of the electrical oscillations of stimulating signals, which does not allow it to be used in cosmetology.

MPK7 A61H 39/00, A61N 1/36.

(OPTIONS).

This stimulator contains a block of rectangular pulses, a block of energy impact control, an output block, passive and active electrodes, a block of formation of bursts of pulses, a feedback block, an individual norm memory block, and a probe signal recording unit. The disadvantage of the prototype is the low efficiency of its use in cosmetology, since there is no possibility of forced changes in the parameters of the electrical vibrations of the acting signal, which does not provide the effect of rejuvenating the skin of the face and / or neck with its use.

The problem solved by the utility model is to increase the efficiency of the use of an electron-adaptive stimulator in cosmetology in order to achieve the effect of rejuvenating the skin of the face and / or neck.

The solution of this problem in the first embodiment is achieved by the fact that the electroneuroadaptive stimulator, intended primarily for rejuvenating the skin of the face and / or the face, containing a direct current source, a control unit for generating triggering pulses and an electrode device including coaxially placed passive and active electrodes, contains a two-section high-quality inductor and demultiplexer, the signal input of which is connected to the pulse output of the control unit and the formation of triggering them pulses, and the control input with the code output of this unit, one of the poles of the DC source is connected to the passive electrode of the electrode device and the connection point of the sections of the two-section high-quality inductor, the sections of which are connected according to, the second end of the section with a large number of turns is connected to the active electrode and the input feedback signal of the unit for generating triggering pulses, the section with fewer turns is made with taps, each tap of this section through the key amplifier under is connected to the second pole of the DC source, the signal input of each key amplifier is connected to the corresponding output of the demultiplexer. In an electron-adaptive stimulator, the control unit and the generation of triggering pulses contains a unit for setting operating modes, including at least elements of stimulus energy level control and a power-on element, an indication unit and an analysis, control and pulse generating unit made in the form of an ultra-large integrated circuit (VLSI), In this case, the VLSI installation input is connected to the output of the operation mode setting node, the inputs of the indication node are connected to the VLSI information outputs, the VLSI pulse output is

pulse output of the control unit and the formation of triggering pulses, the VLSI code output is the code output of the control unit and the formation of triggering pulses, the VLSI signal input is the input of the feedback signal of the control unit and the formation of triggering pulses, and the VLSI has at least two operating modes, in the first of which at the pulse output of the control unit there are a series of triggering pulses with a fixed number of pulses in the series, and at the code output a sequence of codes from 1 to p, where p - the number of key amplifiers, in which the code changes with each series of triggering pulses, and in the second - on the pulse output, a continuous sequence or sequence of series of triggering pulses, on the code output - an unchangeable code. The node for analysis, control and pulse generation, made in the form of an ultra-large integrated circuit (VLSI), contains a tactor generator of lean pulses, a trigger pulse generation circuit, a control signal generation circuit, and an analog-to-digital converter connected in series, a feedback signal parameter measurement circuit, a circuit measuring the rate of change of the parameters of the feedback signal, the allocation circuit of the feedback signal with the maximum rate of change of the parameters and the fixation circuit of the absence of changes parameters of the feedback signal, while the input of the analog-to-digital converter is the VLSI signal input, the output of the clock pulse generator is connected to the first input of the trigger pulse generation circuit, the first output of which is connected to the input of the control signal generation circuit, the second input of the trigger pulse generation circuit VLSI input, the second output of the triggering pulse formation circuit is the VLSI pulse output and is connected to the second input of the speed measurement circuit and change the parameters of the feedback signal, the output of the control signal generation circuit is a VLSI code output and is connected to the second input of the feedback signal extraction circuit with the maximum rate of change of parameters, the second output of the feedback signal parameter measurement circuit of the feedback signal is connected respectively to the second input of the no-change fixation circuit feedback signal parameters, the second output of the feedback signal allocation circuit with a maximum rate of change of parameters is connected with the second input of the control signal generation circuit, the third

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the input of which is connected to the first output of the feedback fixing circuit of the absence of changes in the parameters of the feedback signal, the second output of the feedback locking circuit of the absence of changes in the parameters of the feedback signal and the third outputs of the measurement circuit of the rate of change of the feedback signal parameters and the feedback signal extraction circuit with the maximum parameter change are VLSI information outputs . A high-quality inductor has an inductance of 0.1 ..- 2.0 GH, the ratio of the number of turns of the section with fewer turns to the total number of turns is 0.05 ... 0.3, the taps in the sections with fewer turns are made with a uniform pitch , and the quality factor of the inductor exceeds 100.

In the second embodiment, the solution of this problem is achieved by the fact that the electroneuroadaptive stimulator, intended primarily for rejuvenating the skin of the face and neck, contains a direct current source, a control unit and the formation of triggering pulses and an electrode device that includes coaxially placed passive and active electrodes, additionally contains several (two and more) active electrodes, a two-section high-quality inductor, sections of which are included according to, and a decoder, one of the poles of the DC current source is connected to the connection point of the sections of the two-section high-quality inductor and the passive electrode of the electrode device, the second end of the section with fewer turns through a key amplifier is connected to the second pole of the DC source, the second end of the section with more turns is connected to the input of the feedback signal of the unit control and formation of triggering pulses and through controlled electronic keys with each active electrode, the pulse output of the unit is controlled Generating and generating triggering pulses is connected to the input of the key amplifier, the code output of the control unit and generating triggering pulses is connected to the input of the decoder, the outputs of which are each connected to the control input of the corresponding controlled electronic key. Each controlled electronic key additionally contains an adjustment resistor in the load circuit. The control formation and triggering pulse generation unit contains an operation mode setting unit including at least stimulus energy level control elements and a power-on element, an indication unit and an impulse analysis, control and formation unit made in the form of an ultra-large integrated circuit (VLSI), VLSI input connected to the node output

M job modes, the inputs of the display unit are connected to the information outputs

VLSI, VLSI pulse output is the pulse output of the control unit and the formation of triggering pulses, VLSI code output is the code output of the control unit and the formation of triggering pulses, VLSI signal input is the feedback signal input of the control unit and the formation of triggering pulses, and 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 the code output the code sequence is from 1 to k, where k is the number of controlled electronic keys, in which the code changes with each series of triggering pulses, and in the second, a continuous sequence or sequence of series of triggering pulses at the pulse output, and an unchangeable code at the code output. The node for analysis, control and pulse generation, made in the form of an ultra-large integrated circuit (VLSI), contains a clock pulse generator, a trigger pulse generation circuit, a control signal generation circuit and an analog-to-digital converter connected in series, a feedback signal parameter measurement circuit, a speed measurement circuit changes in the parameters of the feedback signal, the allocation circuit of the feedback signal with a maximum rate of change of parameters and the fixation circuit for the absence of changes parameters of the feedback signal, while the input of the analog-to-digital converter is the VLSI signal input, the output of the clock pulse generator is connected to the first input of the trigger pulse generation circuit, the first output of which is connected to the input of the control signal generation circuit, the second input of the trigger pulse generation circuit VLSI input, the second output of the triggering pulse formation circuit is the VLSI pulse output and is connected to the second input of the speed measurement circuit and change the feedback signal parameters, the output of the control signal generation circuit is a VLSI code output and is connected to the second input of the feedback signal injection circuit with a maximum rate of change of parameters, the second output of the feedback signal parameter measurement circuit is connected to the second input of the no-change fixation circuit feedback signal parameters, the second output of the feedback signal allocation circuit with a maximum rate of change of parameters is connected on the second

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the input of the control signal generation circuit, the third input of which is connected to the first output of the feedback fixation circuit for no change in the parameters of the feedback signal, the second output of the feedback fixation circuit for no change in the parameters of the feedback signal and the third outputs of the circuit for measuring the rate of change of the feedback signal parameters and the feedback signal extraction circuit the maximum change in the parameters are VLSI information outputs. A high-quality inductor has an inductance of 0.1 2.0 H, the ratio of the number of turns of the section with fewer turns to the total number of turns is 0.05 ... 0.3, the taps in the sections with fewer turns are made with a uniform pitch, and the quality factor Inductors exceed 100.

The electrode device for electrical stimulation used in the inventive electroneuroadaptive stimulator is an independent security-capable object.

From the description of the USSR copyright certificate JVbl024061, IPC АВВ 5/05, publ. 1983

It is known an electrode device comprising a housing, the walls of which have a different degree of elasticity, and a contact element made in the form of a disk membrane with radial slots, and the peripheral section of the contact element is fixed in the housing. Such an electrode device is not suitable for the inventive electrical stimulator, as it does not provide

the necessary constancy of the reactive component of the sub-electrode resistance.

Copyright certificate of the USSR .№706062, IPC АВВ 5/02, publ. 1977 a device for diverting biopotentials is protected, comprising a housing with coaxially arranged electrodes that are separated by an insulating pad. The electrodes are made of dissimilar materials, and the housing on the side of the contact surface of the electrodes has a cavity filled with electrolyte. The disadvantage of such an electrode device is the instability of the reactive component of the interelectrode resistance due to the heterogeneity of the electrode materials and the presence of an electrolyte in the body cavity between the electrodes.

The closest to the claimed electrode device selected technical solution,

described in the description of the author's certificate of the USSR No. 730346, IPC АВВ 5/05, publ. 1976 women in a case made of insulating material, the case is equipped with a support pad with a diameter

25..35 mm, in the center of which the end surfaces of the electrodes are located, while the outer diameter of the outer electrode is 2 ... 6 mm. Such an electrode device is not very effective when used for electrical stimulation due to the instability of the area of contact with the skin and the small diameter of the electrodes.

The technical result, the achievement of which is aimed at creating a utility model for ensuring the stability of the contact of the electrode device with the skin with electro-stimulating effects on the face and / or neck with the aim of rejuvenating and healing the skin.

The specified technical result is achieved by the fact that in the first embodiment, in the electrode device for electrical stimulation, containing a body of electrical insulation material and placed coaxially on the end and / or side surface of the body of the external passive and internal active electrodes, the body is made in the form of a hollow truncated tetrahedral pyramid, and contact the surface of the electrodes is the surface of a body of revolution with a radius exceeding 3 ... 10 times the maximum size of the external electrode. The edges of the electrodes are made with a rounding radius of at least 0.5 mm. The surface of the inner electrode protrudes above the surface of the outer electrode by no more than 5 mm. The width of the insulating gap between the outer and inner electrodes is 1 ... 5 mm, while the contact surface area of the inner electrode exceeds 2 mm. Inside the circuit of the external passive electrode, several (two or more) internal active electrodes can be placed, isolated from each other and having separate connectors for connection to an electric stimulator.

In the second embodiment, the technical result is achieved by the fact that in the electrode device for electrical stimulation containing passive and active electrodes mounted on an insulating casing with a wall thickness of not more than 2 mm, the contact pad of the active electrode is installed on the outside of the surface of the casing, and a flat passive electrode is placed on the inner surface of the housing parallel to the plane of the contact pad of the active electrode and is made in the form of a similarity of a rectangle with an internal cutout, while m in the projection onto the plane of the passive electrode, the external contour of the active electrode overlaps the contour of the internal cut-out of the flat passive electrode by no more than 1 mm on either side of this circuit, and the external contour of the passive electrode stands for the projection of the active contour

electrode not less than 2 mm on each side of this circuit.

For marking the inventive electro-adaptive stimulator, the trademark “COSMODRZH” was registered (decision on registration of the trademark f. No. 01 TZ of 06/29/2002 by application No. 2000730710/50).

Utility models are illustrated by drawings.

Figure 1 shows the functional diagram of the first variant of the electro-neuroadaptive stimulator "COSMODIC. Figure 2 is a functional diagram of a second variant of the electro-neuroadaptive stimulator "COSMODIC. On Fig.3 shows a block diagram of a control unit and the formation of trigger pulses. Figure 4 shows the structural diagram of the node analysis, control and formation of trigger pulses. In Fig. 3 is a possible diagram of a key amplifier. 6 is a possible diagram of a managed electronic key. 7 - schematically shows the design of the first embodiment of the electrode device with one active electrode. On Fig shows the construction of the first variant of the electrode device with multiple active electrodes. Figure 9 shows the construction of a second embodiment of an electrode device. In FIG. 10 shows an enlarged algorithm for the operation of the control unit and the formation of triggering pulses. In FIG. 11 shows the directions of movement of the electrode device along the massage lines of the face and neck.

In FIG. 1 .. .9 are indicated by numbers;

1- direct current source;

2- control unit and the formation of triggering pulses;

3- demultiplexer;

4-section high-quality inductor;

5, 51 ... 5p - key amplifiers; 6 - electrode device; 7, 71 ... 7k - active electrodes;

.t

8 ow pool met 10 - the second end of the section with fewer turns; Yu ... 10p - branch bends with fewer turns; 11- second end of the section with a large number of turns; 12-pulse output of the control unit and the formation of trigger pulses; 13-code output of the control unit and the formation of trigger pulses; 141 ... 14p - outputs of the demultiplexer; 15- input of the feedback signal of the control unit and the formation of triggering impulse 16-decoder; 171 ... 17k - managed electronic keys; 181 ... 18k - decoder outputs; 19 - node analysis, control and formation of triggering pulses; 20- node for setting operation modes; 21- display unit; 22 - installation input node analysis, control and formation of triggering pulses; 23 - information outputs of the analysis, control and formation of launching imov node; 24- clock pulse generator (GTI); 25 is a diagram of the formation of triggering pulses (FZI); 26 is a diagram of the formation of control signals (FSU); 27- analog-to-digital converter (ADC); 28 is a circuit for measuring parameters of a feedback signal (SIP); 29 is a diagram of measuring the rate of change of the parameters of the feedback signal (SIS); 30 is a feedback signal extraction circuit with a maximum rate of change of pairs (CB); 31- diagram of the fixation of the absence of changes in the parameters of the feedback signal (SF);

34 - the first input of the circuit fixing the absence of changes in the parameters of the feedback signal;

35 - the second input of the circuit fixing the absence of changes in the parameters of the feedback signal;

36 - information output of the circuit of the rate of change of the parameters of the feedback signal;

37 - information output of the maximum rate of change of feedback signal parameters;

38- information output of the circuit for the absence of changes in the parameters of the feedback signal;

39 - damping diode;

40- semiconductor triode;

41-controlled electronic key (CMOS key);

42- adjustment resistor;

43- housing of the electrode device;

44- tap wire from the passive electrode;

45, 45i .. .45k - outlet wires from active electrodes.

The electro-adaptive stimulator "COSMODIC (Fig. 1) in the first embodiment contains a direct current source 1, control and generating pulses 2, a demultiplexer 3, a two-section high-quality inductance 4, key amplifiers 5 ... 5p, an electrode device 6, including coaxially placed active electrode 7 and passive electrode 8. Two-section high-quality inductor 4 has a connection point of sections 9, taps 10i ... lOn of the section with fewer turns and the second end 11 of the section with a large number ETS turns. The pulse output 12 of block 2 is connected to the pulse input of the demultiplexer 4, the code output 13 of block 2 is connected to the code input of the demultiplexer 4, the outputs of which are connected to the corresponding signal inputs of key amplifiers 5 | ... 5n. The outputs of the key amplifiers 5b..5p are connected respectively to the taps 10i ... lOn of the section with fewer turns. The connection point of sections 9 is connected to the first

the pole of the DC source 1 and the passive electrode 8, and the second end 11 of the section with a large number of turns with the active electrode 7 of the electrode device 6 and the input 15 of the feedback signal of unit 2. The second pole of the DC source 1 is connected to the power bus of the key amplifiers 5i. ..5n. A high-quality inductor 3 has an inductance of 0.1 2.0 H, the ratio of the number of turns of the section with fewer turns to the total number of turns is 0.05 ... 0.3, taps 10i ... lOn of the section with fewer turns are made with in a uniform step, and the quality factor of the inductance coil exceeds 100. The COSMODIC electroneuroadaptive stimulator (Fig. 2) in the second embodiment contains a direct current source 1, a control and generating pulse generating unit 2, a decoder 16, a two-section high-quality inductance coil 4, a key amplifier 5, an electrode device 6, including active electrodes 1 ... 1 and a passive electrode 8, and controlled electronic keys 17 ... 17k. A two-section high-quality inductor 4 has a connection point for sections 9, a second end 10 of the section with fewer turns and a second end 11 of the section with more turns. The pulse output 12 of block 2 is connected to the signal input of the key amplifier 5, the code output 13 of block 2 is connected to the input of the decoder 16, the outputs of which 18 ... 18k are connected to the control inputs of the corresponding controlled electronic keys 17i ... l7k. The output of the key amplifier 5 is connected to the second end 10 of the section with fewer turns. The connection point of sections 9 is connected to the first pole of the DC source 1 and the passive electrode 8, and the second end 11 of the section with a large number of turns with input 15 of the feedback signal of unit 2 and signal inputs of controlled electronic keys 17 ... 17k, to the outputs of which are connected active electrodes 7 | ... 7k of the electrode device 6. In the load circuits of the controlled keys 17 ... 17k, adjustment resistors 42 can be included (Fig. 6). The second pole of the DC source 1 is connected to the power bus of the key amplifier 5. The high-quality inductor 3 has an inductance of 0.1 ... 2.0 H, the ratio of the number of turns of a section with fewer turns to the total number of turns is 0.05 ... 0.3, the quality factor of the inductor exceeds 100.

o Z / MED li Block 2 (Fig.Z), designed to select operating modes, control the energy level

stimulus and analysis of feedback signals, in both versions of the electro-adaptive stimulator, contains a node 19 for analysis, control and formation of triggering pulses, a node 20 for specifying operating modes and an indication node 21. The node 20 includes at least controls for the stimulus energy level and a power-on element. The output of node 20, by commands from which continuous or periodic operation modes are set, the duration of the triggering pulses and their number in a series is set, connected to the installation input 22 of node 19. The pulse output of node 19 is a pulse output 12, the code output of node 19 is a code output 13 and the signal input - input 15 of the feedback signal of unit 2. Node 19, made in the form of an ultra-large integrated circuit (VLSI), has at least two operating modes, in the first of which there are series at the pulse output 12 of the control unit triggering pulses with a fixed number of pulses in a series, and at the code output 13, a sequence of codes from 1 to N (in the first embodiment) or K (in the second embodiment), where N is the number of key amplifiers, and K is the number of controlled electronic keys. A code change in the sequence of codes occurs with each series of triggering pulses. In the second mode of operation of the node 19 at the pulse output 12 is a continuous sequence or sequence of series of triggering pulses, at the code output 13 is an unchanged code. The information outputs 23 of the node 19 are connected to the input of the node 21, designed to display the operating mode and parameters of the stimulating effect.

The node 19 analysis, control and formation of triggering pulses (figure 4) is made in the form of an extra-large integrated circuit - VLSI, which contains a clock pulse generator - GTI 24, a circuit for generating triggering pulses - FZI 25, a circuit for generating control signals - FSU 26, and sequentially connected analog-to-digital converter - ADC 27, feedback signal parameter measurement circuit - SIP 28, feedback signal parameter velocity measurement circuit - SIS 29, feedback signal extraction circuit with maximum speed the change rate of parameters - CB 30 and the fixation circuit for the absence of changes in the parameters of the feedback signal - SF 31. The input of the ADC 27 is the signal input 15 of node 19, the output of the GTI 24 is connected to the first input of the FZI 25, the first output of which is connected to the input of the FSU 26. The second input FZI 25 is the installation input 22 of the node 19, and the second

12

the output of the FDI 25 is by the pulse output 12 of the node 19 and is connected to the second input of the CB 30. The output of the FSU 26 is the code output 13 of the node 19 and is connected to the second input of the CB 30. The second output of the SIS 29 is connected to the second input of the SF 31. The second output of the 30 is connected with the second input of the FSU 26, the third input of which is connected to the first output of the SF 31. The second output of the SF 31 and the third outputs of the SIS 29 and CB 30 are information outputs 36, 37 and 38, combined into an information output 23 of the node 19.

The electrode device for electrical stimulation used in the electro-adaptive stimulator "COSMODIC (Fig. 8) contains a housing 43 made of electrical insulation material and placed on the front and / or side surface of the housing coaxially external 8 passive and internal 7 active electrodes, connected through lead wires 44 and 45 to the outputs of the electron-adaptive stimulator. The housing 43 is made in the form of a hollow truncated tetrahedral pyramid, and the contact surfaces of the electrodes 7 and 8 represent the surface of the body of revolution with a radius 3 ... 10 times the maximum size of the external electrode 8. The edges of the electrodes 7 and 8 are made with a rounding radius of at least 0.5 mm The surface of the inner electrode 7 protrudes above the surface of the external electrode 8 by no more than 5 mm.

The width of the insulating gap between the outer 8 and inner 7 electrodes is 1 ... 5

MM, while the contact surface area of the inner electrode 7 exceeds 2 mm Inside

of the circuit of the external passive electrode 8, several (two or more) internal active electrodes 7i ... 7k can be placed, isolated from each other and having separate connectors 45) ... 45k for connecting to the electronic keys 17i ... l7k of the electro-adaptive stimulator (Fig. 8).

In the second embodiment of the electrode device for electrical stimulation (Fig.9), containing a passive 8 and active 7 electrodes mounted on an insulating housing 42, the contact pad of the active electrode 7 is installed on the outside of the surface of the housing 42, and a flat passive electrode 8 is placed on the inner surface of the housing 42 parallel to the plane of the contact pad of the active electrode 7 and is made in the form of a rectangle with an internal cutout, while in the projection onto the plane of the passive electrode 8, the external contour of the electrode 7 overlaps the contour of the internal cut-out of the flat passive electrode 8 by no more than 1 mm on either side of this circuit, and the external circuit of the passive electrode 8 stands for the projection of the circuit of the active electrode 7 by at least 2 mm on each side of this circuit, and the thickness the walls of the housing in the area of the electrodes does not exceed 2 mm

The work of the claimed electroneuroadaptive stimulator "COSMODRZH. Active 7 and passive 8 electrodes are connected to one of the sections of the two-section inductor 4, the other section of which is connected between the poles of the DC source 1 through the key amplifier 5, in the initial state it is locked and unlocked for the duration of the triggering pulse, during which the inductor 4 is saturated electromagnetic energy. At the end of the triggering pulse, the key amplifier is locked and the oscillatory circuit formed by the circuit: active electrode 7 - interelectrode fabric - passive electrode 8 - point 9 of the connection sections of the two-section inductor 4 - section with a large number of inductance 4 - the second end 11 of this section - active electrode 7 there are electrical vibrations, which are a stimulating signal. The energy power of the stimulating signal is greater, the greater the duration of the triggering pulse. In the second embodiment, between the second end 11 of the section with a large number of turns of the coil 4 and the active electrodes 71 ... 7k, controlled electronic keys 171 ... 17k are included. A characteristic feature of the electroneuroadaptive stimulator is that the parameters of the stimulating signal, for example, the amplitude of the first half-wave, attenuation, and frequency, depend on the reactive and active resistances of the interelectrode tissue. Therefore, as a criterion of the degree of influence of the stimulating effect, a factor of changing the parameter (s) of the stimulating signal and a sign of the end of stimulation, the absence of a change in the parameters of the stimulating signal, can be taken.

The electrode device 6 is pressed by the electrodes 7 and 8 to the skin of the face and / or neck in the affected area. Since the contact surfaces of electrodes 7 and 8 are a surface of revolution with a radius of 3 ... 10 times larger than the maximum size of the electrode, and the active electrode 7 protrudes above the surface of the passive electrode by no more than 5 mm, reliable contact with both electrodes is ensured even at the slightest presses. After turning on the power, a continuous mode of operation and a minimum duration of triggering pulses at the output 12 of block 2 are established. Gradually increasing the duration of the triggering pulses using the controls in node 20, the stimulating energy energy is set at the sensitivity threshold level, i.e. in which the effect is felt in the form of light tingling or tickling. Next, the operating mode is switched on, the sequence of actions of which is illustrated by the algorithm of operation of block 2 shown in FIG. 10. At the beginning, the “SEARCH. In this mode, at the output 12 of block 2 there are a series of triggering pulses with a fixed number of pulses in a series, for example, two or three pulses in a series, and at the code output there is a sequence of codes, according to which the outputs of demultiplexer 3 in the first embodiment and decryptor 16 are switched - in the second option. Thus, in the “SEARCH series of

two pulses are alternately fed to the inputs of key amplifiers 5 ... 5p in the first embodiment or to the inputs of controlled electronic keys 17i ... 17k in the second embodiment, which leads to a change from the series to the series of triggering pulses of the amplitude of the first half-wave of the stimulating signal and the frequency of the decaying fluctuations. The feedback signal is fed to the input 15 of the node 19, is converted to digital form by the ADC 27, and in the SIP 28 the parameters (parameter) of the feedback signal are measured. Further, in the SIS 29, the rate of change of the feedback signal parameters from the first trigger pulse is determined

in the series to the last (second or third) - L P. The rate of change of the feedback signal parameters determined for the current series of triggering pulses in CB 30 is compared with the maximum rate of change of parameters determined in the previous series, and if it turns out to be equal to or

more, then in SV 30 the value of this speed is fixed - D PM and the code number of the key amplifier 5 or the controlled electronic key 17 - NM. As a result, in the “SEARCH” mode of operation, that key amplifier 5 or that controlled electronic key 17 is detected, when it is fed to the input, the maximum rate of change of the feedback signal parameters is observed. At the end of the enumeration of codes (NjeK NKOH, the current number is equal to the final one) at the FSU 26 code output, i.e. after

in turn, key amplifiers 5i ... 5n or controlled keys Hj ... П, according to the input signal

FSU 26, the “STIMULATION. When working in this mode, at the output 12 of block 2, a continuous sequence of triggering pulses or a series of pulses is observed, the number of pulses in which is not normalized, and at output 13, the code number of the key amplifier 5 or the controlled electronic key 17 is NM- In SF 31, a change in parameters is measured feedback signal, and when this change will be absent, i.e. when the parameters of the previous feedback signal are equal to the parameters of the subsequent feedback signal, the “SEARCH by the signal at input 32 FSU 26 mode is switched back on. Thus, the stimulating effect optimal in terms of parameters is automatically established on each area of the skin of the face or body. The claimed technical result is due to the fact that in the first embodiment, the design of the electro-adaptive stimulator when switching

taps lOi -.- lOn sections with fewer turns changes the inductive resistance of the oscillatory circuit, and therefore the frequency of electrical vibrations of the stimulating signal when using an electrode device with one active electrode 7 (Fig. 7). In the second embodiment, the design of an electron-adaptive stimulator using an electrode device with several

electrodes 7 ... 7 | with the switching of the electrodes, the active resistance of the oscillatory circuit changes, both due to the passage resistance of the controlled electronic keys, and, if necessary, due to additional adjustment resistances 42 (Fig. 6), which also leads to a change in the frequency of electrical oscillations. The authors experimentally established that the inductance of the inductor 4 to achieve a cosmetic effect should be in the range of 0.1 ... 2.0 H at a quality factor of at least 100.

Achievement of the claimed technical result can be explained as follows.

It is known that under the influence of microcurrents in the human body, the concentration of biologically active substances (serotonin, heparin, histamine) increases, the release of which into the blood is accompanied by a change in the composition of blood microelements as a result of oxidation of biologically active substances by transition metal ions. In this case, metal biocomplexes are formed, which activate the biological functions of the body at the cellular level, and the concentration of most trace elements in the blood decreases accordingly (see the article by Zorin O.I. and Orlova M.V. Human blood currents after microcurrents. Biophysics, v. 37, vol. 2, Science, 1992).

In addition, exposure to microcurrents is effective in neutralizing polarity fluctuations in damaged cells (if a cell does not function adequately, exposure to microcurrents will balance its electrical potential). The influence of microcurrents significantly increases the cell supply of ATP (adenosine triphosphate), increases the permeability of cell membranes and, thus, provides ion transport and cell nutrition.

Thus, due to an increase in the concentration of biologically active substances in the body and the formation of metal biocomplexes, the biological functions of the body at the cellular level are activated, which allows you to effectively restore and treat the skin and reduce the time of this recovery and treatment, as well as to eliminate the effect of the body getting used to

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electrical exposure and increase the comfort of electrical exposure. Electrical stimulation of the neuromuscular apparatus is a method of non-pharmacological treatment and prophylaxis, expanding the own compensatory capabilities of the human body, significantly increasing its protective functions.

Currently, pulsed electrotherapy is universally recognized as one of the leading methods of physical treatment, successfully competing with drug and other types of therapy. Several of the most used methods of low-frequency pulsed electrical stimulation with a wide range of therapeutic effects have been developed. Among them: electrosleep, diadynamic therapy, amplipulse therapy, interference therapy, fluctuation, percutaneous electroneurostimulation.

In these methods, by changing the shape and duration of the pulse, using medium-frequency filling of low-frequency pulses, varying the frequency response of the current, as well as using combined modes, including sending currents of different frequencies, sending currents and pause, special methods of applying electrodes, it is possible to normalize the function of the central nervous system and higher autonomic centers, changes in the state of general and local hemodynamics (lowering blood pressure, reducing the frequency of cardiac contractions, vasodilation, increased collateral blood flow and microcirculation), elimination of pain, swelling, smooth muscle spasms of blood vessels and internal organs, anti-inflammatory and trophic-stimulating effects, stimulation of skeletal muscles.

Opportunities for improving the therapeutic methods of low-frequency pulsed electrotherapy are associated with the search for the most physiological and effective form of pulses, as well as the introduction of elements of automatic programmatic regulation of frequency and amplitude parameters of exposure.

The main feature of electroneuroadaptive stimulation is the formation of an electrostimulating signal, approaching in phase structure to the current of action of the membrane of neuromuscular cells of a healthy person, which are best perceived by excitable structures and cause the most adequate response of the body.

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An electro-stimulating signal - electrical vibrations in a resonant circuit formed by the inductance of a high-quality inductor and the impedance of the interelectrode tissue, changes the concentration of tissue ions in the cell membrane and, changing its permeability, acts like natural biocurrents.

In this regard, it is the most universal irritant for all excitable structures. Electrical stimulation of the above waveform not only prevents the development of muscle atrophy (as with other types of electrical stimulation), but also activates hormonal regulation (stimulation of the corticoid function of the adrenal cortex) and activates the processes of tissue respiration; enhances venous circulation and lymph flow; normalizes the function of the affected organ or organ system.

The output impulse should be as close as possible in physical impact to the impulse of the central nervous system of a healthy person, which allows (with the specified exposure pattern) to regulate the work of organs and systems of the human body, forcing it to work in health mode.

The peculiarity of the acting (stimulating) signal of the COSMODIC electroneuroadaptive stimulator is that the electrical vibrations that occur in the resonant circuit cause mechanical vibrations in the skin microstructures, and when the frequency of the electrical vibrations is tuned, conditions arise for the resonance of mechanical vibrations in one or another skin microstructure. Under the influence of mechanical vibrations, chemical reactions are activated, conformative changes in the protein molecules occur, as a result of which the membrane permeability increases (decreases) and the process of depolarization (excitation) or hyperpolarization (inhibition) is formed. In addition, when moving the electrode device along the massage lines of the face and / or soup, an additionally purely mechanical effect is applied to the muscles of the face and neck, regardless of the force with which the electrode device is pressed against the skin. This mechanical effect on the muscles of the face and neck, directed along their fibers, additionally provides for the regulation of blood flow in the muscles and helps to restore their volume.

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Claims (15)

1. An electro-adaptive stimulator designed primarily for rejuvenating the skin of the face and / or neck, containing a direct current source, a trigger pulse generating unit and an electrode device including passive and active electrodes, characterized in that it contains a two-section high-quality inductor and a demultiplexer, a signal input which are connected to the pulse output of the trigger generation block, and the control input with the code output of the trigger pulse generation block, the dyne from the poles of the direct current source is connected to the passive electrode of the electrode device and the connection point of the sections of a two-section high-quality inductor, the sections of which are connected according to, the second end of the section with a large number of turns is connected to the active electrode and the feedback signal input of the triggering pulse generating unit, section with a smaller the number of turns is made with taps, each tap of this section through a key amplifier is connected to the second pole of the DC source, input control of each key amplifier is connected to the corresponding output of the demultiplexer. 2. The electron-adaptive stimulator according to claim 1, characterized in that the triggering 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 an analysis, control and generating pulse generating unit, made in the form of an ultra-large integrated circuit (VLSI), while the 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 output is the pulse output of the triggering pulse generating unit, the VLSI code output is the code output of the triggering pulse generating unit, the VLSI signal input is the feedback signal input of the control unit, and the VLSI has at least two operating modes, the first of which is at the pulse output of the block control there are a series of triggering pulses with 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 key amplifiers, changes in which the code on each series of trigger pulses, while the second - the pulse output a continuous sequence or series of firing pulses, seven output - unmodifiable code. 3. The electron-adaptive stimulator according to claim 2, characterized in that the node analysis, control and pulse shaping, made in the form of an ultra-large integrated circuit (VLSI) contains a clock pulse generator, a trigger pulse generation circuit, a control signal generation circuit, and analog-digital connected in series converter, a feedback signal parameter measurement circuit, a feedback signal measurement rate measuring circuit, a maximum feedback signal allocation circuit the rate of change of parameters and the fixation circuit for the absence of a change in the parameters of the feedback signal, while the output of the analog-to-digital converter is a feedback signal input, the output of the clock pulse generator is connected to the first inputs of the trigger pulse generation circuit and the control signal generation circuit, the output of the trigger pulse generation circuit is VLSI signal output and is connected to the second input of the circuit for measuring the rate of change of the parameters of the feedback signal, the output of the circuit of the control signals is the VLSI code output and is connected to the second input of the feedback signal extraction circuit with a maximum rate of change of parameters, the second outputs of the feedback signal measurement circuit of the feedback signal and the feedback signal allocation circuit with a maximum rate of change of parameters are connected respectively to the first and second inputs of the fixing circuit of the absence of changes in the parameters of the feedback signal, the first output of the feedback signal allocation circuit with the maximum soon a parameter change circuit is connected to a second input of a control signal generation circuit, a third input of which is connected to a first output of a feedback signal fixation circuit without a change in parameters, a second output of a feedback signal fixation circuit of no change in a feedback signal parameters and third outputs of a circuit for measuring a rate of change of a feedback signal parameters and feedback signal isolation circuits with maximum parameter changes are VLSI information outputs. 4. The electron-adaptive stimulator according to one of claims 1 to 3, characterized in that the high-quality inductor has an inductance of 0.1-2.0 H, the ratio of the number of turns of the section with fewer turns to the total number of turns is 0.05-0, 3, the taps are made with a uniform pitch, and the quality factor of the inductor exceeds 100. 5. An electro-adaptive stimulator designed primarily for rejuvenating the skin of the face and neck, containing a direct current source, a trigger pulse generating unit and an electrode device including passive and active electrodes, characterized in that it additionally contains several (two or more) active electrodes, a two-section a high-quality inductor, the sections of which are included according to, and a decoder, one of the poles of the DC source is connected to the connection point of the two-section sections of a high-quality inductor and a passive electrode of the electrode device, the second end of the section with fewer turns through a key amplifier is connected to the second pole of the DC source, the second end of the section with more turns is connected to the input of the feedback signal of the triggering pulse generating unit and through controlled electronic keys with each active electrode, the signal output of the block forming the triggering pulses is connected to the signal input of the key amplifier, code output d probing pulse forming unit is connected to the input of the decoder, the outputs of which are each connected to a corresponding control input of the electronic key managed. 6. The electron-adaptive stimulator according to claim 5, characterized in that the controlled electronic keys contain adjustable resistors in the load circuits. 7. The electro-adaptive stimulator according to claims 5 and / or 6, characterized in that the triggering pulse generating unit comprises a mode setting unit including at least stimulus energy level control elements and a power-on element, an indication unit and an analysis unit, control and pulse generation, made in the form of an extra-large integrated circuit (VLSI), while the 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 signal the VLSI path is the pulse output of the triggering pulse generating unit, the VLSI code output is the code output of the triggering pulse generating unit, the VLSI signal input is the feedback signal input of the triggering pulse generating unit, and the VLSI has at least two operating modes, in the first of which a pulse output of the control unit there are a series of triggering pulses with a fixed number of pulses in the series, and at the code output a sequence of codes from 1 to k, where k is the number of control Mykh electronic keys, change the code in which happens to each series of trigger pulses, and in the second - on the pulse output a continuous sequence or series of firing pulses, seven output - an immutable code. 8. The electron-adaptive stimulator according to claim 7, characterized in that the node analysis, control and pulse shaping, made in the form of an ultra-large integrated circuit (VLSI) contains a clock pulse generator, a trigger pulse generating circuit, a control signal generating circuit, and analog-digital connected in series converter, a feedback signal parameter measurement circuit, a feedback signal measurement rate measuring circuit, a maximum feedback signal allocation circuit the rate of change of parameters and the fixation circuit for the absence of changes in the parameters of the feedback signal, while the output of the analog-to-digital converter is the input of the feedback signal, the output of the clock pulse generator is connected to the first inputs of the formation of trigger pulses and the control signal generation circuit, the output of the trigger pulse generation circuit is a signal VLSI output and connected to the second input of the circuit for measuring the rate of change of the feedback signal parameters, the output of the formation circuit I control signal is the VLSI code output and is connected to the second input of the feedback signal allocation circuit with a maximum rate of change of parameters, the second outputs of the feedback signal measurement circuit of the change of parameters of the feedback signal and the feedback signal allocation circuit with a maximum rate of change of parameters are connected respectively to the first and second inputs of the fixation circuit of the absence of changes in the parameters of the feedback signal, the first output of the feedback signal allocation circuit with the maximum speed parameter changes are connected to the second input of the control signal generation circuit, the third input of which is connected to the first output of the fixation circuit for the absence of changes in the parameters of the feedback signal and the third outputs of the circuit for measuring the rate of change of the feedback signal parameters and the feedback signal extraction circuit with the maximum parameter change are information outputs VLSI. 9. The electron-adaptive stimulator according to one of claims 5 to 8, characterized in that the high-quality inductor has an inductance of 0.1-2.0 H, the ratio of the number of turns of a section with fewer turns to the total number of turns is 0.05 ... 0.3, the bends are made with a uniform step, and the quality factor of the inductor exceeds 100. 19. An electrode device for electrical stimulation, comprising a housing of electrical insulating material and placed coaxially on the end and / or side surface of the housing external passive and internal active electrodes, characterized in that the housing is made in the form of a hollow truncated tetrahedral pyramid, and the contact surfaces of the electrodes are a surface bodies of revolution with a radius 3-10 times greater than the maximum size of the external electrode. 11. The electrode device according to claim 10, characterized in that the edges of the electrodes are made with a rounding radius of at least 0.5 mm. 12. The electrode device according to claim 10 or 11, characterized in that the surface of the inner electrode protrudes above the surface of the outer electrode by no more than 5 mm. 13. The electrode device according to one of paragraphs.10 to 12, characterized in that the width of the insulating gap between the outer and inner electrodes is 1-5 mm, while the contact surface area of the inner electrode exceeds 2 mm ² . 14. The electrode device according to one of paragraphs.10 to 13, characterized in that it contains several (two or more) internal active electrodes inside the circuit of the external passive electrode, isolated from each other and having separate connectors for connection to an electric stimulator. 15. An electrode device for electrical stimulation, containing a passive and active electrodes mounted on an insulating casing, characterized in that the contact pad of the active electrode is installed on the outer side of the surface of the casing, and a flat passive electrode is placed on the inner surface of the casing parallel to the plane of the contact pad of the active electrode and is made in the form of a similarity to a rectangle with an internal cutout, while in the projection onto the plane of the passive electrode the external contour of the active electro and overlaps the inner contour of the recess flat passive electrode is not more than 1 mm from either side of the contour and the outer contour of the passive electrode stands for projection electrode active circuit is not less than 2 mm on each side of the circuit.