RU2018106870A - Cell memory blocking device, respiratory gas mixture formation apparatus and method for treating oncological, bacterial, viral diseases, benign tumors with a mixture of oxygen and noble gases - Google Patents

Claims (17)

1. The apparatus for forming a respiratory gas mixture, including a container with compressed oxygen, a container with compressed argon, a regulator with an oxygen flow meter, a regulator with an argon flow meter, a timer, a breathing circuit formed by a carbon dioxide absorber, a 3-5-liter breathing bag, a valve inhalation, exhalation valve, mask on / off valve, patient mask, overpressure valve, connecting tubes, with an oxygen gas analyzer connected to the circuit, with the ability to connect to the device containers with compressed krypton and / or containers with compressed xenon, a regulator with a krypton flow meter and / or a regulator with a xenon flow meter, with the possibility of connecting an argon gas analyzer, a krypton gas analyzer and / or xenon gas analyzer to the breathing circuit, characterized in that the breathing bag has a volume 3-5 l is equipped with a connection / disconnection valve from the respiratory circuit; in addition to the breathing circuit, another 6-11 liter air bag is connected, which is also equipped with a connection valve / The shut down. 2. The device according to claim 1, characterized in that the device is equipped with a remote control unit with a remotely controlled regulator with an oxygen flow meter, a regulator with an argon flow meter, with remote-controlled valves for connecting / disconnecting breathing bags, with the ability to connect a remotely controlled regulator with a meter krypton flow rate and / or regulator with xenon flow meter, with remote control, with transmission / reception system with two transceivers, operating and a wired mode transmission using frequency division mode or in wireless transmission ultrasonic range for exchanging control signals between the unit and remote control data transmission from the analyzers oxygen, argon, krypton and xenon on the remote control. 3. A device for blocking cell memory for the treatment of human oncological, bacterial, viral diseases to combat the addiction of cells to the treatment, which is a separate module that looks like a room for several patients, the device is designed for effective electromagnetic shielding of a range of electromagnetic waves with wavelengths from 60 cm to 220 nm, for this the device walls are made of steel, and / or copper, and / or stainless steel sheets, or a three-layer steel-honey structure stainless steel is stainless, while the thickness of the layers of steel, for structural reasons, has a thickness of at least 1 mm., the inner layer of steel is made stainless for hygienic reasons, the copper layer has a thickness of at least 0.04 mm, for steel sheets all the seams are solid welded, the copper seams are sealed and / or rolled, the device has a door, has holes for the copper tubes of the air conditioning system inside the device, these holes are carefully electrically sealed, for example, sealed, no other holes the device does not have, the door, to ensure complete electromagnetic sealing, is equipped with a contact system around the perimeter, the contact system is placed on the door leaf itself, the door contact systems are made of round and / or pyramidal contacts made of phosphor bronze and / or brass, contact the connection is made adjustable to ensure uniform contact connection around the perimeter, for a three-layer structure of the walls of the device, each layer has its own contact connection on the door , even if the walls of the device are made single-layer, to improve reliability, the door contact system has three rows of contacts, the device is equipped with an internal air conditioning system, an internal air purification system from dust, an internal oxygen maintenance system, an internal carbon dioxide absorption system and power sources for these systems, necessary medical equipment is placed inside the device, for example, apparatus / apparatus for forming a respiratory gas mixture, furniture for seats I / the patient’s / patients’s lying, during the treatment procedures, the patients and the necessary attendants are inside the device, at this time to ensure full electromagnetic shielding inside the device in a given wavelength range, the device door is closed tightly to provide communication between inside and outside devices that use acoustic communication methods, for example, sound or ultrasound, for which in some places the walls of the device have low resistance, the apparatus / apparatus for forming the respiratory gas mixture used are those described in claim 1, in 2 or others, with similar characteristics, when using the apparatus according to claim 2, the remote control is placed outside the device, the transceivers of the transmit / receive system in the ultrasonic range are located from different sides of any of the walls of the device towards each other, i.e. one inside, the other outside the device, in any place where the information exchange signal between the transceivers is good enough for their reliable operation. 4. An individual cell memory blocking device for the treatment of human oncological, bacterial, viral diseases to combat the addiction of cells to the treatment, which is a room for one patient, with an approximate size of 0.5 * 1.0 * 2.0 m, which has the form cabinet, the device is designed for effective electromagnetic shielding of the range of electromagnetic waves with wavelengths from 60 cm to 220 nm, for this the device walls are made of steel, and / or copper, and / or stainless steel sheets, whether the three-layer structure is steel-copper-steel stainless, while the thickness of the layers of steel, based on structural considerations, has a thickness of at least 1 mm, the inner layer of steel is made stainless, based on hygienic considerations, the copper layer has a thickness of at least 0.04 mm, on steel sheets, all seams are solid welded, copper seams are sealed and / or rolled, the device has a door, has two ventilation holes, one at the top of the supply device and the second at the bottom for air outlet, in the place of organization of the device wall openings The thicknesses are up to 5–8 mm., holes are made round of the required diameters, at least 50 mm, both holes are equipped with a fitting filter system, the purpose of the fitting filter system is to provide the hole with the maximum possible attenuation of electromagnetic waves in a given frequency range from 60 cm to 220 nm , providing the hole with optimal resistance to air, gas or gas mixture, the fitting filter system is made of copper (copper-containing materials) or stainless steel, the fitting filter system is performed as follows: in the hole Fittings corresponding to the diameter of the hole have an external thread, on which nuts with locknuts are screwed towards each other on both sides, washers and flexible conductive gaskets are placed under the nuts, a conductive seal is used to seal the thread, thereby achieving a tight connection between the fittings and the device body , on the outside of the device, the fittings have a flat sealing threaded connection, which is usually used for gas media, each flat sealing threaded connection bakes the connection between the fitting and the removable special filter of the optical frequency range, the filter housings are also made of copper or stainless steel, one end of the filters has a flat sealing threaded connection for a reliable tight connection with its fitting, the diameter of the middle part of the filters can be increased to increase their throughput , filters are made collapsible for maintenance, filters consist of several parts connected by a threaded method, using a sealing mat In order to achieve tightness, inside each filter there are at least 2 filter elements, each of which is a compressed springy small metal copper or stainless steel chip or sponge, about 1 cm thick, each element is pressed to a state that white passage cannot be detected through it light, but air passing through it, when the filter element is inserted into the filter, the element, due to its springy structure, clings to the filter walls and does not move along it, between air remains as the dielectric element, it is checked that each filter provides attenuation in the optical frequency range of at least 30 dB and not more than three times increases the breathing resistance, the output of each filter not connected to the fitting is connected to its fan, below for the supply, at the top for exhaust ventilation, the outputs of the fittings inside the device are left free, the door is equipped with a contact system around the perimeter to ensure full electromagnetic sealing, a contact system placed on the door leaf itself, door contact systems are made of round and / or pyramidal contacts made of phosphor bronze and / or brass, the contact connection is made adjustable to ensure uniform contact connection around the perimeter, for a three-layer structure of the device walls for each layer, make its contact connection on the door, even if the walls of the device are made single-layer, to increase reliability, the door contact system has three rows of contacts, inside the device place the apparatus for forming the respiratory gas mixture, furniture for sitting / lying of the patient, during the treatment procedures the patient is inside the device, for the duration of the procedure to ensure full electromagnetic shielding inside the device in the specified wavelength range, the device door is tightly closed to power various equipment inside the device, a constant voltage of 12-24 V is used to supply power to the inside of the device and to organize the transmission of control signals and communication signals the system is equipped with two power terminals for which two through holes with a diameter of 6-7 mm are made, at the place of organization of the holes the walls of the device are thickened to 5-8 mm., each die is inserted with a dielectric sleeve 1 mm less than the length of the hole plus thickness 6 washers plus the thickness of two flexible conductive gaskets plus the thickness of two petals with a terminal, the outer diameter of the sleeve equal to the diameter of the hole, a metal stud with a thread corresponding to a diameter of 5-6 mm is inserted into the sleeve, on both sides of the stud and w put on the tab: a flexible conductive pad to improve contact, a copper washer, a thin dielectric pad from an electric cardboard or cotton fabric or cotton liner from another material with similar characteristics with a thickness of 0.10 mm, a copper washer, a petal tip with a terminal for connecting power, a copper washer, on both sides this design is fastened with a metal nut and a lock nut, control signals and communication signals are transmitted through the power terminals using frequency separation, if the device does not have power terminals, To ensure communication between the inside and the outside of the device, acoustic communication methods are used, for example, sound or ultrasound for which in some places the walls of the device have low resistance, devices for forming a respiratory gas mixture use those described in paragraph 2 or others, with similar characteristics, when using the devices according to claim 2, the remote control is placed outside the device, the transceivers of the transmit / receive system in the ultrasonic range are located on different sides of one of the walls of the device -keeping towards each other, i.e., one inside, the other outside the device, in any of the places where the information exchange signal between the transceivers is good enough for their reliable operation. 5. The device according to claim 4, characterized in that the device is sized for several people, which is a separate module that looks like a room, the vessels of compressed oxygen and argon gases are located outside the device, far from the apparatus for forming a respiratory gas mixture, for supplying oxygen and argon in the device make two holes, one for each gas, an additional hole is made for the overpressure of the apparatus for forming the respiratory gas mixture to exit from the device, I make all three holes t of one diameter, for example 1/2 inch, thicken up to 5 - 8 mm at the place of opening of the openings of the device, if metal pipes are used to supply gases from the pressure vessels of the compressed gas vessels to the device, metal pipes and a metal pressure valve are used to exit the overpressure , the pipe outlets from the device are carefully electrically sealed, then you do not need to install filters on these holes, otherwise all three holes are equipped with a fitting filter system similar to that described in paragraph 4, characterized in that inside of each filter there are at least 4 filter elements, each filter provides attenuation in the optical frequency range of at least 40 dB, an adapter sleeve is placed on the output of each filter that is not connected to the fitting to connect each filter according to its purpose to the gas reducer of the vessel with oxygen, to the gas reducer of the vessel with argon, to the overpressure valve, inside the device, respiratory gas mixture formation devices, for example, those described in paragraphs 1, 2, through the necessary valves and Khodnev couplings, connected to supply of oxygen and argon and excess pressure relief outlet. 6. The device according to claim 4, characterized in that the apparatus for forming a respiratory gas mixture is placed outside the device, for the procedures in the device make two additional holes for supplying and exiting breathing gas mixtures, each with a diameter of 3/4 inch, at the location of the holes the walls of the device are thickened to 5–8 mm, both holes are equipped with a fitting filter system similar to the fitting filter system described in paragraph 4, characterized in that the diameter of the middle part of the filters is 30–40 mm to increase the throughput, by the transition of both fittings inside the device puts a transitional copper or stainless clutch, for a transition to a diameter of 20 mm to connect the patient’s breathing circuit, the output of both filters of the fitting filter system outside the device also puts a transitional copper or stainless clutch for a transition to a diameter of 20 mm for connecting the respiratory circuit of the apparatus for forming the respiratory gas mixture, filters that work with the respiratory gas mixture must be thoroughly dried after each procedure to avoid loss their efficiency. 7. The device according to claim 4, characterized in that between the fans and the outputs of the filters of the system the fitting filter of the ventilation openings is placed by an active jammer, the housing of the active jammer is made, like the filter housing from copper or stainless steel, it is also permissible to place the producer in the housing filter, the main part of the director is an ultraviolet emitter with an average wavelength of 265 nm, which consists of several ultraviolet LEDs with a maximum radiation at different lengths waves, so that the total emission spectrum overlaps the range of 400 nm - 220 nm, one emitter is placed on the board, the board is passing along the air flow, the total capacity of the radiator is not less than 1.5 mW. 8. The device according to claim 7, characterized in that the apparatus for forming the respiratory gas mixture is placed outside the device, for carrying out procedures in the device make two additional holes equipped with a fitting filter system, the same as in claim 6, between each output of the filters the systems of the fitting filter of the breathing holes and the apparatus put the director of active interference, just like between the fans and the outputs of the filters of the system of the fitting filter of the ventilation holes according to claim 7. 9. The device according to p. 5, characterized in that between the fans and the outputs of the filters of the fitting-filter of the ventilation openings of the system put the director of active interference, as well as according to p. 7. 10. The apparatus according to claims 1 and 2, characterized in that the apparatus that is used in conjunction with the device according to claim 6 or claim 8 is additionally equipped with a circulation air pump with a capacity of 0.15 m ³ / min, the pump is connected between the system fitting fitting filter standing at the outlet of the respiratory gas mixture from the device according to claim 6 or 8 and the exhalation valve of the apparatus, the air pump is turned on so that its direction of action coincides with the direction of movement of the air mixture along the respiratory circuit. 11. The apparatus according to claims 1, 10, characterized in that the apparatus that is used outside the device is additionally equipped with a gas mixture heating unit with the possibility of heating the gas to a temperature of 90 degrees Celsius, the unit is placed at the gas mixture inlet at the device’s connection point fitting to a filter or an active jammer of a device. 12. A method of treating various diseases, characterized in that the treatment procedure is to find inside the device for blocking cell memory according to claims 3, 4, 5, 6, 7, 8, the necessary time without the use of any additional drugs with a tightly closed door, when active interference modules are turned on for the devices according to claim 7, 8. 13. The method according to p. 12, characterized in that the treatment is carried out after or while the patient is taking any drugs, for example, chemotherapy, antibiotics or inhalation of any drugs. 14. A method of treating cancer, bacterial, viral diseases, benign tumors with gas mixtures of oxygen and argon using an apparatus for forming a respiratory gas mixture, using a cell memory blocking device, characterized in that the treatment procedure is carried out inside the cell memory blocking device according to paragraphs. 3-8 when the door is tightly closed, active interference directors are included for the devices according to claim 7, 8, the method is a set of breathing procedures that are carried out using any apparatus for generating a respiratory gas mixture, including a container with compressed oxygen, a container with compressed argon, a regulator with an oxygen flow meter, a regulator with an argon flow meter, a timer, a breathing circuit formed by a 3-5 liter breathing bag, a carbon dioxide absorber, an inhalation valve, an exhalation valve, a valve reading / disabling the mask, patient mask, overpressure valve, connecting tubes, with an oxygen gas analyzer connected to the circuit, with an argon analyzer connected to the circuit, the device is located inside the device according to claims 3, 4, 5, 7 or outside the device according to claims. 6, 8, the breathing procedure is carried out along a half-closed circuit, before the start of the procedure, the valves at the containers with compressed oxygen and argon must be open, the mask valve must be closed, with the help of regulators with an oxygen and argon flow meter fill the respirator the bag with a gas mixture of oxygen and argon in the required ratio, when the bag is full, the patient exhales all the air out of himself, presses the mask tightly to the face, opens the valve valve and begins to breathe, during the whole procedure argon is fed into the circuit in a small flow of 1 l / min , oxygen is supplied with control by the gas analyzer of its required percentage, if the apparatus has an argon gas analyzer, then the percentage of argon is controlled, excess mixture from the respiratory circuit is vented through cells excess pressure panel, the procedure is monitored by a timer, after the procedure, the patient closes the mask valve, removes the mask from the face and is in the closed device for another 10 minutes, only after that the device door opens and the patient leaves the device, the percentage of oxygen and argon in the gas O2: Ar mixtures are selected based on the complexity of the disease and the patient’s condition, the higher the amount of argon, the greater the force of exposure, also take into account that the composition of the gas mixture from procedure to procedure is desirable it is necessary to change to combat the effect of addiction, therefore, they compose a weekly schedule of procedures, provided that the percentage of the gas mixture does not repeat for more than two consecutive days, and also begin the weekly course of procedures with a lower argon content, but not lower than 60% at an O2 ratio : Ar = 40: 60, and end with a higher argon content, preferably not higher than 80% with a ratio of O2: Ar = 20: 80, in special cases 90%, with a ratio of O2: Ar = 10: 90, the duration of one procedure is not less than 20 min and no more than 80 min, most often the total time I am carrying out procedures during the day does not exceed 80 minutes, during the week it is undesirable to take more than one day of a break from the procedures until the patient is completely treated. 15. A method for the treatment of cancer, bacterial, viral diseases, benign tumors with gas mixtures of oxygen and argon, using the apparatus for forming a respiratory gas mixture according to claim 1 or 2, using the cell memory blocking device according to claim 3-8, characterized in that the treatment procedure is carried out inside the device for blocking cellular memory with a tightly closed door, active interference directors are turned on for devices according to claims 7, 8, the device is inside the device according to claims 3, 4, 5, 7, or outside the device According to p. 6, 8, the method is a set of breathing procedures for a closed breathing circuit, before the procedure starts, valves are opened at containers with compressed oxygen and argon, the mask valve is closed, and using regulators with an oxygen and argon flow meter, they fill the breathing bag 6- 11 l with a gas mixture of oxygen and argon in the required ratio, close the valve on the vessel with compressed argon, fill the 3-5 l bag with one oxygen and connect it to the breathing circuit, the patient exhales all the air from himself, clearly presses the mask to the face, opens the valve valve and begins to breathe, during the entire initial procedure, which lasts 10 minutes, oxygen is supplied to the circuit with a flow of 5 - 7 l / min, excess mixture is vented from the breathing circuit through the overpressure valve, using an oxygen gas analyzer control its percentage, after 10 minutes, the oxygen analyzer should show an oxygen content in the circuit of at least 95%, the oxygen supply to the circuit is reduced to zero, wait until the patient exhales oxygen, i.e. a 3-5 liter bag will be filled, after that, using a valve, a breathing bag filled with a gas mixture is connected to a breathing bag of 6-11 liters, also a 3-5 liter bag will be disconnected from the circuit with a valve, the treatment procedure itself begins, the percentage is monitored by an oxygen gas analyzer the oxygen content, if necessary, correct by supplying the necessary amount of oxygen to the respiratory circuit, if there is argon in the apparatus of the gas analyzer, at the same time, the percentage of argon is controlled, the time of the treatment procedure they roll on a timer, after the procedure is completed, the patient closes the mask valve, also closes the valve on the vessel with compressed oxygen, the patient removes the mask from the face and is in the closed device for another 10 minutes, only after that the device door opens and the patient leaves the device, oxygen percentage and argon in the O2: Ar gas mixture is selected based on the complexity of the disease and the patient’s condition, the higher the amount of argon, the greater the force of exposure, also take into account that the composition of the gas mixture from procedure to the procedure is changed to combat the effect of addiction, therefore, a weekly schedule of procedures is compiled so that the percentage of the gas mixture does not repeat for more than two consecutive days, and the weekly course of the procedures begins with a lower argon content, but not lower than 60% at an O2 ratio : Ar = 40: 60, and end with a higher argon content, preferably not higher than 80% with a ratio of O2: Ar = 20: 80, in special cases 90%, with a ratio of O2: Ar = 10: 90, the duration of one procedure is not less than 20 minutes and not more than 80 minutes, most often common its duration of the procedures during the day does not exceed 80 minutes, during the week it is not allowed to take more than one day of a break from the procedures until the patient’s treatment is completed. 16. The method according to clause 15, characterized in that instead of argon, an argon / krypton mixture or an argon / xenon mixture or an argon / (xenon / krypton) mixture is used, a container with compressed krypton, a regulator with a krypton flow meter, a container with compressed xenon, a regulator with a xenon flow meter, it is desirable to add a xenon gas analyzer and / or krypton gas analyzer to the apparatus, while where in the method according to claim 14 the O2: Ar ratio is used, instead of Ar, an Ar / Kr or Ar / Xe mixture is used or Ar / (Kr / Xe), the ratio in the mixture is chosen based on the fact that argon in the mixture should be at least 50%, the weight of the resulting mixture is an effective factor in the mixture, i.e. the heavier the mixture, the more efficient it is, but argon should be at least 50%, when drawing up a weekly course of procedures, it must be taken into account that the percentage of the gas mixture does not repeat for more than two consecutive days. 17. The method according to PP.14, 15, 16, characterized in that to increase the effectiveness of the treatment, the gas mixture is heated up to a temperature of 90 degrees Celsius.