WO1995012430A1

WO1995012430A1 - Improvement to electromagnetotherapy apparatuses

Info

Publication number: WO1995012430A1
Application number: PCT/IB1994/000343
Authority: WO
Inventors: Guido P. Annoni Di Gussola
Original assignee: Annoni Di Gussola Guido P
Priority date: 1993-11-05
Filing date: 1994-11-04
Publication date: 1995-05-11
Also published as: AU7947994A

Abstract

Disclosed electromagnetotherapy apparatus comprises a generator of electromagnetic waves having a fundamental carrier frequency of the order of MHz, an LED (20) and a reverse diode (20a) to produce a frequency spectrum extending from a low frequency up to several GHz. The apparatus comprises an emitter part (11) comprising a spiral-shaped electrode (14) and a second electrode (18) situated at the center of the electrode (14), said second electrode (18) comprising a monofilament wire (18a) and a multifilament wire (18b) as well as a central portion (18c) connected in parallel with the multifilament wire (18b) and comprising a herring-bone patterned part.

Description

Advanced training in electromagnetotherapy devices

In 1900 the Russian doctor Danilewski studied the action of radio waves in cells and on the nervous system. This work was continued in France later by d'Arsonval.

In 1970, the French doctor Fellus noted that electromagnetic waves, among other effects, increase the electrical charge of cells. We know that in healthy living cells, there is a potential difference between the nucleus and the membrane, which is 90 mV for the cells of the nerve centers and 70 mV for the other cells. When the cells are sick, their energy reserve is reduced and the potential difference can fall to 55-50 mV; if this difference in potential drops below 30 mV, the cell dies. When the cells "discharge", like an electric battery, pain is felt in the organism (pain in the bones, in the joints, in the back, etc.).

By subjecting cells having undergone such a discharge to electromagnetic waves, their difference in potential can be brought back to normal, as Fellus had discovered. Depending on the case and the type of cells, treatment can take from a few days to several weeks. The result of this return to normal of the difference in cell potential is to make the painful inflammation of a joint or due to distortion disappear; rheumatism may go away after a few sessions, while that healing a fracture may require weeks.

The action of electromagnetic waves is also beneficial in other cases (dermatological infections, arthritis, reduction of the cholesterol level in the blood, normalization of the blood pressure, sedative action in the nervous system, elimination of wrinkles and cellulite for example).

Electromagnetotherapy is applicable to all senior mothers.

Doctors Kraus and Lechner were the first, in 1972, to adopt this therapy, with great success. Thus was confirmed the fact that electromagnetic waves are capable of "repolarizing" the cells. The so-called short-wave devices (diathermy) currently used have the drawback of requiring high powers (of the order of KW), which is dangerous and requires the supervision of a specialist. In addition, these devices are only suitable for the treatment of certain cells, therefore certain cases of pain only. Document WO91 / 04070 discloses an electromagnetic therapy device capable of bringing back to normal the difference in cellular potential of all types of cells in the body, which works at very low power, therefore harmless and portable and works with rechargeable batteries.

The practical tests carried out with this device have however shown its limits, in particular in its capacity to transmit to discharged cells high energy frequency, essential for the application of electromagnetic therapy.

The subject of the present invention is an electromagnetic therapy device which overcomes the aforementioned drawbacks and which is distinguished by the characteristics of claim 1. The accompanying drawing shows, by way of example, an embodiment of the device according to the invention. 'invention. Fig. 1 is a perspective view of the housing of the device.

Fig. 2 is a block diagram of the electronic circuit. Figs. 3 and 3a are electrical diagrams. Fig. 4 represents wave trains.

Fig. 5 shows on a larger scale, an example of a wave of these trains.

Fig. 6 represents a spectrum of the frequencies present in the wave modulated according to fig. 5.

Fig. 7 schematically represents two successive groups of 32 wave trains according to FIG. 4, separated by an intermediate break period, each train being represented by a vertical line.

FIG. 8 illustrates the yields of an electrode according to WO 91/04070 and of an electrode according to the invention. The box 1 comprises a series of six LEDs 2 used to indicate the program in progress. This program is selected by a button 3. A button 4 is used to switch on the appliance and an output 6a. Another button, 5, is used to activate an output 6b.

The outputs 6a and 6b are used to supply two electrodes allowing two parts of the body to be treated simultaneously. In fig. 2, 7 shows a power supply (including either the conventional transformer and rectifier bridge system, an accumulator with automatic charger or an AC-DC converter). 8 is a timer made with an integrated circuit in LOCMos technology, with resistance and capacitor, which determines and regulates the operating time of the following four programs: a = High; b = high / medium, c = medium / low; d = low. The program a, corresponds to small rest intervals between the groups of wave trains according to fig. 7. In this example there are 32 trains according to fig. 4 in each group of trains. Program d corresponds to large rest intervals between groups of trains, and programs b and c correspond to rest intervals between the two preceding ones (a and d _. ), The intervals b being shorter than the intervals ç. At the end of each program, an electrical pulse is sent to a switch 9, to stop the operation of the apparatus, in the case of programs a and d, or to move to the next program in the case of programs b and c, and and then stop the operation of the device. 10 is a frequency generator with an oscillating circuit (inductance and capacity) at 140 KHz. This frequency is divided by a divider not shown (integrated circuit LOCMos) into different values, to obtain, with a flip-flop circuit, sets of 32 trains of pulses as will be seen below. 11 is the electromagnetic field generator.

The outputs 6a, 6b of the housing 1 (fig. 1) each serve to connect by means of a cable, a field generator 11 electromagnetic to housing 1.

In fig. 3a, we see a high frequency transistor 15 which oscillates freely and which generates the high frequency of 9 MHz. This transistor is turned on and off by two other cascaded transistors (not shown) which operate as a switch at the frequency of 140 KHz. The transistor 15 is connected, with its base and its collector to an inductance 14 in the form of a spiral, in printed circuit carried by a flexible support of the Kapton type and which functions as an oscillating inductance. It is connected, on the one hand, to a power supply (24 V) and on the other hand (via a capacity 17 of ac¬ coupling, control and energy transfer of 82 pf) to another inductor 18 located in the center of the first and also produced in printed circuit. This inductance 18 is connected to ground by a limiting resistor 19 to charcoal, of 51 ohm and a LED diode 20 of 10 mA in parallel with it, and which indicates whether the circuit is operating. A second diode 20a is mounted in parallel to the diode 20 but in the opposite direction and, acting so as to create a chopper effect, its presence makes it possible to increase the efficiency at high frequencies of the field generator. This second inductor, 18, serves, with the first which acts on it as the primary of an auto-transformer, to create the electromagnetic field used for the treatments. The emitter of transistor 15 is connected to ground via a limiting resistor 16 of 50 ohm, in parallel with which there is a capacitance 23 of 10 nf. In fig. 3a we still see two capacitors 21 (56 pf) and 22 (100 pf). This arrangement has the effect of considerably boosting the diodes 20 and 20a which, then, under the effect of this boost, generate a multiplicity of frequencies which modulate the fundamental frequency of 9 MHz (FIG. 5). Experience has shown that the frequency spectrum of the current thus modulated extends from a few hundred Hertz to frequencies of several GHz. It is this modulated current which runs through the inductors 14 and 18, which, therefore, emit a synchronous electromagnetic field, therefore having such a very wide spectrum of frequencies (fig. 6).

In fig. 4 we have shown two successive wave trains with a duration of 3 us each and separated by an intermediate break of 2 us. It is indeed essential to achieve a satisfactory treatment, that the wave trains follow each other with periods of rest between them. In fig. 5, there is shown, on a much larger time scale, the wave curve, that is to say the carrier and a quantity of waves of higher frequencies (due to the presence of boosted diodes 20, 20a), which modulate this carrier. This curve is obtained by an oscillograph and corresponds to the field emitted by the ducts 14 and 18.

In fig. 6, we see the spectrum of Fouier frequencies present in the wave modulated according to fig. 4. The scale extends from a few hundred Hertz beyond 3 GHz. In fact, it can extend beyond, for example up to 5 GHz. We see that the frequency spectrum given by the Fourier analysis covers practically a band extending from a very low frequency to the highest frequencies (several GHz) suitable for the repolarization of different types of mammalian cells. Thus the device provides the organism treated with an almost continuous set of frequencies among which are all those necessary to repolarize all types of cells.

Switch 9 is an integrated circuit which controls four switches and is used to switch the four durations a, b, c, d, of intervals between groups of pulse trains. These four different intervals or breaks are necessary depending on the treatment. The repolarization time varies according to the condition of the cells and the type of pain to be treated. So for example, for sciatica we will use the "medium" program and for tendinitis the "high" program. Short intervals can be 1.6 ms and long intervals 13 ms, for example. The apparatus described operates at very low power, of the order of a watt. With the 24 V supply, the current in the inductors 14 and 18 is of the order of mA. The device is therefore safe and can be worn easily. The electrodes in which the radiating inductors 14 and 18 are incorporated being flexible, they can be applied directly to the parts to be treated, taking the form of these parts. The size of these electrodes will be chosen according to the parts to be treated. We will therefore have electrodes of different sizes, capable of producing fields of different intensities. Apart from the addition of the reverse diode 20a, which no doubt increases the efficiency of the device in high frequencies. quences, this device differs from that described in document WO91 / 04070 by a very particular configuration of the inductor 18 also favoring the transmission of the field, in particular of the HF components of the field to the cells of the patient.

This electrode 18 comprises a single-strand rising strand 18a and a multi-strand descending strand 18b. In this way, the magnetic fields of the ascending and descending strands are prevented from compensating each other as is generally the case, at least in part, with spiral electrodes. The configuration of the descending strand 18b is important and its central part 18c, fishbone, greatly promotes the effect of the high frequency field by the reduced length of its branches.

In the example illustrated, the multifilament descending strand 18b comprises lateral strands 18d and 18e, connected in parallel between the end of the ascending strand 18a distant from terminal a and terminal c and located laterally on either side of the portion Central 18b formed by three parallel conductors 18f, g, h connected by conduc tors in ^¬ 18i rafters.

The emitting part 14, 18 (FIG. 3) is connected to the electric circuit (FIG. 3a) in that the terminals a, b, c and d of the electrodes 14, 18 are electrically connected at points a, b, c and d of the electrical circuit (Figure 3a). Such an arrangement, configuration or pattern of the electrode 18, located at the center of an electrode 14 comprising three spirals, proves to be extremely favorable for an optimal transfer of electromagnetic energy at all the frequencies of interest for the treatment. It is kills in particular a very significant improvement in high frequency performance.

It should be noted that for reasons of clarity of the drawing and the explanation, the printed circuit (fig. 3a) is in practice located in situ on the same support as that comprising the generating part and in particular the electrodes 14 and 18 and more particularly disposed between the terminals a, b, c of this generating part.

In variants the external lateral strands 18d and 18e could be left in the air and not be connected to the terminal c.

Similarly, in another embodiment the conductors 18g and / or 18f and 18h could also be in the air and not connected to the terminal c.

Finally, in another variant, the central part of the electrode could comprise only a central conductor, not connected to point c, provided with chevron branches, the end of which would be in the air. The branches can be of different lengths.

FIG. 8 shows the amplitude of the radiant field of the electrodes as a function of the frequency, of the conventional electrodes (X) and of the electrodes according to the present invention (Y). It can be seen that the power of the radiated field, in particular for the high and very high frequencies, is much greater with an electrode according to the invention.

Claims

claims

1. An electromagnetotherapy device comprising a generator of electromagnetic waves with a fundamental frequency carrying the order of megahertz, this generator of electromagnetic waves comprising means presenting a highly boosted LED diode 20 to produce a modulation frequency spectrum covering practically a band going from the fundamental frequency to several gigahertz, so that the resulting field includes Fourier frequencies suitable for the treatment of all types of mammalian cells, apparatus further comprising means (15) to produce trains of these waves, of a duration of the order of microseconds, with breaks between trains of the same order of duration, and to group these wave trains in groups of several tens of trains, with between these groups of breaks of the order of milliseconds, apparatus further comprising a transmitting part provided with two electrodes (14, 18), characteristic se the fact that the means for producing the very wide modulation frequency spectrum also include an inverse diode (20a) connected in parallel with the diode (20); and by the fact that the electrode (14) of the emitting part has a spiral shape with 2 or more turns while the electrode (18), located in the center of the electrode (14) comprises a single-strand (18a ) and a multi-wire strand (18b).

2. Apparatus according to claim 1, characterized in that it comprises means (9) for varying the duration of the rest intervals between the groups of wave trains, depending on the case to be treated.

3. Apparatus according to claim 1, characterized in that it comprises at least one flexible plate in which is incorporated the emitting part (14, 18) of electromagnetic waves of the wave generator.

4. Apparatus according to claim 3, characterized in that this emitting part is constituted by a printed circuit on a flexible support.

5. Apparatus according to one of the preceding claims, characterized in that the multi-wire strand (18b) of the central electrode (18) comprises lateral strands (18d, 18e), connected in parallel and located on either side another of a central portion (18c) also connected in parallel with these lateral strands.

6. Apparatus according to claim 5, characterized in that the central portion (18c) comprises three parallel conduc¬ tor (18f, g, h) connected in parallel with each other and with the strands (18a, d, e), the central conductor (18g) being connected to the adjacent conductor (18f, h) by conductive parts (18i) arranged in a chevron.

7. Apparatus according to claim 5, characterized in that the multi-wire strand (18b) comprises two pairs of lateral strands (18d, 18e), one strand of each pair being connected in parallel, the other being in the air ( not related to point c).

8. Apparatus according to claim 7, characterized in that the central portion (18c) comprises three conduc¬ tor parallel to each other and connected by parts conductive (18i) of the chevron parts, this central part being in the air (not connected to point c).

9. Apparatus according to claim 5 or claim 7, characterized in that the central portion com¬ carries a central conductor, not connected to the side strands (18d, 18th), provided with chevron conductors whose end is in the air.

10. Apparatus according to claim 9, characterized in that the rafters are of different lengths.