WO1992005792A1

WO1992005792A1 - Use of the reaction product of a gas and a liquid, as well as process and device for producing the same

Info

Publication number: WO1992005792A1
Application number: PCT/EP1990/001651
Authority: WO
Inventors: Klaus L. Buchholz
Original assignee: Buchholz Klaus L
Priority date: 1990-10-02
Filing date: 1990-10-02
Publication date: 1992-04-16

Abstract

The reaction product of a gas and a liquid, the gas being present in normal conditions in an activated form and in an amount at least 30% higher than the saturation level, in normal conditions, for the dissolution of the gas in the liquid, and that contains at least water and oxygen, is used for producing a medicament useful for the therapeutical and/or prophylactic treatment of herpes zoster, gangrene, stomatitis, eye diseases, adult-onset diabetes, torpid wounds, keratitis, radiation sickness or for support treatment in the case of irradiation with slightly ionizing radiation. It can be produced by pumping the liquid or the liquid-gas mixture in a closed circuit and (a) by drawing the gas in the form of very small bubbles into a funnel vortex and vortex line formed in the liquid and that preferably swing around their axis of rotation; and/or (b) by injecting the liquid or the liquid-gas mixture into the gas atmosphere by means of a nozzle and/or (c) by forming with the liquid-gas mixture a vortex line having a high energy of rotation in the gas atmosphere; as well as by carrying out in addition at least one of the following process steps: (d) the single or multiple repetition of at least one of the process steps: (a), (b) and (c); (e) flowing at least once through a helical tube; (f) tangentially feeding at least once the liquid-gas mixture into a cyclone type mixer filled with the liquid-gas mixture; (g) introducing gas bubbles at least once into the liquid (or treating the liquid-gas mixture) by means of a vibrator and/or pressure wave generator.

Description

Use of a reaction product from a gas and a liquid, as well as a method and device for its production

The invention relates to the use of a reaction product of a gas and a liquid, the gas being present under normal conditions in an activated form and in an amount which is at least 30% above the normal conditions corresponding saturation amount for the solution of the gas in the liquid, and which contains at least water and oxygen; further a process for producing such a reaction product according to the preamble of claims 2 to 4; and a device for carrying out the method according to the preamble of claim 7 or claim 12.

Such a reaction product, in particular from gas and water, is known from EP-AI-0314015. This document describes that this reaction product of oxygen and water has proven to be successful in the treatment of Candida albicans and congelatio cutis. When this reaction product was taken orally, a significant reduction in the - previously elevated - blood alcohol content was found. However, the uses described for therapeutic purposes are only a small part of a much broader field of application.

^~~

According to the invention, the reaction product of oxygen and water is suitable for the production of medicaments for the therapeutic and/or prophylactic treatment of a wide variety of pathological changes.

Remarkable successes have been achieved both with oral and with local application, especially with herpes zoster, gangrene, mouth rot, with eye diseases Age-related diabetes, radiation hangovers, torpid wounds and to support the oxygen effect during exposure to loosely ionizing radiation.

In various clinical tests, the water-oxygen mixture has proven to be particularly suitable for therapy or to support therapy, which is briefly outlined below:

- The deteriorated ability to absorb and utilize oxygen with increasing age causes poorer glucose utilization, which can lead to adult-onset diabetes, among other things. The learning ability and reaction time of older people is also reduced. The use of the water-oxygen reaction product has proven to be successful in the early stages of adult-onset diabetes; in many cases it was possible to dispense with further medication with oral antidiabetics.

- The effectiveness of loosely ionizing radiation is two to three times greater when there is a good supply of oxygen to the tissue than when there is complete anoxia. This oxygen effect depends exclusively on the oxygen conditions at the time of irradiation. Supportive oral application of the water-oxygen reaction product shows a satisfactory effectiveness of the radiation.

- Drugs are known (Oxoferin, registered trademark of the company OXO Chemie, Heidelberg) which, applied locally, are used to treat the hypoxia of problem wounds. A disadvantage, however, is the need to prevent unpleasant, painful side effects in many cases by applying zinc ointment, for example. The reaction product according to the invention does not show any of these side effects; in contrast, it even has a pain-relieving effect in many cases. The local application of the water-oxygen reaction product in diabetic gangrene and wet herpes zoster has proven to be particularly effective, sometimes also in severe cases.

- As a result of therapeutically necessary radiation, especially when using densely ionizing radiation (high LET), radiation hangover occurs, which manifests itself in general nausea, tachycardia, headaches, etc. Oral use of the water-oxygen reaction product brings about favorable results, and in most cases the symptoms typical of a radiation hangover disappear.

The therapeutically effective water-oxygen reaction product, in which the oxygen becomes active beyond the reactivity achieved in dissolved form, remains stable for a long time without special measures, such as storage under increased pressure or reduced temperature. and the half-life is at least a month, mostly even a year.

According to Henry's law, the dissolution (solubility) of gases in water (as in other liquids) is proportional to the partial pressure of the gas above the solution. In order to dissolve gases in liquids, these are generally introduced into the liquids. The maximum amount of gas absorbed at a given temperature is the saturation concentration. It increases with sinking the temperature of the liquid. By increasing the partial pressure of the gas above the liquid, the liquid-gas mixture becomes supersaturated, but after the partial pressure has been reduced, the excess dissolved gas, which is then no longer soluble, is quickly released. Various methods for introducing bubbles into liquids are known. From DE-3543002-C1, for example, a device for gassing liquids is known, with gas being introduced from a chamber into liquid via an elastic chamber wall which vibrates.

It is also known that a helical flow can be maintained in a reaction vessel if the feedstock is introduced tangentially into the reaction space at one or more points. Such devices are also known under the designation cyclone or centrifugal separator; they serve to separate solid substances from gases or from liquids. DE-C-967943 uses this flow phenomenon for intensive mixing of the reactants when carrying out endothermic chemical reactions. A similar device is known as the Hilsch tube, in which, when gases are blown in, a vortex that is cold on the inside and warm on the outside is created around the axis of the tube. None of these methods are suitable for introducing gas into liquid in a form and quantity desired for the use according to the invention.

A method is described in EP-A1-0314015 in which a gas is "bound" in the water, namely beyond the saturation value under the corresponding standard conditions. The gas is introduced into the water via a vortex thread. For this purpose, a container is provided, hereinafter referred to as perturbator ^* , which is connected via hose lines to a reaction chamber, hereinafter referred to as converter, in a closed circuit, with a liquid-conveying pump being provided in this circuit.

However, this method, which in and of itself works quite well, can still be improved. Other process steps are also found to be just as advantageous and expedient, which is reflected in particular in the favored "binding" of gas in the liquid and the longer shelf life of the reaction tion products. In this way, for example, comparably good results were achieved with nitrogen and water.

The method according to the invention uses the known, vortex-generating mode of operation of a cyclone, combined with additional method steps containing a smooth flow path and, as a result of an uninterrupted, extended, preferably repeated, cycle, the effect is increased to a greater extent, as in the characterizing features of Anspru¬ ches 2 or claims 3 or 4 described. Advantageous developments of the method are described in the features of claims 5 and 6.

The reaction chamber or the converter of EP-A1-0314015 is only very conditionally suitable for ensuring a uniform, rotating flow movement due to the described shape. The channels leading into the interior of the converter allow an approximately tangential inflow direction. However, in order to be effective in the manner of a cyclone, and thus particularly effective, the channels should on the one hand also be guided at an angle towards the closed apex of the converter interior and on the other hand have their outlet openings on the inside still if possible below the largest diameter of the converter interior (seen in relation to the direction of flow) .

Variants of the method according to the invention and the device described in the characterizing part of claims 7 to 13 for carrying out the method according to the invention, as well as possible variants for the component 3 are described by way of example with reference to the drawing. Show it: 1 shows a schematic representation of a device suitable for carrying out the method, partly in section;

2a and b variants of a perturbator;

3 shows a variant of a converter in cross section;

4 shows the compact arrangement of the device for carrying out the method according to the invention and

5a to c schematic arrangement variants for carrying out the method according to the invention.

The special measures consist in the introduction of a gas into a liquid in a multi-part device consisting of vor¬ preferably three, partly cyclone-like devices, which are referred to as perturbator 1, spinner 2 and converter 3, with this sub-mixing continuously in the circuit over several Hours, preferably at least 36 hours is operated (Fig.1).

Perturbator 1, spinner 2 and converter 3 are connected by means of hose lines 6 to form a closed circuit. The perturbator 1 consists of an approximately pear-shaped container 7 with a volume of 20 liters, for example. Its three-dimensional form can be imagined composed of a hollow spherical cap with a diameter of approx. If this three-dimensional form also proves to be particularly suitable for the course of the process, then good process results are achieved, especially with a different but always funnel-shaped design of the rotary body (e.g. dashed).

The pipe extension 21 is preferably inserted obliquely into the wall of the perturbator 1, in such a way that its axis 36 points obliquely from bottom to top by about 15° to the equatorial plane BB of the perturbator 1—preferably below it opening out - is inclined and with: it encloses an angle of about 45° with the plane passing through the axis of rotation 24 and the center point 30 of the tube attachment. The container 7 is filled with a liquid up to a level 9, via a filling opening 10 with an internal diameter of about 30 mm, which sits gas-tight on the upper side of the container 7 and can be shut off in the operating state (see also FIG. 4). On the upper side of the container 7' there is also a gas inlet 12 which can be shut off by means of a valve 8 and has a clear width of 8 mm, as well as a connection 13 for measuring devices (not shown). Above the liquid level 9 there is a gas space 14 into which gas, for example pure oxygen, was introduced via the gas inlet 12 .

The perturbator 1 is connected to the spinner 2 via a hose line 6b, any intermediate units 4 and a hose line 6c

which is designed as a cyclone-like mixing device for the liquid-gas mixture. It serves as an auxiliary unit between the perturbator 1 and the converter 3 and is located in front of the pump 5. The spatial shape of the spinner 2 corresponds to a hollow egg, which extends downwards in a funnel shape and opens out via an outflow opening 18 into the hose line 6d to the pump 5 . The feeding hose line 6c opens into the spinner 2 via a pipe part 16, the axis 37 of which opens obliquely from bottom to top at an angle of about 10° to the equatorial plane FF of the spinner 2, if necessary above this, and at an angle of approximately 45° to a plane determined by the axis of symmetry 17 of the spinner 2 and the center point of the inlet opening 31 . At its equatorial plane FF, the spinner 2 has a diameter which is at least twice the diameter of the supply hose line 6c. The outflow opening 18 of the spinner 2 is connected via a hose line 6d m ^* t to a preferably magnetically coupled pump 5, which has a minimum output of preferably 25 liters/min for the 20-liter perturbator system. From the pump 5 leads a hose line 6e, the cross section of which is approximately 10 to 15 mm smaller than the cross section of all other hose lines, which are dimensioned at 20 mm, to the lower inlet 19 of the converter 3.

The "heart" of the converter consists of a preferably egg-shaped hollow body 25 (length approx. 7 cm, diameter approx. 3.5 cm), in whose wall in a plane parallel to the equatorial plane DD of the hollow body 25 several obliquely channels 11 running below open tangentially. The axes of the channels 11 are inclined by preferably 45° relative to the equatorial plane D-D and relative to the axis of symmetry of the hollow body 25 . If the opening ends of the channels 11 in the interior of the hollow body 25 lie below the equatorial plane D-D, an optimal, cyclone-like functioning of the hollow body 25 is guaranteed. This egg-shaped hollow body 25 is introduced into an outer hollow body 39 and connected to it firmly and seamlessly, in such a way that the egg-shaped hollow body 25 is held above the channels 11 in the shape of a ring. This holder 27, which encloses the upper part of the egg-shaped hollow body 25, has a channel-like opening in its center, and thus also in the apex of the egg-shaped hollow body 25. This outlet channel 28, which has a diameter of preferably a maximum of 3 mm at the upper end, roughly corresponding to a nozzle, opens into an upper hollow body 40, the upper outlet 20 of which leads back into the perturbator 1 via a hose line 6a and via the pipe extension 21 . It is essential for the course of the process to design the transition between the lower part 39 of the inner wall of the hollow body on the ring-shaped holder 27 and the egg-shaped hollow body 25 in such a way that there are as few undesirable flow resistances as possible, i.e. a change that is as constant as possible, for example to ensure radii of the osculating circles.

The device shown in Fig. 1, which consists of a Pertur¬ bator 1, a spinner 2 and a converter 3, represents a variant of carrying out the method. If the process is carried out using only one perturbator 1 and one converter 3, as described for example in EP-A1-0314015, the process time is lengthened.

Instead of a single spinner 2, several of them, optionally up to ten, can be connected in series in an analogous manner. Instead of the spinner 2 described here, one (or more) perturbator(s) 1 can also be provided.

The position of the individual devices in relation to one another and in space is not necessarily fixed. The axes 17 and 38 of spinner 2 and converter 3 can be inclined or even horizontal, so that the designation used in the description of "above" and "below" for various parts of the device is only relative with reference to the drawing understand. The perturbator 1, as a liquid-receiving apparatus, must of course be positioned vertically, preferably in such a way that no other part of the device comes to lie above the level determined by the filling height 9 for the liquid.

In the operating state, the entire system, with the exception of the gas space 14, is filled with liquid, in particular water. When the pump 5 is switched on, liquid is conveyed in the direction of the arrows 22, with the tangential inflow of water into the container 7 creating a vortex. In the container 7, the surface of the water is changed from its resting position 9 to the funnel position 23 shown in dashed lines, with oxygen au; the gas space 14 is sucked into the liquid in the form of bubbles and conveyed further in the system according to the arrows 22, or is sucked and pressed.

During the course of the process, a gas space is formed in converter 3, which contains cavities 25 and 40 - 1 0 -

mostly filled. If the liquid-gas mixture flows according to the arrows 22, via the channels 11 tangentially into the hollow body 25, a liquid-gas coat rotating on the inner wall is formed there, which reverses at the lower end of the hollow body 25 with increasing rotational speed and whirls along the axis 38 in the form of a rapidly rotating vortex thread against the outlet nozzle 28, where it breaks off into the smallest liquid-gas mixed droplets and, with suitable dimensioning, and a vortex system is formed behind the nozzle edge. The expanded upper hollow body 40 into which the liquid mixture is injected acts as a diffuser. The parts of the liquid-gas mixture should have a maximum diameter of approx. 0.01 μm here, with suitable dimensioning of all components and a suitably selected pump capacity

The gas bubbles are distributed more and more finely as a result of the treatment in the various apparatuses. The resulting mixture is drawn off via an outlet valve 33 arranged in the hose line 6b, for example.

The process runs for several hours, preferably at least 36 hours, during which the gas obviously attaches itself to the liquid molecules, or imprints a stable, activated structure on the liquid over a long period of time.

It has proven to promote the process to switch on a turn (not shown) in the intermediate unit 4 between pert bator 1 and spinner 2, which for a system that is dimensioned according to a 20-liter perturbator, has a length of 6 m (for a the hose lines 6a-de speaking diameter of 20 mm and a helix diameter of 30 cm). The helix causes between the active phases of perturbator 1, spinner 2, converter 3 and pump a smooth flow path, which is of qualitative importance for the process result. It also saves about 20 to 30% of the time needed to achieve the same process result as compared to an apparatus without a helix.

Since the system is warmed up by the circulation and by the pump 5, it is expedient if--particularly in the intermediate unit 4--a cooling system is also provided, which keeps the circulating mixture at only 15 to 18.degree. With regard to the energy consumption and the desired result, this means a rationalization of the process. The mixture enters the coil at the bottom, which is located in a pot through which the cooling medium flows. However, it is also possible to carry out the cooling in a cooling jacket placed around the containers 1, 2 and 3 (see FIG. 4).

Under the conditions described here, for example, 55 to 60 ml of oxygen per liter of water are accumulated in 36 hours when passing through a helix, and 45 to 50 ml of oxygen per liter of water without a helix. For comparison: At room temperature and normal pressure, the natural oxygen saturation of the water in a pure oxygen atmosphere is 35 ml per liter, in air it is only about 7 ml per liter. Since the reaction product according to the invention, as mentioned, is stable over a long period of time, it can also retain 30 to 70% more oxygen in relation to air than corresponds to the previously known natural oxygen saturation (or solution).

The spatial forms of the perturbator 1 described in FIGS. 1 and 2a are possible variants. The one shown in FIG. 2b is characterized by particularly good results. Here one can imagine the three-dimensional form composed of two half-hyperboloids, which have the axis of symmetry 24" as the axis of rotation. These hyperboloids are connected to one another without any kinks by a flat, barrel-like center piece. This spatial form variant, like that in Fig. 2a shown three-dimensional shape, the advantageous property of assigning an ever smaller diameter to the vortex produced during the process, and thus increasing the rotational speed of the vortex funnel.

However, a particularly simple, inexpensive variant (not shown) for the container 7 of the perturbator 1 is also possible, which is designed to correspond to an inverted, wide bottle with an approximately funnel-shaped neck.

Whatever the spatial form of the perturbator 1 looks like, whether the upper part 7" or 7b is cylindrical, spherical cap, cone-shell or hyperboloid-shaped, the lower part 7' or 7a is cone-shell or hyperboloid-shaped, the corresponding ver¬ binding central part 35 is designed in the shape of a barrel or cylinder, then in all these cases it proves to be additionally beneficial to the process if the height h of the lower container part 7' or 7a is as large as possible compared to the radius r of the perturbator container 7 is selected (FIG. 2b) The vortex thread 26, which is important for the process, is then longer and therefore more effective.

The method was described using a perturbator 1 with a capacity of about 20 liters. Larger and also smaller embodiments are conceivable, with smaller dimensions (for example for a perturbator 1 holding approximately 5 l) for the converter 3 a variant corresponding to FIG. 3 proving to be advantageous. Here the channels 11' are not in the wall of the egg-shaped hollow body 25', the wall thickness of which would be too thin for that. The ring-shaped holder 27' is extended downwards in the manner of a ring, so that the channels 11' lie in this ring part. Access to the ducts 11' occurs here via guide ducts 32 which are mounted in the holder 27'. 4 shows a compact arrangement of the components spinner 2, perturbator 1, converter 3, pump 5 and coil 4 within an equipment cabinet 41, which at the same time assumes the function of the cooling unit. This arrangement, which can be designed, for example, as a 20 1, 10 1 or 5 1 system, based on the fluid content, could prove itself when used in doctor's surgeries, therapy centers, sanatoriums, etc. The combination of components shown in FIG. 4 is only one possible example; all other possibilities described above and also below are conceivable.

The liquid is filled in via a filling opening 10 which can be closed here with a standard ground cone 43 which has a cock which is closed at the end of the gassing. The filling level 9 for the liquid can be checked via a filling level indicator 42 . For this purpose, a viewing window can simply be provided in the equipment cabinet 41; however, the display is also possible via tubes that communicate with one another, with the connection to the perturbator 1 or the filling vessel being cut off after the filling level 9 has been reached. A gas reservoir 46 is filled from a gas bottle 45 and feeds the system with gas via the gas inlet opening. A plug-in contact 47 is provided for connecting the portable compact device to the mains power supply. The perturbator 1 is fastened in, for example, a ring-shaped holder 43, and the spinner 2 and converter 3 are arranged around the perturbator 1. Advantageously, a manometer 52 should be connected to the connection 13 provided for this purpose, in order to be able to determine any leaks that may occur in the system or functional defects.

5a to 5c show schematic arrangement variants for carrying out the method according to the invention, in which neither a perturbator 1 nor a converter 3 is required. Since this latter component in particular has a relatively complicated structure, its replacement be preferred by simpler and thus cheaper to produce components. Instead of the perturbator 1, other devices can be used by means of which gas can be introduced into liquid in a manner known per se. The effectiveness of the gas intake is increased by passing through several spinners 2, through one or more coils 4 and by continuously running through and repeating the same cycle. 5a, b and c show the very wide freedom in the number and choice of components that can be used (for the sake of clarity, cooling units are not shown).

In FIG. 5a, in addition to the already known components, a gas introduction device in the form of a vibrator 49 is provided, with gas being introduced into the liquid in a known manner from a gas space via a vibrating membrane provided with fine holes. This arrangement is provided in place of the perturbator. This introduction of gas should take place throughout the process. When running through the circuit, the liquid-gas mixture flows again and again through the mixing container of the vibrator and there is always the possibility of introducing additional gas into the gas-liquid mixture.

In FIG. 5b, instead of the vibrator, a suction device 50 is provided for the gas from a gas reservoir 46a, the mode of operation of which corresponds to the principle of a water jet pump. Instead, the device of FIG. 5c contains an atomizer 51, which brings liquid in a very finely nebulized form into the container filled with gas, which is provided instead of the perturbator. The liquid-gas mixture runs through the circuit in the manner described above, but in addition to increasing the effectiveness it can be atomized several times via the atomizing device, which is in the form of a nozzle or a centrifugal atomizer can be formed, are nebulized into the gas atmosphere. A variant of this consists in atomizing the liquid in an atomizer 51 and feeding it gas in a pulsating manner via a pressure wave generator 53 .

In all of these variants, care must be taken to ensure that the same direction of rotation of the gas-liquid mixture is ensured throughout the circuit in order to achieve a potentiation of the effect. However, the size of the spinners themselves could vary both in terms of volume and diameter-to-height ratio.

A fundamentally different way of running the process consists in introducing gas under increased pressure and/or reduced temperature into a liquid, i.e. dissolving it therein, and dissolving this gas-liquid mixture in, for example, one shown in FIG to c or to subject it to a corresponding cycle, the pressure being reduced and/or the temperature being increased step by step, until normal pressure or normal temperature is reached. Then, instead of the perturbator, a pressure vessel would have to be provided, which regulates the pressure in the vessel and thus also in the circuit via compensating valves; In order to be able to set the required temperature, the entire circuit should advantageously run in a thermostat-controlled environment (housing).

Examples of the effectiveness of the reaction product of water and oxygen for the therapeutic or prophylactic uses listed in the introduction are given below.

Example 1 :

In 1983 a - non-randomized - clinical study, which was not aimed at diabetes mellitus, ran with daily oral doses of 3 to 5 dl oxygen-water-reaction product. However, there were elderly diabetics among the subjects. After just a few days, the laboratory controls revealed the need to reduce the administration of the antidiabetics administered up to that point in the elderly diabetics. The reaction product was then orally administered to volunteer test persons with adult and adult-onset diabetes. They continued their usual way of life. All subjects were able to gradually reduce their diabetes medication after a few days. However, if they were no longer administered the oxygen-water reaction product, the sugar level would rise again before they could resume their usual medication. All subjects were willing to continue taking the reaction product, since they noticed a significantly better general condition and an increased willingness to perform.

Example 2 :

10 patients with a developed form of diabetic gangrene, which had affected the entire foot, were treated locally for two weeks exclusively with the oxygen-water reaction product. All patients were insulin-dependent diabetics, in whom the disease had existed for 8 to 15 years and in which changes in various organs had resulted. Only patients who had a process on the entire foot (toes, dorsum and planta) and were only affected by wet gangrene were included in the test group. The reaction product was applied to the wound using moistened, sterile gauze, over which came a dense bandage layer and a protective net. Before each application, the wounds were freed from detritus in the usual way. Such a treatment took place twice a day. As early as the third day, the erythema decreased both in extent and in color intensity. From the fifth day, the wounds became significantly drier and the excretion much less, which was accompanied by a reduction in the subjective complaints of the patients. went. In the second week of treatment there was a reduction in the extent or the surface of the process, the moistening stopped, except in the case of deep wounds - and here too it was significantly less compared to similar processes which were treated in a different way. After two weeks of treatment, a significant improvement was observed in 8 out of 10 patients. Although a satisfactory effect was achieved in the other two patients, the success was not comparably great because of the depth of the gangrene.

Example 3:

A doctor suffering from advanced thymus carcinoma and being treated with radiotherapy took the oxygen-water reaction product orally. She believed that the usual hangover from radiation, which led to great exhaustion after the radiation, did not occur if she took about 1 dl of the reaction product before the ^radiation .

This was the starting point for a study on 30 patients who were irradiated because of malignant diseases of the genital organs. Only those patients were included in the study in whom the symptoms of radiation hangover (nausea, anorexia, diarrhea, etc.) were clearly pronounced. Favorable responses were obtained in 74% of cases, while weak or even negative results were reported in 26% of cases. In this study, 50 ml of the reaction product was taken orally 3 times a day 20 minutes before meals.

Example 4:

Dry cornea (keratitis sicca) often occurs in contact lens wearers. Rinsing the cornea with the oxygen-water reaction product or dripping in the reaction product was found to be extremely soothing by 5 test persons. In addition, a large amount of experience material is included volunteer test persons who treated their "tired eyes" with the oxygen-water reaction product (eye bath, instillation with a pipette, spraying with a soft nozzle). The subjective impression of relief was significantly represented.

Example 5:

Several groups of patients, each with 7 to 10 participants, were treated with the oxygen-water reaction product because of wet zoster (varicella zoster) of intensive expression and different localization. It was used externally in two ways, namely by applying compresses, which were changed after about 4 hours on the one hand and moistened at least once after evaporation on the other. Diapers were used for large-area appearances in the intimate area.

The development of vesicles and crusts, the erythema, the development of pain and freedom from pain, and the development of new lesions were observed and recorded after 24 hours, 3 days, 5 days and 7 days. After 24 hours, the proliferation of blisters stopped. With severe symptoms, the pain subsided, with milder forms it had disappeared. After 3 days, edema was no longer detectable in any case. After 5 days, no clinical or subjective symptoms were observed in mild symptoms, and no erythema in severe forms. After 7 days, all cases were asymptomatic.

Example 6:

For the treatment of extremely stubborn ulcerative stomatitis and other stomatitis in a known manner d

Mouth rinsed by the doctor. After that, the patients rinsed very intensively at home about every hour with the oxygen-water reaction product. The last rinsing was carried out around 4 p.m., since resorption via the mucous membrane is ingested, with small amounts being swallowed, so that sensitive patients could have trouble falling asleep or sleeping through the night. After one week, all patients were symptom-free.

Example 7:

In the case of senile skin symptoms, dermatological investigations have shown that these skin symptoms have improved significantly after compresses with the oxygen-water reaction product, that the subcutaneous cell tissue was activated and the skin symptoms could be rubbed off mechanically by hand.

Claims

GEÄNDEKEE CLAIMS [received by the International Bureau on 16 October 1991 (10/16/91), original claim 1 amended; all other claims -unamended (3 pages)

1. Use of a reaction product of water and oxygen, the oxygen being present in the activated form under normal conditions and in an amount which is at least 30% above the saturation amount corresponding to normal conditions for the solution of the oxygen in the water, with the exclusion of fluorine compounds , for the manufacture of a medicament for the therapeutic and/or prophylactic treatment of herpes zoster, gangrene, mouth sores, eye diseases, adult-onset diabetes, torpid wounds, keratitis, radiation hangover or for the supportive treatment of exposure to loosely ionizing radiation.

2. A method for producing a reaction product according to An¬ claim 1, wherein the liquid or the liquid-gas mixture is pumped in a closed circuit and a) the gas in the form of tiny bubbles in a formed by the liquid - preferably around its vortex ¬ axis tumbling - vortex funnel and thread is drawn in and / or b) emerges from a nozzle into the gas atmosphere and / or c) forms a vortex thread with high rotational energy from the liquid-gas mixture in the gas atmosphere,

characterized in that at least one of the following process steps is also run through: d) two or more runs through at least one of the process steps a), b) and c); e) passing through a helical tube at least once; f) at least one-time, tangential inflow of the liquid-gas mixture into a cyclone-like mixing device filled with the liquid-gas mixture; g) introducing gas bubbles into the liquid at least once (or treating the liquid-gas mixture) by means of a vibration device and/or a pressure wave generator.

3. A method for producing a reaction product according to An¬ claim 1, wherein the liquid or the liquid-gas mixture is pumped in a closed circuit, characterized in that the following process steps are run through: a) the gas in the form of tiny bubbles in a of the

fluid formed - preferably tumbling about its vortex axis - vortex funnel and thread is drawn in and/or b) emerges from a nozzle into the gas atmosphere and/or c) forms a vortex thread with high rotational energy from the liquid-gas mixture in the gas atmosphere ,

characterized in that as a result of the passage through the nozzle, the liquid or the liquid-gas mixture is broken down into particles of at most 0.1 μm, preferably at most 0.001 μm.

4. A method for producing a reaction product according to claim 1, wherein the liquid or the liquid-gas mixture is pumped in a closed circuit, characterized characterized in that the following process steps are carried out: a) at least one-time, tangential inflow of the liquid-gas mixture into one of the liquid-gas

- 5 mixture filled, cyclonic mixing device; b) and at least one of the following process steps: b1) at least one-time introduction of gas bubbles in the

liquid or treatment of the liquid-gas mixture by means of a vibration device and/or a pressure wave generator; b2) introducing gas into liquid at elevated pressure and/or reduced temperature; b3) spraying the liquid at least once into the gas atmosphere; 15 and preferably c) passing through a coiled tube at least once.

5. The method according to any one of claims 2 to 4, characterized gekenn¬ characterized in that the cycle is started at elevated pressure and / or er¬ lower temperature and repeatedly run through 20, wherein the pressure is gradually or continuously reduced to normal pressure and / or the Temperature is increased to a maximum of room temperature.