NL9401289A - Apparatus and method for preparing a radically acting therapeutic electrically charged vapor mixture. - Google Patents

Description

APPARATUS AND METHOD FOR PREPARING A RADICAL-ACTING THERAPEUTICALLY ELECTRICALLY-CHARGED VAPOR MIXTURE

The present invention relates to a device for the prevention or treatment of disorders or diseases of objects, such as humans, animals, plants, tissues or cells, which are associated with the formation / presence of, whether or not free, radicals, which device is designed as a cabin with heating means for heating steam by an aqueous solution, to which gas particles in the form of molecular and / or atomic (free) hydrogen and / or oxygen ions are fed to form an electrically charged vapor mixture with therapeutic properties .

The invention further relates to a method for preparing a radically acting therapeutically electrically charged vapor mixture from a heated aqueous solution which forms steam, to which molecular and / or atomic (free) hydrogen and / or oxygen ions are added, as well as the therapeutically electrically charged vapor mixture manufactured according to the method, and the use of the therapeutic electrically charged vapor mixture.

The device, the method, the therapeutically electrically charged vapor mixture and its use are known from WO 89/11267.

The known device comprises heating means, as well as a device for the electrolysis of water for the purpose of providing the gas particles to the cabin.

The drawback of this is that the known device is complex and does not lend itself to a compact construction of the various necessary components.

The object of the present invention is to provide a device for the prevention or treatment of disorders or diseases of objects, such as humans, animals, plants, tissues or cells, which can be built up in large numbers in a simple and less expensive manner. and the efficiency and concentration of which vapor mixture is nevertheless easily adjustable.

To that end, the device according to the invention is characterized in that the heating means comprises two or more separate electrically conductive heating parts, which also function as electrodes, which are each connected to an electric control unit for influencing the electric current flowing through the heated aqueous solution, depending on which concentration of gas particles in the electrically charged vapor mixture in the cabin is affected.

The advantage of the device according to the invention is that no separate chemical / electrical decomposition or electrolysis equipment is required to produce the gas particles. The device according to the invention is simpler and therefore cheaper to make and more suitable for large-scale production and installation, in the form of a fixed or movable cabin. The device has a greater compactness and the simultaneous generation of the individual heating means acting as electrodes ensures an increased concentration of gas particles in the vapor mixture.

Although the individual electrically conductive electrodes, which act as electrodes, can be integrated in the reservoir, classical separated heating elements immersed in the aqueous solution in the reservoir can be easily applied without further technical modifications to the reservoir.

A further embodiment of the device according to the invention has the feature that the cabin contains electric and / or magnetic means for preparing or maintaining the electrically charged vapor mixture in the cabin.

It is advantageous that the (additional) production and the long-term maintenance of the vapor mixture increases the chance that it will contact and react with the pathogenic radicals to chemically / physically convert the radicals into a less reactive substance.

In a further embodiment of the device according to the invention, the electrical means are preferably provided with an inner wall of the cabin reflecting the electrically charged vapor mixture. The inner wall is covered with an electrically conductive layer, for example a metal, metal film or metal foil. In an embodiment of the device according to the invention, the inner wall is provided with a conventional and generally available optical mirror. In its most specific version, all interior walls, namely the upright walls, the ceiling and the bottom, are provided with an optical mirror.

A directional effect and thus a further increase in the effectiveness of the prevention or treatment of diseases or diseases of objects is obtained by giving at least one of the interior walls of the cabin a tapered or parabolic course.

In an embodiment of the device according to the invention, in which it is not necessary to bend or bend the mirrors, but in which use can be made of separate flat mirrors, the inner wall, in particular the ceiling, has a pyramid course.

Further concentration by capturing the gas particles in the electrically charged vapor mixture by magnetic means is obtained by arranging the magnetic means to produce one or more local magnetic field concentration in the vicinity of which the object to be treated can be positioned.

The magnetic means necessary for this purpose may comprise, for example, coils, the advantage of which is that by controlling the current strength through each of the individual coils, the different, if desired, varying local magnetic field strengths can be controlled. Conventional configurations made up of permanent magnets are also possible, however.

A further increase in the degree of effectiveness in the device according to the invention is obtained by applying ionizing agents in the cabin to promote the ionization of the vapor mixture. The ionizing agents are preferably one or more high-energy, for example ultraviolet or infrared lamps, which are preferably arranged such that they irradiate the objects located in the cabin and surrounded by the electrically charged vapor mixture. In addition to heat, which by the opening of the pores positively influences the blood circulation in the skin of humans and animals, the lamps thus provide the high-energy radiation that further ionizes the vapor mixture.

It has been found that when the lamps are switched on and off at regular intervals, in particular when they are switched on, the persons present in the cabin, who at the prevailing temperature of ± 40 ° C to ± 70 ° C tend to have to turn around or doze off, are activated when the light level in the cabin increases, whereby certain vitalizing substances are produced in the body.

In a further embodiment, the device according to the invention has ionization means which comprise as electromagnetic radiation and in particular a very high-frequency radiation source and an antenna connected to the radiation source and placed in the cabin.

The electromagnetic radiation emitted by the radiation source acts on the vapor mixture built up as a plasma, which is electrically charged and consists of gas particles. As a result, the vapor mixture, on the one hand, absorbs energy from the radiation, but, on the other hand, is stirred by applying radiation pressure to the vapor mixture, as a result of which an improved mixing of the gas particle concentration in the cabin can be effected.

This effect is amplified by outputting the radiation source to deliver a continuous frequency signal to the antenna.

A further increase in the concentration of gas particles in the vapor mixture can be achieved by providing, in accordance with a further embodiment, the device according to the invention with ionizing agents which are incorporated as ultrasonic exciters in the reservoir.

The effect of this is that the electrolysis and simultaneous heating takes place in a very violent manner similar to a boiling or foaming, whereby the steam and gas particle formation can be increased even further.

The present invention further relates to a process for preparing a radically-acting therapeutic electrically charged vapor mixture from a heated aqueous solution that forms steam, to which molecular and / or atomic (free) hydrogen and / or oxygen are added, the characterizing possesses that both the steam and the gas particles are generated by means of heating means composed of electrically separated parts.

The invention further relates to a therapeutically electrically charged vapor mixture manufactured according to the method, in which the vapor mixture contains practically exclusively oxygen ions, and the invention relates to the use of a vapor mixture for the chemical / physical conversion of a radical into a less reactive substance, as well as the use of that vapor mixture in the preparation of therapeutically active substances capable of scavenging radicals.

The invention, together with the other associated advantages, will now be further elucidated with reference to the annexed drawing, in which the device according to the invention is shown in a very schematic manner, and with the aid of which the method for preparing a radical Acting therapeutic electrically charged vapor mixture will be explained in more detail.

The figure shows a device in the form of a cabin 1 with accessories. The cabin 1 has an access door (not shown) through which objects to be treated in the cabin, in particular, but not limited to, one or more people who can sit on the height and position adjustable couch 2. If desired, instead of the couch 2, for example, a chair (not shown) can be used, or a bath, partly or partly filled with water, can be used. In the cabin 1 there is a reservoir 3, in which two separate electrically conductive heating elements 4 and 5 are shown. In the reservoir 3 there is an aqueous solution, which is heated by the heating elements 4 and 5 supplied with the necessary electrical energy by means of a supply circuit 6. The heating elements 4 and 5 are electrically conductive at least partly on their pipe surface, however, the outer sides thereof are electrically separated from each other and each connected to a control unit 7. The control unit 7 supplies the electric current to electrodes heating elements 4 and 5, as a result of which the aqueous solution is chemically / electrolytically decomposed while being heated by the elements 4 and 5 and forms steam, from which the developed gas particles hang in the form of molecular and / or atomic (free) hydrogen and / or oxygen ions. Thus, an electrically charged vapor mixture with therapeutic properties is formed, in which the concentration of gas particles can be influenced by controlling the electric current provided by the control unit 7. Both the power supply circuit 6 and the control unit 7 are connected to an interface microcontroller 8, which in turn receives commands from a PC 9.

The PC 9, which may be an appropriately programmed conventional computer, is used to visualize and interpret the various signals yet to be explained from the cabin 1, and depending on the desired values adjustable on the PC the various adjustable variables, as well as their course as a function of time, can be set.

The cabin 1 is lined on the inside thereof with an inner wall reflecting the electrically charged vapor mixture, which has an electrically conductive layer, which is formed, for example, by the back of an optical mirror. One or more of the upright inner walls 10, and / or the bottom 11 and / or the ceiling 12 are made of an electrically conductive layer, for instance in the form of a metal or film layer, or composed of one or more mirrors.

The ceiling 12 shown has a faceted pyramid gradient made of mirrors, whereby the electrically conductive vapor mixture is reflected downwards in the cabin 1 towards the couch 2, which increases the effectiveness of the treatment due to an increase in concentration of gas particles around the object . Magnetic means, which are not specifically indicated, are provided in the cabin 1, whereby one or more local magnetic field concentrations 13 are produced. The gas particles from the electrically charged vapor mixture in the cabin 1 are captured by these magnetic field concentrations 13 and spiral around the lines of force of the field concentrations. In the region of elevated field concentrations, more gas particles will therefore accumulate, so that at least locally the effectiveness of the treatment at that location near the object is increased. The magnetic field concentrations 13 can be generated, for example, by means of coils (not shown) supplied with an electric current, or by means of a network of permanent magnets. If desired, the current through the different coils can be influenced by connecting the coils to the interface / microcontroller 8, which has a number of unconnected ports 14 for this purpose.

The concentrations of different types of gas particles can be further influenced by means of ionization means placed in the cabin 1, in the form of, for example, ultraviolet lamps 15 or infrared lamps 16. The lamps 15 and 16 are each separately coupled to ports 14 of the interface / microcontroller 8. For example, lamps 15 and / or 16 are switched on and off regularly.

In the cabin 1 there are furthermore ionizing means in the form of electromagnetic radiation means, which are provided with an antenna 17 placed in the cabin, which is connected to a radio frequency source (not shown) which can be controlled by means of the interface / microcontroller 8. The antenna 17 emits a signal, the frequency of which continuously varies in frequency, for example, the electromagnetic radiation emitted by the antenna 17 lies, for example, in the very high frequency range, whereby the electrons of the cores of the various gas particles present in the vapor mixture are excited and get out of their quantum mechanical ground state. At that time free electrons also form in the cabin, which in turn are retained by the reflective walls of the cabin 1, or are often temporarily captured in the local magnetic field concentrations 13.

An embodiment is shown, in which the ionizing means comprising ultrasonic excitation means 18 connected to the interface / microcontrooper, which are arranged in the reservoir 3. By means of the effect of excitation known per se, if desired, the heated and chemically / electrolytically separated aqueous solution in the reservoir 3 can be brought into a very violent state, in order to further promote the formation of steam and gas particles in the vapor mixture.

In the manner described above, various types of forces are exerted on the gas particles in various ways. In addition to mechanical forces exerted by ultrasonic excitation means, mechanical forces can also be exerted by means of air displacing means 19, which flow out schematically in the cabin 1, and which contain fans in addition to the necessary filters and air treatment devices. The forces further comprise forces which are developed by the radiation pressure resulting from the lamps 15 and 16, and which can optionally be supplemented with lamps (not shown) emitting weak X-rays. In addition to the aforementioned electromagnetic forces, which are produced by the coils, the magnets and the antenna 17, diffusion forces occur due to concentration differences of the different types of gas particles in the cabin 1.

For optimal use of the cabin 1, the different types of applied forces can be brought together and concentrated, in order to prevent the chance that one or more types of gas particles, for example having a first charge, react with an electrically charged radical in the object, which is a charge property that is opposite to the first load is as large as possible.

The cabin 1 is provided with nebulizers 20, with which it is possible to atomize an aqueous mixture, in which an excess of gas particles is present, and let it descend on the object. Naturally, the required pumps (not shown) are connected to the interface / microcontroller 8. The aqueous solution then has the vapor mixture with the gas particles dissolved therein.

If desired, the vapor mixture can be formulated to contain only oxygen ions with an excess of electrons, thus forming the antioxidant with which it must be radically contacted by the appropriate application of the aforementioned forces.

Therapeutically active substances, of which the vapor mixture with the gas particles is the active radical-scavenging component, can be prepared by using the above-described method.

Claims (30)

1. Device for the prevention or treatment of disorders or diseases of objects, such as humans, animals, plants, tissues or cells, which are associated with the formation / presence of free or non-free radicals, which device is designed as a cabin with heating means for forming steam by heating an aqueous solution to which gas particles in the form of molecular and / or atomic (free) hydrogen and / or oxygen ions are fed to form an electrically charged vapor mixture with therapeutic properties, characterized in that the heating means two or more separate electrically conductive heating electrodes, also acting as electrodes, each connected to an electric control unit for influencing the electric current flowing through the heated aqueous solution, depending on which the concentration of gas particles in the electrically charged vapor mixture in the cabin is affected. 2. Device as claimed in claim 1, characterized in that the heating parts are heating elements immersed in a reservoir containing the aqueous solution. Device according to claim 1 or 2, characterized in that the cabin contains electric and / or magnetic means for preparing or maintaining the electrically charged vapor mixture in the cabin. 4. Device as claimed in claim 3, characterized in that the electrical means comprise an inner wall of the cabin reflecting the electrically charged vapor mixture. Device according to claim 4, characterized in that the inner wall is covered with an electrically conductive layer. Device according to claim 4 or 5, characterized in that the inner wall is an optical mirror. Device according to any one of claims 4 to 6, characterized in that at least one of the interior walls of the cabin has a tapered or parabolic profile. Device according to any one of claims 4 to 7, characterized in that the ceiling has a pyramid course. Device according to any one of claims 3 to 8, characterized in that the magnetic means are arranged to produce one or more local magnetic field concentrations for capturing the gas particles of the electrically charged vapor mixture. Device according to claim 9, characterized in that the magnetic means comprise coils. 11. Device as claimed in claim 9 or 10, characterized in that the magnetic means comprise a configuration built up from permanent magnets Device according to any one of claims 1 to 11, characterized in. that the cabin contains ionizing agents for promoting the ionization of the vapor mixture. Device according to claim 12, characterized in that the ionizing means contain one or more high-energy, for example ultraviolet or infrared lamps, which are preferably arranged in such a way that they enclose the cabin contained in the cabin and are charged by the electrically charged vapor mixture. objects are irradiated. Device according to claim 13, characterized in that the lamps, preferably electrically controlled, are switched on and off with a certain regularity. Device according to any one of claims 12 to 14, characterized in that the ionization means contain electromagnetic radiation means. Device according to claim 15, characterized in. that the electromagnetic radiation means comprise a very high-frequency radiation source and an antenna connected to the radiation source and placed in the cabin. Device according to claim 16, characterized in. that the radiation source is configured to deliver a continuous frequency signal to the antenna. Device according to any one of claims 12-17, characterized in that the ionization means comprise ultrasonic excitation means which are arranged in the reservoir. Process for preparing a radically-acting therapeutically electrically charged vapor mixture from a heated aqueous solution that forms steam, to which molecular and / or atomic (free) hydrogen and / or oxygen ions are added, characterized in that both the steam when the gas particles are generated by means of heating means composed of electrically separated parts. Method according to claim 19, characterized in that the position and the local concentration of the electrically charged vapor mixture in the cabin is influenced by exerting forces on the gas particles. Method according to claim 20, characterized in that the forces are exerted by mechanical forces generated with ultrasonic excitation means and / or air displacing means, such as fans. Method according to claim 20 or 21, characterized in that the forces are exerted by radiation pressure forces developed with ionization means and / or light generating means. Method according to any one of claims 20-22, characterized in that the vapor mixture is irradiated with electromagnetic rays, for example light, X-ray, UV or IR rays, the frequency of which lies in the range in which the electrons of the nuclei of the various gas particles in the vapor mixture are excited and come out of their quantum mechanical ground state. A method according to any one of claims 20-23, characterized in that the forces are diffusion forces caused by concentration differences of gas particles in the cabin. A method according to any one of claims 20-24, characterized in that the forces are exerted by electromagnetic forces developed by electromagnetic means. A method according to any one of claims 20-25, characterized in that the different types of forces are concentrated and cooperate in such a way that the chance that an electrically charged radical reacts with one or more gas particles in the vapor mixture which have an electric charge which is opposite to that of the radical, as large as possible. A method according to any one of claims 20-26, characterized in that the vapor mixture is atomized in the cabin. 28. Therapeutically electrically charged vapor mixture manufactured according to the method according to any one of claims 19-27, characterized in that the vapor mixture contains practically exclusively oxygen ions. Use of the therapeutically electrically charged vapor mixture according to claim 28, characterized in that the vapor mixture is used for chemically / physically converting a radical into a less reactive substance. Use of the therapeutic electrically charged vapor mixture according to claim 28, characterized in that the vapor mixture is used in the preparation of therapeutically active substances capable of scavenging radicals.