FR3071163A1 - ELECTROMAGNETIC WAVE EMISSION DEVICE - Google Patents

Abstract

It is a portable device (10) for emitting electromagnetic waves. It is suitable, when disposed at a surface, to emit waves having a surface density of power of at least 0.5 milliwatts per square centimeter of surface and a frequency value of between 3 and 120 gigahertz.

Description

Electromagnetic wave emission device

The invention relates to the treatment of pain, in particular the treatment of chronic pain of low to moderate intensity.

A significant part of the population suffers from chronic pain. By definition, chronic pain is recurrent or even continuous pain that can occur for months or years, without necessarily being determined or eliminated. Failing to neutralize the source, it is therefore necessary to relieve the patient by reducing or even eradicating the symptom, that is to say, the pain. Currently, the most common approach to treating a patient's pain, such as chronic pain, is to administer so-called pain relievers, especially when the pain occurs, to calm them down. These pain relievers may contain paracetamol, opiate derivatives such as codeine or morphine, anti-inflammatory drugs such as ibuprofen, or anesthetics.

However, regular use of such active analgesics can cause unwanted side effects (e.g. nausea, drowsiness, heartburn).

An alternative to taking medication is to treat the pain with physical methods. The risk of side effects is reduced as well as that of drug dependence.

We know in particular a form of treatment by transcutaneous electrical neurostimulation (or "TENS for" Transcuteaneous electrical nerve stimulation ") which consists in circulating an electric current in an area of the patient's body to stimulate nerves in order to reduce pain. However, the use of this technique requires a binding device composed of electrodes to be placed on the patient's body and connected to an electric generator. In addition, it generates a feeling of tingling, which can be experienced as unpleasant by the patient.

We also know forms of medicine called "alternative" such as acupuncture, reflexology or Chinese medicine. Although the effectiveness of some of these practices has been demonstrated, there is no clearly established scientific basis to support their operation.

We finally know that the emission therapy called "millimeter" waves (that is to say, the frequency is less than 300 gigaherz) causes pain reduction (see the publication Usichenko Tl, Edinger H, Gizkho VV, Lehmann C, Wendt M, Feyerherd F: "Low-intensity electromagnetic millimeter waves for pain therapy. Evid Based Complement Alternat Med"). Indeed, it has been shown that the exposure of an area of the human body to millimeter electromagnetic waves allows the release

- 2 endogenous opioids (see the publication Rojavin MA, Ziskin MC: "Electromagnetic Millimeter waves increase the duration of anaesthesia caused by ketamine and chloral hydrate in mice Int J Radiai Biol"), generating in the brain the synthesis of enkephalin , a natural peptide involved in pain tolerance.

This technique therefore avoids the drawbacks of treatment with analgesics or neurostimulation, and its operation is understood.

Application WO2012 / 022538 discloses on this principle a device aimed at reducing pain in a patient by emitting electromagnetic waves to the surface of the patient's body. The device is bulky, it has an imposing shape of a horn, and therefore requires either to bring the patient to a specific place comprising the device, or to transport the device to the patient, who cannot therefore keep it on him and the '' use at any time and place. In addition, the patient should preferably be assisted by one or more persons specially trained to operate the device. The importance of the volume of the device is largely due to the organs of emission of the wave, such as the generator and the antenna (s), which must provide, for an effective treatment, waves of frequency between 30 and 300 GHz, which waves must have a high pfd density.

The company CEM Tech distributes a less bulky device aimed at reducing pain by means of electromagnetic waves. Although this device is small, the level of power surface density of the waves emitted is from 10 ^_19 to 10 ^-6 Watts / cm ² . However, it is known that the analgesic effect of millimeter waves is not observed for a surface power density of less than 0.5 mW / cm ² (see the publication Rojavin MA, Radzievsky AA, Cowan A, Ziskin MC: “Pain relief caused by millimeter waves in mice: results of cold water tail flick tests >>.).

An object of the invention is therefore to treat pain effectively by means of electromagnetic waves, and to make the devices provided for this purpose accessible and easily usable by patients.

To this end, there is provided according to the invention a portable device for emitting electromagnetic waves capable, when it is disposed at a surface, of emitting waves having a power surface density of at least 0.5 milliwatts. per square centimeter of surface and a frequency value between 3 and 120 gigahertz.

Thus, the device is portable, that is to say capable and intended to be worn by a patient on a regular or even continuous basis, without significant effort and without logistical or practical inconvenience. In addition, the power surface density of at least 0.5 milliwatts per square centimeter of surface allows the treatment to be effective and to reduce pain. Finally, concerning the frequency, it is a frequency band

-3particularly effective for millimeter wave treatment. Moreover, the study Radzievsky AA, Gordiienko OV, Alekseev S, Szabo I, Cowan A, Ziskin MC: “Electromagnetic millimeter waves for pain therapy. Evid Based Complement Alternat Med ”tends to show that the optimal effect of millimeter wave treatment is obtained with a frequency around 61.25 GHz and a power surface density of around 13 mW / cm ² .

Advantageously, the waves have a power surface density of between 5 and 35mW / cm ² .

Thus, it is a particularly efficient power band. On the other hand, some standards do not allow a power density greater than 35mW / cm ² , so that the device can be calibrated so as not to exceed this barrier if necessary.

Preferably, the surface being human or animal skin, the device comprises a member for detecting human or animal skin, the device being capable of signaling the presence or absence of the skin to be exposed to waves, and preferably capable of determine a distance between the skin and the device.

By "exposing to the waves", we also mean "irradiating by the waves".

Thus, the device emits waves directly to the subject's skin only if the skin is detected. If the skin is not detected, or if the distance is too great between the device and the skin, no emission takes place. In this way, we avoid sending waves in any direction and we save energy. We can also adapt the power or other parameters of the waves emitted according to the estimated distance between the device and the skin.

Advantageously, the device is able to be worn at least in one of the following places:

- around a wrist;

- on one leg;

- an ankle;

- in the back ;

- to one ear;

- in the palm of one hand; or more generally any place presenting a strongly innervated zone.

Thus, it is fixed at one of these places, for example in the manner of a watch around the wrist, so as to be worn without particular inconvenience by the patient. Regarding highly innervated areas, the study "Radzievsky AA, Rojavin MA, Cowan A, Alekseev SI, Ziskin MC. Hypoalgesic effect of millimeter waves in mice: Dependence on the site of exposure. Life sciences. 2000; 66 (21): 2101-11 "has demonstrated the beneficial therapeutic effect of sending millimeter waves in such areas.

Preferably, the device includes a rechargeable battery.

So it works wirelessly. Alternatively, it can operate by wire, in order to deliver higher powers or over longer periods of time.

Advantageously, the device is able to expose waves simultaneously at least

2.5 continuous square centimeters of the surface.

For example, the device has a module comprising several antennas emitting waves simultaneously, the area covered by all the antennas and therefore by the module representing at least 2.5 continuous square centimeters, exposed to the waves in a homogeneous manner. This provides a surface area exposed to continuous waves sufficient to induce the expected biological response.

Preferably, the device comprises a heat sink comprising at least one of the following elements:

- a flexible material;

- a phase change material;

- a thermal buffer;

- graphite; and

- an elastomeric material.

Thus, the heat sink makes it possible to minimize heating of the device in order to maintain it at a temperature below 41 ° C. If it is flexible, it allows it to adapt to the shape of the device and its maneuverability.

Advantageously, the device comprises a member for determining at least one datum of the surface, for example an impedance datum.

Thus, this measurement is made after the emission of electromagnetic waves, by a measurement of the output power which is a function of the adaptation of impedance relative to the skin. The device thereby obtains one or more characteristics of the patient's skin automatically.

Preferably, the device comprises a processing member making it possible to deduce from the or each determined data at least one wave emission parameter.

Thus, the data obtained are processed autonomously by the device which adapts the wave parameters itself, without handling the patient, who only has to trigger or program the emission of waves without worrying about the settings and of the adaptation of the waves to his person.

According to the invention, an electromagnetic wave emission module is also provided, which has a total volume of less than 4 cubic centimeters, preferably less than 3 cubic centimeters, and is suitable, when it is placed at a level. surface, to emit electromagnetic waves with a power surface density of at least 0.5 milliwatts per square centimeter of surface.

-5Thus, this module is particularly miniaturized, which allows it to be integrated into portable devices or to transport and use it easily. The minimum surface power of 0.5 mW / cm ² is that from which millimeter wave treatment is effective in treating pain, but this module may be intended for other uses.

An electromagnetic wave emission method is also provided according to the invention, in which a transmitter carried by a human or animal subject transmits electromagnetic waves having a surface power density of at least 0.5 milliwatts per skin of the subject. square centimeter of skin and a frequency between 3 and 120 gigahertz.

Advantageously, the method comprises the following steps:

- an organ detects human or animal skin, and

- when the organ detects that the skin is located three millimeters or less from the transmitter, the transmitter emits the waves.

Another predetermined distance can be provided. The distance of 3 mm corresponds to a distance close enough to allow the skin to absorb almost all of the power of the electromagnetic radiation, and this even if the module is not in contact with the skin, for example in movement moving the device or if the device is not fixed by being pressed against the patient's body.

Preferably, the method comprises the following steps:

- determination of at least one data item of skin impedance; and

- depending on the or each data, adaptation of at least one parameter of the program.

Preferably, the emission of waves takes place at the level of at least one predetermined acupuncture point of the subject.

Indeed, just like the Lyensuk VP, Samosyuk IZ, Kulikovich YN, Kozhanova AK study: "Experimental study on the low-intensity millimeter-wave electro-magetic stimulation of acupuncture points", several publications have demonstrated a particularly analgesic effect of waves millimeters at acupuncture points. For a device worn on the wrist, we think in particular of the pericaridium point 6, the wrist being moreover an area particularly rich in nerve endings, which again makes it possible to increase the effectiveness of the millimeter wave treatment.

Advantageously, the transmission is controlled at the level of the transmitter or by means of a device capable of communicating with the transmitter by a telecommunications network.

According to the invention, a computer program is also provided, comprising code instructions able to control the implementation of the steps of the method described.

-6 previously when running on a computer.

This computer program can be included in computer software but also in a mobile terminal application such as a smartphone or a "smartwatch", otherwise known as a "connected watch".

According to the invention, there is also provided a method of making the program according to the invention available for downloading on a communication network.

Finally, according to the invention, a device is provided comprising telecommunication means and the program according to the invention.

Thus, this device can be for example a computer or a smartphone.

We will now present embodiments of the invention by way of non-limiting examples and with reference to the drawings in which:

- Figure 1 is an overall diagram of an embodiment of the invention;

- Figures 2 and 3, 5 and 6 are illustrations of a portable device according to a first embodiment of the invention;

- Figure 4 illustrates a first mode of implementation of such a device;

- Figures 7 to 13 are diagrams of the components of a wave emission module according to a first embodiment;

- Figures 14 and 15 are illustrations of such a module respectively without and with heat sink;

- Figure 16 is an illustration of a radiation of the module of Figures 14 and 15;

- Figures 17 and 18 are illustrations of use according to second and third embodiments of the invention; and

- Figures 19 to 24 illustrate components of a module according to other embodiments of the invention.

Figure 1 illustrates the general framework of the invention. Patient 1 has chronic pain. He wears a device 10 according to a first embodiment and a first embodiment of the invention, which treats these pains by emitting millimeter electromagnetic waves towards the skin of patient 1, at the level of his wrist. In this case, this device 10 has the general shape of a wristwatch, and is fixed around the wrist in the same way as a watch. Illustrated in FIG. 2 schematically and in FIGS. 3, 5 and 6 in more detail, the device 10 comprises a control module 20 and a wave emission module 22. The device 10 having the general shape of a watch, it may be a watch in which the modules 20 and 22 would have been integrated. Conversely, the functionality of a watch can be integrated into device 10.

The control module 20 controls the transmission module 22. The transmission module

Command 7 is activated by the patient, but it can also be programmed by the patient or another user, on the device 10 directly by the button 23 or via a terminal such as the computer 12. The button 23 is provided with diodes which can be activated to indicate an event to the patient, for example a lack of battery or the operation of a particular program in progress. The control module 20 is present in the upper part of the device 10 while the millimeter wave emission module 22 is located in the lower part and is therefore intended to be in contact with the lower skin of the wrist.

We will now describe in detail the wave transmission module 22 integrated in the device 10. It is a transmission module according to a first embodiment. This type of module, as well as its other embodiments, can be integrated into any type of device intended to emit waves, and not only into the device 10 in the form of a wristwatch. Its applications are not limited to the treatment of pain.

This transmission module 22 illustrated diagrammatically in FIG. 7 has several circuit-antenna pairs 42, a heat sink 46 and a skin sensor 44.

Each circuit-antenna pair 42, one of which is schematically illustrated in FIG. 8, has a control interface 24 in connection with the control module 20, an ASIC (“application-specific integrated circuit”, or integrated circuit for specific application). 26 and an antenna 28. The interface 24 can be located within the control module 20. The ASIC 26 includes an oscillator 32, a power amplifier 34 and a digital part 36 for setting and controlling the component. The framework of the ASIC is represented in FIG. 11. The manufacturing of this ASIC 26 is carried out using “CMOS” (“Complementary Metal Oxide Semiconductor”) technology, a technology known to those skilled in the art and which does not will therefore not be described in detail. More specifically, the transistors are of the “65 nanometer CMOS” type. ASIC 26 thus includes an integrated circuit 33 in silicon in a housing 37 of BGA (“Bail GridArray”) type, comprising balls 35 (called “bump”), circuit 33 being soldered on a “HF” substrate 39 in PTFE (Polytetrafluoroethylene) R03003, with a so-called "flip chip" arrangement, which makes it possible to minimize losses of high frequency electromagnetic radiation. The frequency oscillator 32 is placed in a cavity (not shown) within this housing, 37 which makes it possible not to disturb the frequency generated. The size of this 37 BGA case in this case is 2.2 * 2.2 * 0.9 millimeters. Any alternative material to the PFE substrate having the same technical advantage is of course admissible, for example a woven glass fiber substrate impregnated with ASTRA-MT77 type resin. The connection to the antennas 28 is made by means of “balls” 43. This set of components makes it possible to reduce to the maximum

-8 loss of electromagnetic waves. It is the antenna 28 which transmits electromagnetic waves to the skin of the patient 1. The arrangement of the ASICs, control interface and antennas within the transmission module can of course be different.

The terminal connection 41 between an ASIC 26 and its antenna 28 is visible in the figure

12. A coaxial connection 41 thus ensures the transmission of the wave between the power amplifier 34 and the antenna 28. By antenna is generally meant any form of radiating element, provided in this case that it is flat. We can call this type of radiating element a "patch".

As shown in FIG. 13, the ASIC 26 and the antenna 28 are arranged on either side of the substrate 39.

The set of antennas 28 forms an array of antennas illustrated in FIG. 9. This rectangular array here, this array of antennas intended to be placed against the skin of patient 1 or at a short distance from it, measures approximately 2.5 centimeters long for about 1 centimeter wide. It is provided in this case with 27 radiating elements 28 operating in the near field, at the rate of three rows of nine antennas, aligned vertically and horizontally with respect to each other. These quantities and these provisions are not limiting and others may be considered.

This arrangement makes it possible to emit waves homogeneously over 2.5 square centimeters of skin. By “homogeneous”, it is meant to mean that the intensity of the waves arriving on the skin must not present a difference greater than about 30% between its maximum value at one point and its minimum value at another. FIG. 16 shows the radiation on the patient's skin emitted by the device in a normal operating mode. The white shapes correspond to a radiation between 5 and 15mW / cm ² , the black shapes to a radiation of less than 5mW / cm ² . It is observed that 75% of the surface is exposed to waves of density between 5 and 15mW / cm ² . In general, the power density can be greater than 35 mW / cm ² , but the device is designed so that the power range used is of the order of 5 to 35 mW / cm ² in normal operation, in particular for 30 minutes of continuous wave emission. This operating mode is indeed the most usual, as will be described below.

FIG. 10 illustrates an application of the module 22 for emitting waves at the level of the skin 60 of the patient 1. A distance of 3 millimeters separates the module in kind from the skin of the patient. Although the goal is to affix the device to the skin, there may be times when a slight gap is created between the skin and the device. Furthermore, for more comfort and for reasons of biocompatibility, a layer 52 of silicone separates the antennas from the skin, so that the skin does not have to directly support the antennas.

-9 Alternatively, it may be another transparent material with millimeter waves such as polycarbonate. This layer 52 of silicone can measure from 1 to 2 millimeters, the design of the antennas allowing the layer 52 to interfere little or not with the waves emitted.

In total, this wave emission module 22, which can be called a millimeter module (the waves being said to be “millimeter” in view of their frequency) or millimeter map, measures 37 millimeters in length, for 20 millimeters in width and 3 millimeters thick in the present embodiment. The volume of the millimeter module is therefore 2.96 cubic centimeters. Illustrated in FIG. 14, it is therefore less than four and even three cubic centimeters, which makes it possible to insert it in devices of small volume and light, such as the device 10 in the form of a wristwatch. With this volume and the described arrangement having 27 antennas, the ASICs 26 developed, coupled to the antennas 28, allow the millimeter module to emit waves of frequency situated between 3 and 300 gigahertz, preferably between 30 and 120 gigahertz, with a power surface density of at least 0.5 milliwatts per square centimeter, simultaneously on a skin surface of 2.5 square centimeters. However, a millimeter wave treatment is effective from a power density of 0.5 milliwatts per square centimeter, preferably on a surface of at least 1 square centimeter. The module described therefore allows the treatment to be carried out by being integrated into any device and this in an easy manner in view of its small volume.

It is understood that the ASICs, the antennas, as well as the whole of the millimeter module 22, can have different volumes, numbers and different layouts.

The skin sensor 44 uses a capacitive type measurement making it possible to determine that the patient's skin is positioned near the millimeter module 22. Its structure is known to those skilled in the art and is not limited to a capacitive measurement, all being miniaturizable skin sensor admissible. Connected to the control interface 24 and / or to the control module 20, the skin sensor 44 determines the presence or absence of human or animal skin. It is also able to determine the distance between the skin and the millimeter module. At 3 millimeters or less, wave emission is allowed. Otherwise, the control module 20 can prevent the sending of waves. The goal here is to prevent the sending of waves inefficiently, on the one hand to control the direction of the waves emitted, and on the other to save energy. In the first embodiment, the skin sensor 44 is located outside the module, on a side of the device 10.

The millimeter module 22 can further comprise a rechargeable battery. Preferably, the entire device comprising the module 22, such as the device 10,

- 10 has a battery supplying both the control module 20 and the wave transmission module 22. This battery can be conventionally recharged from the mains or in any other way. It is of course interesting that its autonomy is several hours, even several days, so that the patient's portable device aimed at treating his pain is more convenient to use.

Of course, some of the components of the module can be placed outside of it to better interact with the device comprising the module, such as the battery.

Besides the control module 20, the millimeter module 22 and the skin sensor 44, the device 10 has other components described now.

The ply 58 of FIG. 3 is flexible and aims to adapt to the shape and size of the wrist as a conventional watch strap would do.

The device 10 also includes a dissipator 46 illustrated in FIG. 5, which can be considered to be part of the millimeter module 22. In the present case, it is located outside this module, and comprises a flexible sheet 47 and a thermal buffer 48, the two components being inserted within the bracelet of the device 10. The ply 47 is associated with graphite and rubber. The rubber allows the tablecloth to be flexible and therefore adaptable to the bracelet. Graphite is light and has good thermal conductivity. The ply 47 can be made of another elastomeric material than rubber. It can also have a completely different material, its advantage here being that it is flexible to adapt to the shape of the device. The pad 48 includes a phase change material. Thus, during the release of heat due to the operation of the device, the phase change material absorbs part of the calories removed and allows the overall temperature to be maintained. The heatsink is arranged with the device in order to maintain the temperature of the surrounding body area below 41 ° C for a continuous operation of the device for approximately 30 minutes. This temperature of 41 ° corresponds to these maximum temperature standards set by certain authorities, and that is why the arrangement of the device is designed to comply with it. It could thus be designed differently if the maximum authorized temperature was higher.

The device 10 also includes a member (not shown) for determining the impedance of the skin. This member can be part of the millimeter module 22.

Concerning the frequency of the waves emitted by the device 10 thanks to the module 22, it can be located between 3 and 300 gigaherz for an effective treatment. However, the frequency of the device described preferably varies between 30 and 120 gigaherz, with a preferred frequency located around 60 gigaherz.

For each component, its dielectric properties, such as its permittivity, its conductivity, its loss tangent, had to be taken into account for the design of the module 22 and of the device 10. Simulations and tests outside the nominal operating range of the 65nm CMOS type ASIC transistors have been made, and do not call into question the lifetime of the components with regard to the implementation of millimeter wave treatment which will be described below.

We will now focus on the implementation of pain treatment in the patient.

This treatment aims to emit waves at an area of the patient's skin. The program generally lasts 30 minutes, with a program of two a day. The frequency, preferably between 30 and 120 gigahertz, is predetermined. It may possibly vary during a transmission, as can the pfd density which generally varies between 5 and 35mW / cm ² , but may be less or more than this range. Obviously, any other type of treatment is possible, in particular with longer and / or more frequent emissions.

In a first mode of implementation, the waves are emitted by the module 22 integrated in the device 10 in the form of a wristwatch at the wrist, a highly innervated zone and can be placed on the "pericardium point six" referenced 6 on Figure 4, which is a known acupuncture point. Indeed, it has been shown that the emission of waves to acupuncture points is particularly effective in the treatment of pain. In addition, very good results are also achieved for particularly innervated areas. Indeed, the stimulation of the nerve endings located under the skin induces a set of physiological actions called "systemic response", actions which in turn induce the synthesis of endogenous opioids (including enkephalin) themselves responsible for the decrease in pain. Thus, the more the emission of waves takes place in an area with a high density of nerve endings, the more the treatment is likely to be effective. The pericardium point six is an acupuncture point at the same time located in an area rich in nerve endings. The interest of a device emitting waves at this level is therefore maximum.

In addition, other potential benefits described in the literature associated with this increase in the synthesis of opioids are known, such as a reduction in heart rate, stress, improved sleep, or even a euphoric effect. Such benefits can therefore be drawn from device 10.

The frequency, the duration, and the power of the waves can be configured by means of the module 20 of the device 10. As illustrated in FIG. 1, it can be programmed in advance by means of a terminal, for example a computer 12 , which can communicate with it by any telecommunication network, such as a Bluetooth or Wifi type link 18. The computer 12 includes a database 14 on which a

- 12 program 16 implementing the process or processes having a link with the invention, as well as various data allowing the implementation of the invention, in particular data entered by the patient 1 and data obtained by the device 10.

Furthermore, by determining the impedance of the skin by means of the impedance detection member, the latter transfers to the control module 20 a datum characteristic of the patient's skin. Parameters of the waves emitted by the module 22 can then be modified automatically via the control member 20, using the program 16, or manually by the patient or another user. Thus, the device 10 adapts to the patient's skin. In other words, the electromagnetic field created is subject to the characteristics of the skin. It can also be modified as a function of the distance measured between the skin and the device, via the skin detector 44. The device can include other organs determining and processing other data obtained directly from the patient, which can serve to adapt the parameters of the transmitted waves such as power, frequency and duration of emission.

Other embodiments of the transmission module are illustrated in FIGS. 19 to 24. They differ from the previous mode by their number of ASICs and antennas. The module in Figure 19 thus presents 8 ASICs. In addition, an ASIC can correspond to one or more radiating elements. Thus, the module 320 presents 4 ASICs for 8 radiating elements, at the rate of 2 radiating elements for 1 ASIC. Finally, the 420 module presents 6 ASICs and 6 radiating elements.

Furthermore, the transmission module can also be integrated into another device, for example intended to be worn by the patient in another part of the body. FIG. 17 thus illustrates a device 100 according to a second mode of implementation comprising the control and emission modules placed on the pin, while FIG. 18 illustrates such a device 1000 according to a third mode of implementation placed at calf level. In these second and third embodiments, the waves are therefore emitted at other areas of the patient's body by means of devices which differ from the device 10 essentially in order to adapt to the targeted area of skin. In all cases, the miniaturization of the modules allows the device to be light and not bulky, so that it is easy to carry and not very restrictive.

Regardless of any pain treatment, the wave emission module, possibly with the control module, can be useful for sending waves for other purposes, since it is particularly miniaturized, and therefore light. . It can therefore be integrated into any device where it is necessary to send millimeter waves to a surface or in any direction.

Furthermore, the transmission module, or the control module, and / or the device integrating these modules, can be controlled remotely, from a terminal such as a

- 13 computer, but also from a mobile terminal. For example, a mobile application comprising a pain treatment program can be registered on the mobile terminal, so that the patient can program his treatment himself, for example the power, the frequency, the duration and the time of sending the waves, or that his doctor or any medical assistant programs these parameters remotely. In this case, the terminal includes software having one or more interfaces allowing the user of the terminal to configure the device. The program for implementing the invention can be downloaded via a telecommunications network.

It may be added that the emission module and the device comprising it can also be used in order to reduce the patient's stress or even bring a feeling of well-being.

Of course, many modifications can be made to the invention without departing from the scope thereof.

Claims (15)

1. Portable device (10; 100; 1000) for emitting electromagnetic waves, characterized in that it is capable, when it is arranged at a surface (60), of emitting waves having a density areal power of at least 0.5 milliwatts per square centimeter of surface and a frequency value between 3 and 120 gigahertz. 2. Device according to the preceding claim, wherein the waves have a power surface density of between 5 and 35 mW / cm ² . 3. Device (10; 100; 1000) according to any one of the preceding claims, which comprises a detection member (44) of human or animal skin, the device being capable of signaling the presence or absence of the skin to expose to waves, and preferably able to determine a distance separating the skin (60) and the device (10; 100; 1000). 4. Device (10; 100; 1000) according to any one of the preceding claims, capable of being worn at least in one of the following places: - around a wrist; - on one leg; - an ankle; - on a back; - to one ear; or - in the palm of one hand. 5. Device (10; 100; 1000) according to any one of the preceding claims, comprising a rechargeable battery. 6. Device (10; 100; 1000) according to any one of the preceding claims, capable of simultaneously exposing at least 2.5 continuous square centimeters of the surface (60) to the waves. 7. Device (10; 100; 1000) according to any one of the preceding claims, comprising a heat sink (46) comprising at least one of the following elements: - a flexible material; - a phase change material; - a thermal buffer; - graphite; and - an elastomeric material. 8. Device (10; 100; 1000) according to any one of the preceding claims, comprising a member for determining at least one datum of the surface (60), for example an impedance datum. 9. Device (10; 100; 1000) according to the preceding claim, comprising a processing member (20) making it possible to deduce from the or each determined data at least one parameter of emission of the waves. 10. Computer program (16), comprising code instructions capable, when executed on a computer, of controlling the implementation of the steps of an electromagnetic wave emission method, in which a transmitter (10; 100; 1000; 22; 220; 320; 420) carried by a human or animal subject emits towards a skin (60) of the subject electromagnetic waves having a surface power density of at least 0.5 milliwatts per square centimeter of skin and a frequency value between 3 and 120 gigahertz. 11. Program according to the preceding claim, in which the method comprises the following steps: - an organ (44) detects human or animal skin, and - when the organ detects that the skin (60) is located at three millimeters or less from the transmitter (10; 100; 1000; 22; 220; 320; 420), the transmitter emits the waves. 12. Program according to any one of claims 10 to 11, in which the method comprises the following steps: - determination of at least one data item of skin impedance (60); and - depending on the or each data, adaptation of at least one parameter of the program. 13. Program according to any one of claims 10 to 12, in which the emission of the method is controlled at the level of the transmitter or by means of a device capable of communicating with the transmitter by a telecommunications network. 14. A method of making the program available according to any one of claims 10 to 13 for downloading on a communication network. 15. Device comprising telecommunications means and the program according to any one of claims 10 to 13.