PL194547B1 - Method of and apparatus for activating ions transport - Google Patents

Abstract

A method of ion transport activation through cell membranes and capillary walls of living organisms consists in an influence of pulsed very low frequency electromagnetic field, generated by electric current pulses. Two types of signals are used, as well as their combinations in a form of consecutive packets, packet groups, packet group series, packet group series sets and combinations of packet group series, for a purpose to create simultaneous magnetomechanical and electrodynamic influence on ions of different elements, giving rise to ion cyclotron resonance. An apparatus for ion transport activation contains control and supervision panel (PS) connected to infrared radiation receiver (IR) remotely controlled from remote infrared radiation transmitter (P). A control and supervision panel (PS) is connected to a microprocessor control unit (MUS) containing RAM memory and non-volatile EEPROM memory. Microprocessor control unit (MUS) is connected - by voltage amplifier (W), symmetrical current source (IS) and execution circuit (UW) - to current pulse-to-magnetic signal converter (PA).

Description

Description of the invention

The subject of the invention is a device for activating the transport of ions, in particular through the cell membranes and capillary walls of living organisms.

A method and a device for transporting ions across cell membranes is known from the European patent application EP 0 407 006. The presented method consists in the simultaneous activation of the transport of selected ions of two different elements, especially Ca and Mg ions through the use of cyclotron magnetic resonance. The interaction of the signals of a homogeneous magnetic field of very low frequencies generated by current sinusoidal electric pulses with an average value greater than zero is applied, the field lines being parallel to the axis in which the area of the living organism is located. Sinusoidal electrical impulses cause changes in the magnetic flux density with the cyclotron resonance frequency determined by the relationship fc = Bq / 2 π m, where f _c - the frequency of the magnetic field vibrations in Hz q / m - the ratio of the charge to the mass of the ion in C / kg B - average value flux densities along the axis in Tesla

The device for applying the method according to the patent application comprises a generator of sinusoidal electric pulses connected to a DC system of a certain value and an amplifier, the outputs of which are controlled by a switch cooperating with a pair of Helmholtz coils, constituting a converter of electric pulses into magnetic signals.

In another solution, presented in European patent EP 0 594 655, an ion transport device is described, which consists of a control panel connected to a microprocessor control system and further through an amplifier with a transmitting coil that converts current pulses into magnetic signals. The control system includes a microprocessor, a timing generator, a memory, an address generator, and an analog-to-digital converter. The generator produces low frequency current pulses and is connected to the transmitting antenna. The antenna's electromagnetic field covers the area of the body that is to be treated. The device transports ions, in particular protons, from the intracorporeal electrolytic fluids to and through the walls of the vessels and the membranes surrounding them. Transport consists in sending a specific energy at a sufficiently high level such that an induced energy is generated in the electrolytic fluid that is higher than the thermal energy so that it falls within the range of the characteristic amplitude cellular window. The current pulses are produced by a generator in a transmitting coil, which is typically designed to be low-inductive. A fundamental current pulse consists of a square wave, superimposed on an exponentially increasing waveform, followed by a pause at least as long as the pulse duration. The pulses together with the pauses create a wave with a frequency of 100 Hz to 1000 Hz. The amplitude of the pulses is modulated with a frequency of 0.5 Hz to 35 Hz, and the modulation envelope forms a close-to-isosceles triangle. The modulated sequence of basic pulses emitted without changing the polarity creates a series with a duration of 0.3 sec. up to 1 sec., followed by a pause of 0.7 sec. up to 5.0 sec. The series of pulses are converted into alternating magnetic field signals which cause electrodynamic and magnetomechanical effects on ions, especially protons, causing them to be transported across cell membranes.

According to the invention, the device for activating the transport of ions through the cell membranes and capillary walls of living organisms by the interaction of pulsed electromagnetic field signals of very low frequencies from 10 Hz to 1000 Hz, includes a control and monitoring panel with a pilot, connected to a microprocessor control system with a current pulse generator and memory. The microprocessor control system is connected with a symmetrical current source through a two-stage binary-controlled voltage amplifier and further with the switching actuator. The executive system controlled directly from the control system is connected with a converter of current pulses into electromagnetic signals and with the equivalent load. The converter of current pulses into electromagnetic signals in the form of a magnetic applicator comprises at least one electromagnetic coil generating a non-uniform magnetic field. The control and monitoring desk is connected with an infrared radiation receiver controlled by a remote control. The microprocessor control system comprises a memory, preferably

PL 194 547 B1 type of RAM for direct control and an additional non-volatile EEPROM memory for external programming of device functions, the RAM type memory containing two types of current signal shapes and their connection in the form of consecutive packages, groups of packages, series of package groups, bundle group series harvest, bundle group series series harvest combination. The EEPROM non-volatile memory contains ready-made programs for sets of combinations of signal connections into packages, groups of packages, series of groups of packages, sets of series of groups of packages, taking into account time dependencies and changes in amplitude.

In turn, the binary-controlled voltage amplifier contains a system of two operational amplifiers. The input of the voltage amplifier is connected directly to the non-inverting input of the first op-amp and through a resistor to the inverting input of the second op-amp. This amplifier together with the four resistors constitutes a differential amplifier with a non-inverting input connected to the output of the first operational amplifier. In turn, between the ground and the inverting input of the first operational amplifier, branches of series key connections with resistors are connected in parallel. These branches are located in the negative feedback circuit of the first operational amplifier. The output of the voltage amplifier is also the output of the second operational amplifier. The output voltage of the voltage amplifier varies depending on the attached keys according to the formula:

n

Uwy = Uwe · Σ ^2n_1 for n> 1 and Uwy = 0 for n = 0, where Uwy is the output voltage of the amplifier,

Uwe - amplifier input voltage

Two types of signals produced in the pulse generator have characteristics of changes in induction B as a function of time B = f (t) in the shape of two different broken lines with waveforms increasing from zero to Bmax.

The characteristic of the first type of signal has the shape of a broken line, formed by seven segments with a total duration from 3.0 msec. up to 9.4 msec. In the first segment, the induction increases linearly from zero to 1/3 Bmax over time from 0.5 msec. up to 1.6 msec. In the second segment parallel to the t axis, the induction is maintained at 1/3 Bmax from 0.5 msec. up to 1.2 msec. Then, in the third segment, it increases linearly from 1/3 Bmax to 2/3 Bmax over 0.4 msec. up to 1.5 msec. and in the fourth segment parallel to the t axis, the induction is maintained at 2/3 of Bmax in 0.1 msec. up to 0.5 msec. Finally, in the fifth segment, the induction increases linearly to the Bmax value over 0.5 msec. to 1.5 msec, and then in the sixth segment almost perpendicular to the t axis, the induction drops sharply to zero in 0.1 msec or less. and remains at zero for 0.5 msec. up to 1.5 msec. on the seventh episode.

In turn, the characteristic of the second type of signal has the shape of a broken line formed by five segments with a total duration of 5.0 msec. up to 9.4 msec. and a course wherein the first segment increases the induction linearly to a value of 1/2 Bmax from 0.7 msec. up to 1.3 msec. In the second segment parallel to the t axis, the induction is maintained at the previously achieved value of 1/2 Bmax for 1.8 msec. to 2.8 msec, then in the third segment, the induction increases linearly to 1/2 Bmax from 0.5 msec. down to 1.2 msec, and then in the fourth segment almost perpendicular to the t axis, the induction sharply drops to zero, in 0.1 msec at most. and remains at zero for 1 msec. up to 2 msec. on the fifth episode.

The values of induction B of both types of signals do not exceed the effective value of Bsk = 100 μΤ, and its linear increase presented in the characteristics B = f (t) with sections inclined towards the t axis causes mainly electrodynamic and magnetomechanical effects. On the other hand, the induction maintained at the level of 1/3 Bmax, 2/3 Bmax and 1/2 Bmax presented on the characteristics B = f (t) with segments parallel to the t axis causes mainly ionic cyclotron resonance, the frequencies f _c for ions of various elements are the frequencies of the variable magnetic field. The ratio of these frequencies to the induction B of the alternating magnetic field is equal to the ratio of the electric charge of the ion of a given element to its mass.

PL 194 547 B1

The RAM memory of the microprocessor control system contains both types of signal packs. Each burst consists of a series of consecutive single signals of a given type and a break, but the pause time between consecutive bursts of signals of the first kind is greater than the pause time between bursts of signals of the second type. Most often, packets contain four signals of the first type and five signals of the second type. The duration of a burst of signals of the first type is from 10 msec. up to 50 msec., pause time 40 msec. up to 60 msec.

In turn, the duration of a burst of signals of the second type is from 20 msec. up to 30 msec., and the pause time between packets is from 20 msec. up to 50 msec.

The RAM memory of the microprocessor control system contains groups of packets of signals of both kinds. Each group consists of a series of signal packs of a given type and break. The duration of the group of packets of signals of the first type is from 250 msec. up to 400 msec., and the pause time is from 40 msec. up to 60 msec.

The duration of the group of packets of signals of the second type is from 140 msec. to 300 msec., and the interval between packets is from 80 msec. up to 200 msec. Preferably, the first type signal packet groups contain at least five each and the second type signal packet groups contain at least four packets.

The RAM also includes bundles groups into series, series into sets, and then harvest into combinations.

The current pulse transducer is a magnetic applicator of both types of signals, signal packets, groups of signal packets, a series of signal packets groups, sets of a series of signal packets groups, a combination of sets of a series of signal packets and / or ready programs, sets of combinations of sets of a series of signal packs control system. Each series of groups of signal packets of both kinds consists of a series of groups of signal packets of the given type and break. The duration of a series of packets of signals of the first type is from 7 sec. up to 10 sec., and the pause time is from 3 sec. up to 4 sec. The duration of the series of packets of the second type of signal packs is from 5 sec. up to 9 sec., and the break between sets is 2 sec. up to 4 sec.

Typically, the series of the first kind of signal packet groups comprises twenty to twenty-six groups, preferably twenty-four groups, and the series of the second kind signal packet groups comprises twenty to twenty-four groups, preferably twenty-two groups. Each set of a series of signal packet groups of both kinds consists of a series of signal packet groups of a given type. The duration of the set of a series of bundles of the first and second kind signals ranges from 90 sec. up to 240 sec. The set of a series of groups of signal packets of a given type has positive and negative polarity, usually alternating. Preferably, the plurality of the series of the first type signal packet groups consists of at least ten series, and the plurality of the series of the second type signal packet groups consists of at least twelve series.

In the sets of series of groups of signal packets of both types, the signal amplitude is at a certain level not exceeding the effective value Bsk = 100 μΓ and / or it changes abruptly in the increasing direction in successive series.

Most often, the combinations of the sets of the first and second kinds of signal packet group series contain at least two sets of the first kind of signal packet group series followed by at least two sets of the second kind of packet group series.

Adjacent sets have polarization with opposite signs. The signals generated by the device according to the invention cause a simultaneous magnetomechanical and electrodynamic effect on ions of various elements, causing ion cyclotron resonance of the ions of these elements in the cells of living organisms.

As a result of the electrodynamic influence of the magnetic field on a biological system in the shape similar to a cylinder, an electric field is induced with the intensity E depending on the rate of change of induction dB / dt and is expressed as r dB 2 dt where r is the radius of the cylinder.

PL 194 547 B1

The resulting field E, varying in time, produces inductive ion currents of intensity density j according to the equation j = δο · E where do is the specific conductivity of a biological system.

At current densities greater than 10 mA / m ² , changes in carbohydrate and protein metabolism occur, as well as changes in the permeability of lipid cell membranes, thus facilitating the transport of ions through cell membranes.

The phenomenon of ionic eddy currents is related to the effect of ion cyclotron resonance. The frequency of ion cyclotron resonance, both circular c and linear f _c = ω ₀ / 2π, depends on the induction B of the magnetic field in a given place of a living organism and the ratio of the charge q to its mass m, according to the formula:

w = 2π f _c = B

The magnetomechanical influence on the biological system consists in generating the magnetomechanical force F which causes the movement of particles and atoms with uncompensated spins.

The magnetomechanical force F is caused by the magnetic field induction gradient B and is expressed by the equation:

_F (μ -1) V. dB. _B μ ₀ ^dx

Where V is the volume of uncompensated spins μ - relative magnetic permeability of a biological system mo - magnetic permeability of vacuum

The device for activating the ion transport, equipped with a microprocessor control system connected to the amplifier and converter through a symmetrical current source, enables the generation, amplification and transmission of two signals with characteristic waveforms causing the simultaneous occurrence of three types of electrodynamic interaction, magnetomechanical and ion cyclotron resonance. The device increases the amount of transported ions of a given element, as well as extends the range of types of elements whose ions are transported. The possibility of creating combinations of signal connections into packages, package groups, series of package groups, sets of series of package groups with the possibility of changing the duration and amplitude allows for quantitative and qualitative regulation in a wide range of transported ions by changing the share of individual types of magnetic field influence. The equipment of the microprocessor control system with RAM memory allows for direct selection from the control panel of a combination of signal connections of both types into packages, package groups, series of package groups, sets of series of package groups with the adjustment of duration and amplitude changes. The introduction of additional EEPROM memory to the microprocessor control system makes it possible to select and enable ready-made sets of signal connection combinations, taking into account the duration and amplitude changes.

A significant advantage of this solution is the ability to remotely turn on the device without exposing the operating personnel to long-term effects of the magnetic field.

Moreover, thanks to equipping the device with an executive system with equivalent load, it is possible to simulate the device operation.

The invention is explained in more detail in the embodiment of the device in the drawing, in which fig. 1 shows the device for activating the ion transport in a block diagram, fig. 2 voltage amplifier in a schematic diagram, fig. 3 - characteristics of changes in induction B as a function of time of a signal of the first type, Fig. 4 - characteristics of changes in induction B as a function of time of the second type of signal, Fig. 5 - characteristics of changes in induction B as a function of time for a bundle of four signals of the first type, Fig. 6 - characteristics of changes in induction B as a function of time for a bundle of five signals of the second type , fig. 7 - characteristics of changes in induction B as a function of time for a group of five packets of signals of the first type, fig. 8 - characteristics of changes in induction B as a function of time for

Fig. 9 - characteristics of changes in induction B as a function of time for a series of twenty-four groups of packets of signals of the first type, Fig. 10 - characteristics of changes in induction B as a function of time for a series of twenty-two groups of signal packets the second type, Fig. 11 - characteristics of changes in induction B as a function of time for two sets, each for fifteen series of groups of packets of signals of the first type, Fig. 12 - characteristics of changes in induction B as a function of time for two sets, each for twelve series of groups of packets of signals of the second type 13: characteristics of changes in induction B as a function of time for two sets, each for ten series of packet groups of signals of the first kind, Fig. 14 - characteristics of changes in induction B as a function of time for two sets, each for eighteen series of packet groups of signals of the second kind Fig. 15 shows the change of induction B versus time for program I, which is a combination of two sets of the series of packets of the first kind of signal packets with two sets of the series of packet groups of the second kind of signals, Fig. 16 - characteristics of the changes of induction B as a function of time for program II, which is a combination of two sets of the series of packets of the second kind of signals with two sets of the series of packets of the first kind Fig. 17 - the characteristics of changes in induction B as a function of time for program III, which is a combination of two sets of the series of packet groups of signals of the second kind and two sets of the series of packet groups of signals of the first kind with an amplitude incrementally increasing in each set, Fig. 18 - characteristics of induction changes B as a function of time for program IV, which is a combination of two sets of the series of packets of the first kind of signals and two series of packets of the second kind of signals with an amplitude increasing abruptly in the first set and decreasing abruptly in the last set.

The device for activating the ion transport shown in Fig. 1 consists of a control and control PS console containing control buttons and indicator lamps, connected to a microprocessor control system MUS with a generator and RAM memory, EEPROM, and further to the amplifier W. connected through a symmetrical current IS source and the UW executive circuit with a PA converter and a PL equivalent load. The UW executive system is directly connected to the microprocessor-based MUS control system. The control and monitoring PS panel is connected with the IR receiver of infrared radiation controlled by the P remote control. The microprocessor control system MUS includes RAM memory for direct control and additional non-volatile EEPROM memory for external programming of device functions. The RAM memory contains two types of current signal shapes, the order of their occurrence, combinations of connections into packets, packet groups, packet group series, sets of packet group series, taking into account time dependencies and amplitude changes. EEPROM non-volatile memory contains ready-made programs for sets of combinations of sets of series of packets, taking into account time dependencies and changes in amplitude.

In turn, the voltage amplifier W shown in Fig. 2 comprises a system of two operational amplifiers W1 and W2. The voltage amplifier input WE is connected directly to the non-inverting input (+) of the first operational amplifier W1 and through a resistor R1 to the inverting input (-) of the second operational amplifier W2. The operational amplifier W2 together with the four resistors R1 constitutes a differential amplifier with a non-inverting input (+) connected to the output of the first operational amplifier W1. In turn, between the ground and the inverting input (-) of the first operational amplifier W1, branches of series connections of the keys K1, K2, K3 ... Kn with resistors R, R / 2, R / 4 ... R / 2 ^{n 1 are connected in parallel.} . These branches are located in the negative feedback circuit of the first operational amplifier W1. The output of the voltage amplifier W is also the output of the second operational amplifier W2. The voltage Uwy, the voltage amplifier W changes depending on the attached keys K1, K2, K3 ... Kn according to the formula:

n

Uwy = Uwe £ 2n-1 for n £ 1 and Uwy = 0 for n = 0 where Uwy is the output voltage of the amplifier W, Uwe - the input voltage of the amplifier W

PL 194 547 B1

The device starts up after selecting the program and activating the buttons on the desktop

PS or in the P remote control. The device produces two types of signals which have characteristics of changes in induction B as a function of time t in the form of two different broken lines.

For the first type of signal, the broken line shown in FIG. 3 is made up of seven sections a, b, c, d, e, f, g and duration T ₁ = 5.33 msec.

On the segment a with a duration of t1 = 1.2 msec. the induction increases linearly from zero to 1/3 Bmax = 30 mT and remains at this value for t2 = 0.8 msec. on segment b. Then, on segment c, it increases linearly to the value of 2/3 Bmax = 60 mT at time t3 = 1.0 msec. and it is held at this value for the time t ₄ = 0.3 msec. on the section d.

In turn, on the segment e, the induction increases linearly to the value of Bmax = 90 mT at time t ₅ = 0.95 msec., And then on the segment f it drops sharply to zero at te = 0.08 msec. and remains at zero along the segment g for the time ty = 1 msec.

For the second type of signal, the broken line shown in FIG. 4 is made up of five sections k, 1, m, n, r with a duration of T2 = 5.53 msec.

On the segment k with duration L = 0.9 msec. the induction increases linearly from zero to 1/2 Bmax = 40 mT, for which it remains for t2 = 2.3 msec. on the section l.

It then increases linearly to Bmax = 80 mT at t3 = 0.75 msec. on the distance m, and then rapidly drops to zero at t = 0.08 msec. on the segment ni, it remains at the zero value on the segment r for the time t ₅ = 1.5 msec.

The linear increase in induction presented on the characteristics by the segments a, c, e for the signals of the first kind and by the segments k, m for the signals of the second kind mainly causes electrodynamic and magnetomechanical effects. On the other hand, the induction maintained on the b, d sections at the values B = 30 mT and B = 60 mT for the first type signal and on the l section at the B = 40 mT value for the second type signal causes mainly ion cyclotron resonance, the frequency of which f _c for different ions elements are equal to the frequencies of an alternating magnetic field. The ratio of these frequencies fc to the induction B of an alternating magnetic field is equal to the ratio of the electric charge q of the ion of a given element to its mass m

- ^Mr. _ q_

B mf _c = - B

2p m

The frequencies of fc ion cyclotron resonance for selected ions of body fluids in living organisms depending on the induction of an alternating magnetic field are presented in Table 1.

Table 1

lon B [ ^m T] H + Li + N ^{a +} Mg + Cl ' K + C ^a ++ 10 152 2.2 6.6 12.6 4.3 3.9 7.7 twenty 304 4.4 13.2 25.2 8.7 7.8 11.3 thirty 456 6.6 19.8 37.8 12.9 11.7 23.1 fc (Hz) 40 680 8.8 26.4 50.4 17.2 15.6 30.8 50 760 11.0 33.0 63.0 21.5 19.5 38.5 60 912 13.2 39.6 75.6 25.8 23.4 46.2

In turn, Table 2 shows the ratio of the electric charge q to the ion mass m for the elements in Table 1.

PL 194 547 B1

Table 2

lon H + Li + N ^{a +} Mg + Cl ' K + C ^a ++ m kg 95.6 1.39 4.19 7.92 2.7 2.46 4.81

The signal packet of the first type shown in Fig. 5 consists of four consecutive signals with a total duration Tp ₁ = 21.32 msec. and pause tp ₁ = 50 msec.

The signal packet of the second type shown in Fig. 6 consists of five signals with a total duration Tp2 = 27.65 msec., And an interval tp2 = 35 msec.

The group of signal packets of the first type shown in Fig. 7 includes five packets of four signals each. Duration of the pack group is Tg1 = 306.6 msec., And the gap between groups of packages _S is T 1 = 50 ms.

The group of signal packets of the second type shown in Fig. 8 includes four packets of five signals each. The duration of this batch group is T _S 2 = 215.6 msec and the interval is t _S 2 = 130 msec.

The series of signal packet groups of the first type shown in Fig. 9 includes twenty-four groups of five packets. The series duration is Ts1 = 8.5 seconds, and the interval between series is ts1 = 3.5 seconds.

The series of the second type of signal packet groups shown in Fig. 10 includes twenty-two groups of four packets with a total duration of Ts2 = 7.5 sec., And the pause is ts2 = 2.5 sec.

The set of series of first kind signal packet groups shown in Fig. 11 comprises fifteen series of twenty-four groups. The harvest time is T _Z 1 = 3 minutes. Successive sets have alternately positive and negative polarity.

The set of series of groups of second kind signal bundles shown in Fig. 12 comprises twelve series of twenty-two groups. The harvest time is Tz2 = 2 minutes. In subsequent sets, positive and negative polarization alternately occur.

The set of a series of first kind signal bundle groups shown in Fig. 13 comprises ten series of twenty-four groups. The harvest time is Tz1 = 2 minutes. In subsequent sets, there is alternately positive and negative polarization.

The set of series of groups of second kind signal bundles shown in Fig. 14 comprises eighteen series of twenty-two groups. The harvest time is Tz2 = 3 minutes. In subsequent sets, positive and negative polarization alternately occur.

Program I, shown in Fig. 14, with a duration of 10 minutes, combining two sets of a series of packet groups of signals of the first type having a duration of two times for three minutes and two sets of series of packet groups of signals of the second type of signals having a duration of two times for two minutes. Adjacent sets have polarization with opposite signs.

Program II shown in Fig. 16 with a duration of 10 minutes. it is a combination of two sets of a series of packet groups of signals of the second type with a duration of two times three minutes each and two sets of a series of packet groups of signals of the first type having a duration of two times two minutes each. Adjacent sets have polarization with opposite signs.

Program III, shown in Fig. 17, having a duration of 12 minutes, is a combination of two sets of the second kind signal pack group series and two sets of the first type signal packet group series.

The duration of sets of signals of the second type is six minutes, of which one set contains twelve series and lasts two minutes, and the next set contains twenty-four series and lasts four minutes.

The duration of sets of signals of the first type is six minutes, of which one set contains twenty series and lasts four minutes, and the next set contains ten series and lasts two minutes.

In this program, the amplitude of each series changes stepwise in the cycle from the minimum induction value to the given value of Bsk, and then the cycle repeats in all sets.

PL 194 547 B1

Program IV, shown in Fig. 18, having a duration of twelve minutes, is a combination of two sets of a series of first type signal pack groups and two series of second type signal pack groups.

The duration of sets of signals of the first type is six minutes, of which one set contains ten series and lasts two minutes, and the next set contains twenty series and lasts four minutes.

The duration of sets of signals of the second type is six minutes, of which one set contains twenty-four series and lasts four minutes, and the next set contains twenty series and lasts two minutes.

In the program under discussion, in the first set, the series amplitude changes abruptly from the minimum induction value to 0.8 Bsk. In the middle sets, the series amplitude is constant and amounts to Bsk. However, in the last set, the series amplitude changes from 0.8 Bsk to the minimum induction value.

The operation of the device is based on the fact that the MUS microprocessor control system produces two types of pulses and their connections into packages, package groups, series of package groups, sets of series of package groups, combinations of sets of series of package groups and ready-made programs stored in digital form in RAM and EEPROM. The waveform amplitude is regulated by a binary-controlled voltage amplifier W. The voltage amplifier W controls the symmetrical current IS source, which enables contactless switching of the polarity of the pulses transmitted to the PA converter via the UW executive system operating in the basic position. In the PA transducer, current pulses are converted into signals of an alternating magnetic field affecting a living organism.

In the conditions of simulating the operation of the device, the UW actuator system in the second position is connected with the equivalent load PL. The device is started after selecting the program and pressing the buttons on the PS control panel or in the P remote control.

Claims (8)

Patent claims 1. A device for activating the transport of ions through the cell membranes and capillary walls of living organisms by the interaction of pulsed electromagnetic field signals of very low frequencies from 10 Hz to 1000 Hz, including a control and monitoring panel with a pilot, connected to a microprocessor control system with a current pulse generator and memory and further via a two-stage amplifier with a converter of current pulses into electromagnetic signals, characterized in that the microprocessor control system (MUS) comprises memory preferably of the RAM type for direct control and an additional non-volatile memory of the EEPROM type for external programming of the device functions, the RAM type memory comprising shapes of current signals of two types and their combination in the form of consecutive packages, groups of packages, series of package groups, sets of series of packages groups, combinations of sets of series of groups of packages for simultaneous magnetomechanical interaction and el ectrodynamics on ions of various elements with the induction of ionic cyclotron resonance of the ions of these elements, and both types of signals produced in the pulse generator have characteristics of changes in induction B as a function of time B f (t) in the shape of two different broken lines with waveforms increasing from zero to the Bmax value of from 60 μΓ to 120 μΤ, but the characteristic of the first type of signal has the shape of a broken line, formed by seven segments (a, b, c, d, e, f, g) with a total duration (T1) of 3.0 msec . up to 9.4 msec, in which the induction increases linearly from zero to 1/3 Bmax on the first segment (a) and remains at this value on the second segment (b) parallel to the axis (t), and then on the third segment (c) increases linearly from 1/3 Bmax to 2/3 Bmax and remains at this value on the fourth segment (d) parallel to the (t) axis, and finally increases linearly along the fifth segment (e) to Bmax, after which abruptly drops to zero on the sixth segment (f) almost perpendicular to the axis (t) and remains zero on the seventh segment (g), preferably the time (t Duration on the first segment (a) is from 0.5 msec. , 6 msec., Time ¢ 2) of the signal duration on the second segment (b) is from 0.5 msec. up to 1.2 msec., time ¢ 3) of the signal duration on the third segment (c) is from 0.4 msec. up to 1.5 msec., time ¢ 4) of the signal duration on the fourth segment (d) is from 0.1 msec. up to 0.5 msec., time ¢ 5) of the signal duration on the fifth segment (e) is from 0.5 msec. up to 1.5 msec., the signal duration (t.-,) on the sixth segment (f) is at most 0.1 msec., and the signal duration (ty) on the seventh segment (g) is from 0.5 msec. . to 1.5 msec., in turn, the characteristic of the second type of signal has the shape of a broken line formed by five sections (k, l, m, n, r) with a total duration (T2) of 5.0 msec. up to 9.4 msec. and the course in which on the first segment (k) ind10 The increase linearly to the value of 1/2 Bmax, where it remains on the second segment (l) parallel to the axis (t), and then increases linearly from the value of 1/2 Bmax to Bmax on the third segment (m), after which abruptly drops to zero on the fourth segment (n), almost perpendicular to the axis (t) and remains at zero on the fifth segment (r), preferably the time (t Duration on the first segment (k) is from 0.7 msec. to 1.3 msec., And _{the signal duration (t 2} ) on the second segment (l) is from 1.8 msec. To 2.8 msec., The signal duration (t) on the third segment (m) is from 0, 5 msec. To 1.2 msec., The _{signal duration time (t 4} ) on the fourth segment (n) is at most 0.1 msec., And _{the signal duration (t; i} ) on the fifth segment (r) is from 1 msec. to 2 msec., and the values of induction B of both types of signals do not exceed the effective value of Bsk 100 μΓ, while the linear increase in induction B is represented by the segments (a, c, e) and (k, m) inclined to the axis (t) of the characteristics signals of both kinds mainly causes electrodynamic and magnetomechanical effects, while induction B maintained at 1/3 Bmax and 1/2 Bmax, presented with segments (b, d) and (l) parallel to the (t) axis, causes mainly ion cyclotron resonance, and non-volatile memory of the EEPROM type contains ready-made programs of sets of combinations of sets of series of package groups created from combinations of signals into packages, package groups, series of package groups, sets of series of package groups, taking into account time dependencies and changes in amplitude, while the binary-controlled voltage amplifier (W) is connected to a symmetrical source (IS) current and further with a switching executive system (UW) controlled directly from the control system (MUS) and connected to the transducer (PA) and the equivalent load (PL), the voltage amplifier (W) includes a system of two amplifiers (W1), (W2) operational, and the input (WE) of the voltage amplifier (W) is connected directly to the non-inverting input (+) of the first amplifier (W1 ) and through the resistor (R1) to the inverting input (-) of the second operational amplifier (W2), which together with the four resistors (R1) constitute a differential amplifier with a non-inverting input (+) connected to the output of the first operational amplifier (W1), in turn between the ground and the inverting input (-) of the first operational amplifier (W1), branches of series key connections (K1, K2, K3 ... Kn) with resistors (R, R / 2, R / 4 ... R / 2) are connected in parallel ^{n 1} ) located in 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). 2. The device according to claim 1, characterized in that the voltage amplifier (W) has a voltage (Uwy) that changes depending on the attached keys (K1, K2, K3 ... Kn) according to the formula n Uwy = Uwe · Σ 2 ^M for n = 1 and Uwy = 0, where Uwy means the output voltage of the amplifier, Uwe - the input voltage of the amplifier, n - integer. 3. The device according to claim The method of claim 1, characterized in that the RAM of the microprocessor control system (MUS) comprises signal packs of both kinds, each consisting of a series of consecutive individual signals of a given type and a break, each packet of signals of the first type consisting of at least four time signals (Tp1) of duration from 10 msec. up to 50 msec. and the time (tp1) of a break from 40 msec. to 60 msec., in turn, the signal packet of the second type consists of at least five signals with a duration (T _g2 ) from 20 msec. up to 30 msec. and the time (t _g2 ) of a break of 20 msec. up to 50 msec., however, the interruption time (tp1) in the bursts of signals of the first type is greater than the _{interruption time (t g2} ) in bursts of signals of the second type. 4. The device according to claim 1 3. The method of claim 3, characterized in that the RAM of the microprocessor control system (MUS) comprises groups of signal packets of both kinds, each consisting of a plurality of signal packets of a given type and a break, the group of signal packets of the first type consisting of at least five packets. on time (T _g 0 duration from 250 msec. to 400 msec. and time (t _g 0 interruptions from 40 msec. to 60 msec., in turn, the group of signal packets of the second type consists of at least four time packets (T _g2 ) duration from 140 msec. to 300 msec. and time (t _g2 ) break from 80 msec. to 200 msec. 5. The device according to claim 1 4. The method of claim 4, characterized in that the microprocessor control system (MUS) RAM memory comprises a series of both types of signal packets, each consisting of a plurality of signal packet groups of a given type and a break, each series of signal packets of the first type comprises twenty up to twenty-six groups, preferably twenty-four groups with a duration (Ts1) of 7 sec. up to 10 sec. and the time (ts1) of a break from 3 sec. to 4 sec., in turn, the series of groups of signal packets of the second type comprises twenty to twenty four groups, preferably twenty-two groups with a duration (Ts ₂ ) of 5 sec. up to 9 sec. and the time (ts ₂ ) of a break from 2 sec. up to 4 sec. PL 194 547 B1 6. The device according to claim 1 5. The method of claim 5, characterized in that the RAM memory of the microprocessor control system (MUS) comprises sets of a series of groups of signal packets of both kinds, each of which consists of a series of groups of signal packets of a given type, with a duration (Tz1, Tz2) lasting from 90 sec. up to 240 sec., where the set of the series of packet groups of the first kind consists of at least ten series, the set of the series of packet groups of the second kind consists of at least twelve series, and the consecutive sets have alternating positive and negative polarity. 7. The device according to claim 1 6. The method of claim 6, characterized in that the RAM of the microprocessor control system (MUS) comprises combinations of first and second kind signal packet series sets consisting of at least two sets of a first kind signal packet group series followed by at least two sets of a packet group series of first type signals followed by at least two sets of a packet group series of signals of the first type signals of the second type, wherein the amplitude of the signals in the sets of a series of groups of signal packets of both kinds is constant and / or changes abruptly in successive series. 8. The device according to claim 1 7, characterized in that the transducer (PA) ir ^ | ^ i ^ l ^ c ^ \ wpir ^ (^ c ^ \ ^^ c ^ lh is a magnetic applicator of signals of both types, signal packets, signal packets groups, a series of packets groups signals, sets of a series of signal packs groups, combinations of sets of a series of signal packs groups and / or ready programs, sets of combinations of sets of a series of signal packs groups transferred from the memory of the microprocessor control system (MUS).