RU2002118595A - METHOD AND DEVICE FOR ACTIVATION OF ION TRANSFER - Google Patents

Claims (19)

1. A method of activating ion transfer through cell membranes and capillary walls of living organisms, consisting in the action of a pulsed electromagnetic field of a very low frequency generated by electric current pulses, characterized in that the two types of signals and their combination in the form of successive packets, packet groups , series of groups of packages, sets of series of groups of packages and combinations of sets of series of groups of packages are used to obtain simultaneous magnetomechanical and electrodynamic effects on ions of various elements, which also leads to the appearance of ion cyclotron resonance, and the characteristic of induction B, as a function of time B = f (t), is a broken line that differs for both types of signals and increases from zero to B _max , where the characteristic of signals of the first type is a broken line consisting of seven segments (a, b, c, d, e, f, g) with a total duration (T ₁ ) between 3.0 and 9.4 ms, while the induction increases linearly within the first segment ( a) from zero to 1/3 B _max and remains at this level within the WTO of the second segment (b), which is parallel to the t axis, then, within the third segment (c), the induction increases linearly from 1/3 V _max to 2/3 V _max and remains at the last value within the fourth segment (d), which is parallel to the axis t, then it increases linearly to B _max , within the fifth segment (e), and then it sharply decreases to zero within the sixth segment (f), which is approximately perpendicular to the t axis, then remains equal to zero within the seventh segment (g ), further, the characteristic of the signal of the second type is also a broken line a line consisting of five segments (k, l, m, n, r) with a total duration (T ₂ ) between 5.0 and 9.4 ms, where the induction increases linearly within the first segment (k) from zero to 1 / 2 B _max and remains at this level within the second segment (1), which is parallel to the t axis, then, within the third segment (m), the induction increases linearly from 1/2 B _max to B _max , and then it decreases sharply to zero within the fourth segment (n), which is approximately perpendicular to the t axis, and remains at zero level within the fifth segment (r), when effective the induction values for both types of signals do not exceed B _SK = 100 μT, and where the linear increase in induction B, represented as segments (a, c, e) and (k, m), inclined with respect to the t axis, on the characteristics of the signals of both types lead mainly to electrodynamic and electromechanical effects, and constant induction B, maintained at 1/3 V _max , 2/3 B _max and 1/2 B _max , and represented as segments (b, d) and ( 1), parallel to the t axis, lead mainly to ion cyclotron resonance. 2. The method according to claim 1, characterized in that the first type of signal is used, in which the duration (t ₁ ) of the first segment (a) is between 0.5 and 1.6 ms, the duration (t ₂ ) of the second segment ( b) is between 0.5 and 1.2 ms, the duration (t ₃ ) of the third segment (s) is between 0.4 and 1.5 ms, the duration (t ₄ ) of the fourth segment (d) is between 0.1 and 0.5 ms, the duration (t ₅ ) of the fifth segment (e) is between 0.5 and 1.5 ms, the duration (t ₆ ) of the sixth segment (f) does not exceed 0.1 ms , and will continue lnost (t ₇₎ the seventh segment (g) is between 0.5 and 1.5 ms, also using the second type signal, wherein the duration (t ₁₎ the first segment (k) is between 0.7 and 1 , 3 ms, the duration (t ₂ ) of the second segment (l) is between 1.8 and 2.8 ms, the duration (t ₃ ) of the third segment (m) is between 0.5 and 1.2 ms, the duration (t ₄ ) of the fourth segment (n) does not exceed 0.1 ms, and the duration (t ₅ ) of the fifth segment (r) is between 1 and 2 ms. 3. The method according to claim 2, characterized in that they use packets of signals of both types, each of which consists of a sequence of successive single signals of this type, and use the pause between consecutive packets, the duration of the packet of signals of the first type (T _p1 ) is between 10 and 50 ms, and the pause time (t _p1 ) is between 40 and 60 ms, the duration of the second type of signal packet (T _p2 ) is 20 to 30 ms, and the duration (t _p2 ) between pause packets is from 20 to 50 ms while the duration (t _p1 ) of the pause between consecutive packets of signals of the first type is longer than the duration (t _p2 ) of the pause between packets of signals of the second type. 4. The method according to claim 3, characterized in that they use packets of signals of the first type, consisting of at least four signals, each. 5. The method according to claim 3, characterized in that they use packets of signals of the second type, consisting of at least five signals, each. 6. The method according to claim 3, characterized in that the groups of signal packets of both types are used, each group consisting of series of signal packets of a given type, and a pause between consecutive groups is used, the duration (T _p1 ) of the signal packet group of the first type being from 250 to 400 ms, and the pause (t _p1 ) lasts from 40 to 60 ms, the duration (T _p2 ) of the group of signal packets of the second type is from 140 to 300 ms, and the pause (t _p1 ) lasts from 80 to 200 ms 7. The method according to claim 6, characterized in that they use groups of signal packets of the first type, consisting of at least five packets, each. 8. The method according to claim 6, characterized in that they use groups of signal packets of the second type, consisting of at least four packets, each. 9. The method according to claim 6, characterized in that they use a series of groups of signal packets of both types, each series consisting of a series of groups of signal packets of a given type, and also use a pause between consecutive series, the duration (T _s1 ) of a series of packet groups signals of the first type is from 7 to 10 s, and the pause period (t _s1 ) between series is from 3 to 4 s, the duration (T _s2 ) of a series of signal packet groups of the second type is from 5 to 9 s, and the pause (t _p1 ) between series is from 2 to 4 s. 10. The method according to claim 9, characterized in that they use a series of groups of signal packets of the first type, each series consisting of twenty to twenty-six groups, with twenty-four groups being advantageous. 11. The method according to claim 9, characterized in that they use a series of groups of signal packets of the second type, each series consisting of twenty to twenty-four groups, with twenty-two groups being advantageous. 12. The method according to claim 9, characterized in that they use sets of series of signal packet groups of both types, each set consisting of series of signal packet groups of a given type, the duration (T _z1 , T _z2 ) of series of signal packet groups of the first and second types is between 90 and 240 s, using both positive and negative polarization for a set of series of groups of signal packets of a given type. 13. The method according to p. 12, characterized in that they use sets of series of groups of signal packets of the first type, each set consisting of at least ten series, using a variable positive and negative polarization for successive sets. 14. The method according to p. 12, characterized in that they use sets of series of groups of signal packets of the second type, each set consisting of at least twelve series, using variable positive and negative polarization for successive sets. 15. The method according to p. 12, characterized in that the amplitude of the signals in the sets of series of groups of signal packet groups of both types is maintained at a certain level, which does not exceed the effective value B _SK = 100 μT, and / or is changed stepwise in successive series . 16. The method according to p. 12, characterized in that they use combinations of sets of series of groups of signal packets of the first and second types in the form of at least two sets of series of groups of signal packets of the first type, followed by at least two sets of series groups of signal packets of the second type, and use the opposite polarization for adjacent sets. 17. A device for activating ion transfer, comprising a control and control panel with control buttons and signal lights, which is connected to the microprocessor control unit with a generator and memory, and is also connected, using an amplifier, to a current pulse to electromagnetic signal converter, characterized in that the control and control panel (PS) is connected to an infrared receiver (IR) controlled by a remote controller (P), and the microprocessor control unit (MUS) It holds memory such as random access memory (RAM), mainly for direct control, as well as an additional non-volatile electrically erasable programmable ROM for programming the functions of the device from the outside world, while random access memory (RAM) contains waveforms of both types, the sequence of their appearance, combinations of their parameters in packages, package groups, series of package groups, sets of series of package groups, with time relationships and amplitude changes, take and non-volatile electrically erasable programmable ROM contains standard, ready-to-use programs for setting combinations of signals into packets, packet groups, series of packet groups, sets of series of packet groups, with time relationships and amplitude changes taken into account, in addition, the binary-controlled voltage amplifier (W) is connected to a symmetrical current source (IS) and further connected to a switching actuator circuit (UW), which is directly driven from the microprocessor control unit (MUS), and is additionally connected to the converter (PA) and the load (PL), while the voltage amplifier (W) contains two operational amplifiers (W1, W2), and the input (WE) of the voltage amplifier is directly connected to non-inverting (+) input of the first operational amplifier (W1), and by means of resistance (R1) with an inverting input (-) of the second operational amplifier (W2), while the second operational amplifier together with four resistances (R1) forms a differential amplifier with a non-inverting input (+) Connected to the output of the first operational amplifier (W1), and further between the ground and the inverting input (-) of the first operational amplifier (W1), wherein the branches of series connected keys (K _1, K _2, K ₃ ... K _n ) and resistances (R, R / 2, R / 4 ... R / ^2n-1 ) are connected to the negative feedback circuit of the first operational amplifier (W1), and the output (WY) of the voltage amplifier (W) is simultaneously the output of the second operational amplifier (W2). 18. The device according to 17, characterized in that the output voltage (U _wy ) of the voltage amplifier (W) varies depending on the keys (K ₁ , K ₂ , K ₃ ... K _n ) switched according to the formula

for n≥1, U _wy = 0 for n = 0, where U _wy is the output voltage of the amplifier; U _we - input voltage of the amplifier; n is an integer. 19. The device according to 17, characterized in that the Converter (RA) of the current pulses serves as a magnetic applicator.