ITUA20164049A1 - Procedure and device for the application of weak electromagnetic fields to people, animals or microorganisms in order to obtain biological effects on them. - Google Patents

Description

Procedure and device for the application of electromagnetic fields of low intensity to people, animals or microorganisms in order to obtain biological effects on them.

Summary

The new invention consists of a method and relative device suitable for making the application of the electromagnetic field of low intensity to humans, animals or microorganisms simple and economical (for example by simplifying the electronic equipment that generates the electromagnetic field), and more adhering to the theory underlying most electromagnetic treatments (cyclotron ion resonance), and therefore with more controllable and reproducible effects.

Description

State of the art

Since the discovery of the Electromagnetic Field (henceforth CEM) began to be accepted by the scientific community, efforts have been made to understand its biological effects (one of the very first experimenters: Galvani), and to exploit these effects for practical purposes ( Bassett, Liboff, etc.). To date, the biological mechanism of action of weak EMFs is not completely known, but nevertheless, like other medical devices with a little known mechanism of action (especially medicines), EMFs are widely used in the biological and medical sectors. There are many theories that try to explain the mechanism of the biological action of weak EMFs. Among these, the most accredited is that of Liboff's Cyclotronic Ion Resonance (hereinafter ICR), which takes into account, like many others, the intensity of the Earth's Magnetic Field, which, as we know, can be represented with a continuous value. or at the most slowly variable. In detail, the ICR provides that each ionic species, immersed as it is in the Earth's Static Magnetic Field (of B0 value), has a resonance frequency that depends on the mass m of the ion itself, on its charge Zie and on the B0 value, according to the relationship:

1) Resonance frequency = B0 (Zi / 2pi m) In fact, the excitation of the ion by means of a CEM of frequency equal to that of the relation 1), also known as Cyclotron Frequency, induces a resonance that makes the ion in some way more reactive itself, and therefore more capable of biological action.

Having said this, some aspects of the current industrial realizations in the sector are highlighted below, which we intend to deal with with the new invention.

A) The EMC generation systems produce a current which is translated by the applicator (coil) into an electromagnetic field. This current is alternating but generally, unless appropriate circuit arrangements, which at very low frequencies may also not be trivial, has a non-zero average value, that is, it has a continuous component that generates a continuous magnetic field, which overlaps the terrestrial one. alters the B0 value of relation 1) in the applicator area, making the calculation of the cyclotron frequency fallacious.

B) Empirical practice has shown that if the CEM supplied, normally conceived according to the ICR (substantially the resonance frequencies of certain ionic species, such as Calcium, Sodium, Potassium, are supplied, and therefore the frequencies used are quite low, in the order of tens of Hz), a high frequency component is superimposed (usually tens of KHz), the effectiveness of the treatment is increased (see patent number 0001350305 of 2004 in the name of the applicant, this new invention, in which said high frequency component was added during the generation of the electromagnetic signal, sometimes causing saturation problems).

C) To obtain a good field uniformity it is necessary to use applicators (coils) with a high number of turns. This is equivalent to using conductors with a reduced section (in order not to worsen weight and handling), and therefore with a relatively high ohmic resistance: the generation circuit must therefore resort to higher voltages to make the load (applicator) absorb the current necessary to obtain the intensity of EMF desired. This collides with the need to maintain low voltages dictated by the regulations relating to the safety of electro-medical devices. Therefore, unless special safety precautions are taken, the intensity of the field is limited.

With this new invention it is possible both to eliminate the fallacies of the calculation of the cyclotron frequency highlighted in A), and to introduce a further frequency component in the treatment delivered as explained in B) without having to act on the generator (eliminating the possible onset of saturation phenomena ), and, if necessary, to increase the intensity of the EMF delivered, without resorting to stages with voltages that would make electromedical certification more complicated, as mentioned in C).

Description of the finding

All devices that radiate CEM use an applicator (coil), or even more than one, connecting them in series / parallel to each other, to optimize some characteristics of the field, such as intensity or uniformity. What always happens, both in the case of a single applicator and of several applicators variously connected to each other, is that the signal, that is the power supply current, is unique both in the case of a single applicator and of several applicators variously connected to each other. With the present invention, on the contrary, the applicators (which are two or more) are fed with signals, ie currents, with different characteristics and therefore information, in order to obtain multiple effects.

In figure 1, the number 1 indicates a traditional applicator (coil), represented by a single flat winding of conductors (often gathered in "flat cable"), of suitable size, number of turns and shape to irradiate uniformly the person, the animal or the culture of microorganisms (as foreseen for example in patent number 0001350306 of 2004 in the name of the depositor of this new invention); number 2 indicates by way of example a person positioned on said winding of the traditional type.

Figure 2 shows the new invention, with the number of applicators limited to two, for simplicity of visualization: the number 3 indicates a flat winding, within which a current I1 is made to flow and with the number 4 a second winding, in which a current I2 is made to flow.

The two windings are identical, have suitable dimensions, such that each one can irradiate the subject of the treatment in a uniform way, and are superimposed but offset from each other.

The effects obtainable with the new invention are the following.

Effect 1: by supplying the first of the applicators with the alternating signal of average value other than zero necessary to obtain the desired CEM, and the second applicator with a direct current of the appropriate direction, the effect of the average value of the CEM emitted by the first applicator, obtaining to be able to accurately calculate the Cyclotron Frequency of a given ionic species since the emitted CEM can be considered as having a null average value.

Effect 2: powering all the applicators with different generators, but in phase and with the same signal, it is possible to increase the field without having to resort to a single generator operating with voltages that can be problematic for compliance with safety standards ( typically: CE “Low Voltage” legislation). Effect 3: switching the signal between the various applicators so that they irradiate the CEM alternately, a sort of "electromagnetic massage" is obtained, which actually consists in superimposing an additional signal on the CEM signal, with the advantage described here under.

Classically, the composition of two waveforms of different frequencies is referred to as modulation, and consists of the multiplication of the higher frequency wave (carrier) with that of lower frequency (modulating). Indicating the carrier with:

2) p (t) = A0cos ω0t,

and the modulating cyclotron frequency with:

3) m (t) = Amcos ωmt

it is obtained, by applying the modulating signal to the amplitude of the carrier, that the instantaneous value of the resultant can be expressed as:

4) s (t) = A0 cos ω0 t k Am / 2 cos (ω0 - ωm) t k Am / 2 cos (ω0 ωm) t The relation 4) is represented in figure 3, where it can be seen graphically that the CEM is constituted by carrier, indicated with the number 5, and by two side bands indicated 6 and 7. In other words, the frequency representation highlights the limit of this method: in fact, not only the energy is largely dispersed in the side bands, instead of being used on the Cyclotron Frequency, but also the Cyclotron Frequency actually disappears, being translated by the carrier. The advantage obtained with the new method is evident by viewing the frequency distributions obtained with it with figure 4), in which 8 indicates the cyclotron frequency and 9 indicates the switching frequency between the various applicators: in fact a considerable part of energy is exactly delivered on the freq. cyclotron 8, and not dispersed in lateral bands far from the cyclotron, as is the case with the modulation method. The circuit that obtains what has been described (simplified in the case of 2 applicators) is now represented in figure 5, where 10 represents an CEM generator, built with the usual techniques, 13 and 14 the applicators (coils), i.e. the devices that irradiate the CEM, 12 the devices that alternately switch the signal between the applicators, driven by 11.

Typical implementation

In a preferred embodiment there are two applicators, made as in figure 2, of such dimensions as to completely irradiate a human figure of average height, with the switching between the applicators operated as in figure 5, with a period of 0.5 seconds.

A further preferred embodiment always uses two applicators, in one of which a current is introduced such as to produce a CEM with an average intensity of 10 microTesla in the immediate vicinity of the applicators, while in the other a direct current equal in absolute value to the average value is introduced. of the first, but in the opposite direction: in this way a CEM of null average value is obtained in the immediate vicinity of the applicators, allowing a rigorous calculation of the Cyclotron Frequency according to relation 1).

Claims (1)

Claims 1) Electromagnetic Field Applicator consisting of two or more flat windings adjacent but offset from each other, with shape and size such that each of them is able to irradiate with the desired intensity and field uniformity the object of the treatment (human, animal, microorganism or thing), where the current necessary to produce the desired Electromagnetic Field is circulated in one winding at a time, switching serially between one winding and the next in a time between 1 Second and 1 microSecond; 2) electromagnetic field applicator consisting of two or more flat windings adjacent but offset from each other, with shape and size such that each of them is able to irradiate the object of treatment with the desired intensity and uniformity of the field (human, animal, microorganism or thing), where the current necessary to produce the desired electromagnetic field is circulated only in a part of the windings (at least one winding), while in the remaining windings (at least one winding) a direct current of an appropriate sign of such value as to cancel the continuous average component of this electromagnetic field; 3) electromagnetic field applicator made with two non-flat windings in which the current necessary to produce the desired electromagnetic field is circulated in one winding at a time, switching between one winding and another in a time between 1 second and 1 microSecond, in the same way as 1); 4) as in 1) or 2), where the direct current circulating in part of the windings (at least one) is such as to cancel the continuous magnetic component of the environment; 5) Electromagnetic Field applicator consisting of two or more flat windings adjacent to each other, with shape and size such that each of them is able to irradiate the object of treatment with the desired intensity and uniformity of the field (human, animal, microorganism or thing), where the windings are driven in phase and with the same signal, each by a different generator, in order to increase the maximum intensity of the electromagnetic field.