RU2055604C1 - Device for changing activity of biological cell - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device is made in form of unit, which performs reception, memorizing and transmission of electromagnet waves. Unit for changing temperature is connected to the unit mentioned, which is located close to biological cell. EFFECT: improved efficiency of treatment. 11 cl, 3 dwg

Description

 The invention relates to medicine, namely to medical equipment, and can be used to destroy pathogenic and conditionally pathogenic microorganisms in the human or animal body.

 A known apparatus for decimeter therapy, which contains an oscillator associated with a power meter through a control unit, and a contact type emitter connected in series with a power meter [1] In the process of the apparatus, a signal from a generator that sets the frequency of electromagnetic waves is transmitted to the control unit amplification, regulation of the power of electromagnetic waves and the establishment of the duration of the treatment procedure. Then the signal is fed to a power meter, which allows you to control the dosed power level, and then to the emitter, which is in direct contact with the patient.

 Although this device provides increased accuracy in the dosage of energy absorbed by the patient, it does not allow selective action on individual types of biological cells.

 A device for low-frequency therapy, containing a receiver of electromagnetic waves, a generator of continuous electromagnetic waves, a generator of pulsed electromagnetic waves, a switching unit, an irradiator, an electrode and a capacitor plate, and the above generators of electromagnetic waves are connected to the irradiator, electrode and capacitor plate through a switching unit [2] The use of the device is based on the use of correction of the state of regulatory systems of the human or animal organism with Strongly weak electromagnetic field of low frequency.

 The device operates in two main modes in diagnostic mode and in therapeutic mode. In the diagnostic mode, a pathological bioresonant frequency (or frequency spectrum) of a biological object is determined using a receiver, a generator of continuous electromagnetic waves, and an electrode. After determining the pathological bioresonance frequency, taking into account other medical indications, the regime of exposure to the pathological biological object is determined by the device (remotely or locally). In this case, the type of signals (pulsed or continuous), the amplitude and shape, therapeutic bioresonance frequency or frequency spectrum, and the duration of the procedure are determined.

 The choice of the type of electromagnetic waves, as well as the duration of the therapeutic procedure is carried out using a switching unit that connects a pulse or continuous oscillator to the irradiator, electrode or capacitor plate.

 The described device allows using electromagnetic waves of low intensity to carry out the correction of the biological cells.

 However, this device does not allow metered and selectively change the activity of biological cells of various types.

 The objective of the invention is to provide such a device for changing the activity of a biological cell, which would allow changing the activity of cells of one type without changing the activity of cells of other types due to the resonant interaction of electromagnetic waves of low intensity of the device and the cell at its bioresonant frequency.

 This problem is solved due to the fact that the device for changing the activity of a biological cell, containing a receiver and an electromagnetic wave generator located in close proximity to the cell, according to the invention has a memory unit connected to the receiver and the electromagnetic wave generator and a temperature change unit connected to the receiver , an electromagnetic wave generator and a memory unit, the receiver, a memory unit and an electromagnetic wave generator made in the form of a single element. This allows you to change the activity of cells of one type without changing the activity of cells of other types.

 It is advisable to use a solid substance as a single element. This ensures high reliability of the device.

 It is possible to use a liquid substance as a single element. This allows you to expand the functionality of the device.

 It is possible to use a crystal as a solid of a single element. This makes it possible to maintain the operability of the device for a long period of time.

 The temperature change unit can be made in the form of a resistive element connected to a source of electrical energy. This provides a wide range of temperature changes for a single element.

 It is advisable to use a crystal of a semiconductor device as a solid or liquid substance of a single element, and use at least one semiconductor junction of this device with an electric energy source connected to it as a temperature change unit. This allows you to reduce the size of the device.

 You can use a transistor as a semiconductor device, the emitter of which is connected directly to the source of electrical energy, and the collector through the switch, and the base of this transistor is connected to its collector through a resistor. This simplifies the device.

 It is advisable to provide the device with a shielding housing and a cover. This protects the information stored in the device’s memory from external influences.

 You can make the walls of the shielding housing and the cover of water-containing salt. This provides, together with effective shielding, an extension of the range of ambient temperature in which the device can be operated.

 You can make the walls of the shielding housing and cover hollow. This makes it possible to use liquids or bulk solids as a shielding substance.

 It is possible to fill the cavity of the walls of the shielding housing and the cover with water. This improves shielding performance.

 Figure 1 shows a General block diagram of the proposed device; figure 2 is a schematic diagram of one of the specific embodiments of the proposed device; figure 3 a specific embodiment of the shielding housing and cover of the proposed device.

 The proposed device contains a connected receiver 1, a memory unit 2 and an electromagnetic wave generator 3, as well as a temperature change unit 4 connected to each of these elements. The receiver 1, the memory unit 2 and the electromagnetic wave generator 3 can be interconnected in different ways, however, for ease of understanding of the invention, their series connection is described below. The receiver 1, the memory unit 2 and the electromagnetic wave generator 3 are made in the form of a single element 5.

 As a solid substance of a single element 5, any solid substances can be used, for example, copper, graphite, polyethylene, rosin, wood, etc. As a liquid substance, any liquid substance, for example, water can be used. It is most effective to use as a single element 5 substances having a crystalline structure, high melting and boiling points, high chemical resistance, low electrical conductivity and a minimum amount of impurities, for example, diamond, garnet, silicon, germanium, etc.

 Block 4 changes the temperature of a single element 5 can be made directly in the form of a source of electrical, mechanical, electromagnetic or any other energy. In this case, the temperature of a single element 5 can be changed, for example, due to the release of heat when an electric current passes through it, or due to the heat generated during the elastic deformation of a single element 5 or due to the absorption of electromagnetic waves by it, etc. However, it is most effective to use an element connected to a source of electrical, chemical, mechanical, electromagnetic, etc. as a temperature change unit 4. energies and located in close proximity to a single element 5 or in contact with it.

 The proposed device operates as follows.

 First, information on the metabolic activity of exemplary cells is recorded in memory unit 2 in any known manner. For example, in the immediate vicinity of a single element 5, sample cells 6 of a particular type are located that have metabolic activity predefined by any known method. Using unit 4, the temperature changes carry out heating of a single element 5. At the same time, information on the metabolic activity of sample cells 6 at the bioresonance frequency F is recorded in memory unit 2 using a receiver 1. Heating of a single element 5 can be carried out both with subsequent forced and natural cooling. Heating and cooling of a single element 5 can be carried out several times, for example, to increase the level of information recording. Heating, followed by cooling, or cooling, followed by heating, comprise a cycle of temperature change of a single element 5. After recording information on the metabolic activity of the sample cells 6 in the memory unit 2, the device is ready for operation. Then the cell 7, the biological activity of which must be changed (hereinafter referred to as irradiated), is placed in the immediate vicinity of the single element 5 and using the temperature change unit 4, a temperature change cycle of the single element 5 is carried out.

 When the temperature of a single element 5 changes, the generator 3 emits low-intensity electromagnetic waves at the bioresonance frequency F of the sample cells 6.

 As a result of the resonant interaction of electromagnetic waves emitted by the generator 4 of a single element 5 with the irradiated cell 7 at the bioresonance frequency F, the metabolic activity 5 of the irradiated cell 7 is set to a similar exemplary.

 The above recording and reproduction of information on the metabolic activity of exemplary cells 6 can be carried out using the temperature change unit 4, first in the cooling mode of a single element 5, and then its subsequent heating.

 As a single element 5 of the device can be used a crystal of a semiconductor device 8 (figure 2). In this case, at least one semiconductor junction of this device 8 with an electric energy source 9 connected to it is used as the temperature change unit 4.

 Figure 2 shows an embodiment of the device, where a transistor is used as the semiconductor device 8, the emitter of which is connected directly to the electric power source 9, and the collector K through the switch 10, and the base B of the transistor is connected to its collector K through the resistor 11.

 The device depicted in figure 2 works as follows.

 First, information is recorded on the transistor crystal about the metabolic activity of the exemplary cells 6 by any known method. For example, exemplary cells 6 having a predetermined metabolic activity established by any known method are placed in the immediate vicinity of the transistor. The electric energy source 9 is connected to the transistor by closing the switch 10. Due to the heat generation at the semiconductor junctions of the transistor, the transistor crystal is heated. The resistor 11 sets the operation mode of the transistor and, accordingly, the temperature of its crystal. When the transistor crystal is heated, information is recorded on it about the metabolic activity of the sample cells 6. Then, using the switch 10, the circuit of the source of electric energy 9 is opened. The transistor crystal is being cooled. Information can also be recorded in the cooling mode of the transistor crystal (8). After recording information on the metabolic activity of exemplary cells 6, the device is ready for operation.

 Next, the irradiated cell 7 (or a group of cells) are placed 5 in the immediate vicinity of the transistor and conduct a heating cycle and subsequent cooling of the transistor crystal, closing and then opening the switch 10. As a result of the resonant interaction of low-intensity electromagnetic waves of the device and the irradiated cell 7 and the bioresonance frequency F, the metabolic activity of the irradiated cell is set similar to the activity of the reference.

 To maintain a given metabolic activity of irradiated cells 7 for a long period of time, repeated irradiation sessions are carried out at certain time intervals. In this case, re-recording of information on the device is not carried out.

 Now, let us consider the operation of the device using a specific example of changes in the metabolic activity of bacterial cells of Stafylococcus aureus in the human body.

 First, a culture of Stafylococcus aureus cells is taken and, in any known manner, they are placed in a state with low metabolic activity.

 Then, by any known method, information on the low metabolic activity of Stafylococcus aureus cells is recorded in the memory 2 of a single element 5. For example, a culture of these cells is placed in the immediate vicinity of a single element 5 and a heating cycle is carried out, followed by cooling of a single element 5 using a temperature change unit 4.

 Next, the device is located in close proximity to a person and, using the temperature change unit 4, a heating and cooling cycle of a single element 5 is carried out. At the same time, the low-intensity electromagnetic waves of the device and Stafylococcus aureus cells in the human body resonantly interact at the bioresonance frequency F. B as a result, Stafylococcus aurues cells located in the human or animal body are set in a state of low metabolic activity similar to the activity of exemplary cells Stafylococcus aureus.

 To maintain low metabolic activity of Stafylococcus aureus cells that are in the human or animal body for a long period of time and subsequent destruction of these bacterial cells in the state of low metabolic activity by the human immune system, it is necessary to carry out several exposure cycles, for example, every 6 h for 3.5 days.

 The use of high-quality crystals provides long-term storage and stable reproduction of recorded information. The decrease in the level of information on the metabolic activity of the cell recorded on the transistor crystal does not exceed 3% of the initial after 1000 cycles of heating and cooling the transistor crystal.

The device allows for recording and storing information on the metabolic activity of sample cells 6 having different bioresonance frequencies F ₁ , F ₂ , F ₃ , F _n on a single crystal and simultaneously acting on similar types of cells at bioresonant frequencies, respectively, F ₁ , F ₂ , F ₃ , F _n .

To ensure the safety of information recorded in the device in storage mode, it is placed in a shielding case 12 with a cover 13, which protects the device from exposure to sources of strong thermal radiation, for example, burning alcohol, gasoline, a match, a cigarette, etc. Figure 3 shows a specific embodiment of the shielding housing 12 and the cover 13. A single element 5 and the temperature change device 4 are placed inside the housing 12. The housing 12 and the cover 13 can be made of water-containing salt, for example, magnesium sulfate, seven-water MgSO ₄ · 7H ₂ O, potassium sodium tartaric tetrahydrate KNaC ₄ H ₄ O ₆ · 4H ₂ O.

 The walls of the housing 12 and the cover 13 can be made hollow, and in the cavity of the walls of the housing 12 and the cover 13 can be placed, for example, water 14.

 The proposed device is effectively used to treat diseases caused by pathogenic and conditionally pathogenic microorganisms in the human or animal body.

 The effect of the device in the treatment of diseases caused by pathogenic and opportunistic microorganisms is based on a decrease in the rate of their development and activation of the human or animal immune system.

 A decrease in the rate of development of microorganisms is carried out by setting the potential on their cell membranes to a level corresponding to their low metabolic activity. An increase in the rate of destruction of microorganisms by the human or animal immune system is carried out automatically as the toxins secreted by the bacteria decrease due to a decrease in their metabolic activity. The device is effectively used in the treatment of, for example, diseases such as pneumonia, tonsillitis, rheumatoid arthritis, flu, meningitis, etc. The high selectivity and dosage of exposure, the simplicity and reliability of the device in combination with its small size creates the conditions for the use of the patented device in the treatment of a wide variety of human or animal diseases in both inpatient and outpatient settings. The device has no contraindications for conducting a parallel course of treatment with other methods.

Claims (11)

 1. DEVICE FOR CHANGING THE ACTIVITY OF A BIOLOGICAL CELL, comprising an exposure unit with receiving and transmitting electromagnetic waves located in the immediate vicinity of the biological cell, characterized in that the exposure unit is made as a single element with the storage of received electromagnetic waves, and also contains a unit temperature changes connected to the exposure unit.  2. The device according to p. 1, characterized in that the exposure unit is made in the form of a solid.  3. The device according to p. 1, characterized in that the exposure unit is made in the form of a liquid substance.  4. The device according to claim 2, characterized in that a crystal is used as a solid.  5. The device according to p. 1, characterized in that the temperature change unit is made in the form of a resistive element connected to an electric energy source.  6. The device according to claim 1, characterized in that a solid of a semiconductor device is used as the solid substance of the exposure unit, and at least one semiconductor junction of the semiconductor device with an electric energy source connected to it is used as a temperature change unit.  7. The device according to claim 6, characterized in that a transistor is used as a semiconductor device, the emitter of which is connected directly to the electric energy source, and the collector through the switch, while the base of the transistor is connected to its collector through a current-setting element.  8. The device according to paragraphs. 1 to 7, characterized in that it is equipped with a shielding housing with a cover.  9. The device according to p. 8, characterized in that the shielding housing and the cover are made of a material that is a water-containing salt.  10. The device according to p. 8, characterized in that the walls of the shielding housing and the cover are made hollow.  11. The device according to p. 8, characterized in that the cavity of the walls of the shielding housing and the cover are filled with water.

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