RU2232013C2 - Method for an impact of gaseous mixtures upon a body - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: an impact is performed upon a body with gaseous mixture containing oxygen and, at least, one gas diluter; moreover, curative impact is carried out due to changing both conditions and mode of impact at periodic substitution of one gaseous mixture for another and, also, due to changing, at least, one physical characteristics of the mixture introduced and/or its parameters, moreover, one should maintain oxygen within 12-85% limits. The present innovation enables to activate redox and energetic processes in patient's body, increase its specific adaptation to environmental alterations.

EFFECT: higher efficiency.

9 cl, 1 dwg, 7 ex

Description

The invention relates to medicine and medical equipment and is intended for use as a means for the treatment of broncho-pulmonary, cardiovascular and other diseases, including chronic ones, first aid, as anesthesia, as a rehabilitation means in the postoperative period, to relieve drug dependence syndrome and in a number of other cases, to increase the general nonspecific resistance of the body.

Recent advances in the field of hyperbaric physiology and diving medicine show that the development of new means and methods of breathing with unconventional gas means made it possible to purposefully apply the physicochemical properties and physiological effects of gas mixtures on the biological object, which include indifferent oxygen diluent gases. These gases primarily include helium, argon, nitrogen, hydrogen, krypton and xenon. Of particular interest in this regard is helium. Its physical properties: the density is almost 7 times lower than that of nitrogen, the main oxygen diluent gas in air, thermal conductivity is 5.8 times higher and the solubility in fats is 4.5 times lower than that of nitrogen at normal barometric pressure when breathing, they form physiological effects of oxygen-helium breathing mixtures that are different from air. These effects are used not only for deep-sea diving, but also in the treatment of a number of diseases of the respiratory system and the cardiovascular system, during inhalation anesthesia and in the period of postoperative rehabilitation (Hess DR, Acosta RH The effect of heliox on nebulizer function usinga beta-agonist bronchodilator. Hest 1999, 115 (1): 184-189).

Mixtures of oxygen and inert gases (helium, argon, neon, krypton, xenon) exhibit physiological activity under conditions of normal and high pressure. First of all, the physiological activity of indifferent gases is manifested in their narcotic action. So, xenon and krypton in a mixture with oxygen cause anesthesia even at normal barometric pressure, similar to the anesthetics used in medicine for pain relief. The narcotic properties of argon begin to appear at a pressure of 2 kgf / cm ² , and nitrogen at an increased pressure of 6 kgf / cm ² (this effect of nitrogen has been well studied in diving, and the human condition is called “nitrogen anesthesia”). Hydrogen in respiratory mixtures exhibits narcotic properties at a pressure above 20 kgf / cm ² . No significant narcotic effects were detected in neon and helium under pressure (Lazarev N.V. Biological effect of gases under pressure. - L .: Publishing House of the Military Medical Academy, 1941, p. 219; Salzman G.L. Physiological basis stay of a person in conditions of high pressure of the gas environment. - M .: Medgiz, c. 188, 1961; Zaltsman G.L., Kuchuk G.A., Gurgenidze A.G. Fundamentals of hyperbaric physiology. - L .: Medicine, p. 320, 1970; Brauer RW, Dimov S., Fructus X., et.al. Syndrome neurologique et electrographique des hautes pressions, Rev. Neurol., 1969, v. 121, p. 264-265; Smolin B. B ., Rapoport K.M., Kuchuk G.A. Materials on the narcotic effect of high pressure of nitrogen, argon and helium on the human body. In the book Physiology of humans and animals. - M., 1974, v.14; Bennett PB, Rostain JC The high pressure nervous syndrom, Phisiol, and med. Of diving, 4 ^th ed., 1993, p.195-237; Pavlov BN et al. The effect of hydrogen-containing respiratory gas mixtures on the manifestation of NSDS in rats under compression of 19 MPa. - Aerospace and environmental medicine, 1994.3, p. 37-40, etc.).

When studying the effect of argon on the course of hypoxic hypoxia at normal pressure, it was found that argon increases the resistance of the human body and mammals to oxygen starvation compared to nitrogen (Pavlov BN ,, Grigoriev AI, Smolin VV, Komardin IP, Sokolov GM, et. Al., Hyperoxic, normoxic and hypoxic oxygen-argon gaseous mixtures influence on humans under different pressures and respiration times. VTN International Meeting on High Biology, 1997, St. Peterburg, p.133-142; Shulagin Yu.A., Dyachenko A.I. , Pavlov BN Human gas exchange during physical exertion using for respiration and hypoxic UAN and KAA _p S. Collection of reports. “Indifferent g the basics in diving practice, biology and medicine. ”- M.: Slovo Publishing House, 2000, p.207-214) in gas mixtures similar in oxygen content.

In addition, helium has been successfully used in medicine for the treatment of bronchial obstructive diseases (bronchial asthma, etc.) (Barach AR, Science 1934, 80: 593; Troshikhin GV Organism in a helium-oxygen medium. - Leningrad: Nauka, 1989, p. 157; Kostylev EG Helium-oxygen therapy in the prevention of pulmonary complications in patients after operations on the abdominal organs. A-t. Doc. Dis. - M., 1991, p. 42). To increase the effectiveness of treatment with oxygen-helium mixtures, their heating is justified (Pavlov BN, Logunov AT et al. Method for forming a respiratory gas mixture and apparatus for its implementation. Priority of invention 20.09.1995. Patent No. 2072241). At the same time, some of the physiological effects revealed by the use of oxygen-helium mixtures cannot be explained by the physical properties of helium in the respiratory mixture: activation of the bioelectrical activity of the brain, suppression of catechalamines, activation of tissue respiration, stabilization and increase of the body's overall immunity. Explaining these phenomena, at the State Scientific Center of the Russian Federation “Institute of Biomedical Problems” of the Russian Academy of Sciences, the fundamental principles of molecular-cell gas “massage” explaining these phenomena were developed, the essence of which is the periodic effect of gas molecules on the synapses of the nervous system and cell structures in the process of gas saturation and desaturation when replacing one respiratory gas mixture with another (Pavlov B.N., Smolin V.V., Sokolov G.M. Brief history of hyperbaric development physiology and diving medicine. - M .: Publishing house “Slovo”, 1999, pp. 62-63). It is assumed that the anti-diffusion flow of molecules of various gases created during the implementation of the massage is accompanied by a number of changes in physiological processes at the cellular level, which positively affects the mobilization of the physiological reserves of the body. The described method of exposure to molecules of indifferent gases (oxygen diluent gases) is a hypothesis, since it does not stipulate any data on the chemical composition of gas mixtures, their percentage, the method of introduction into the body, the parameters of the state of gas mixtures, the sequence and order of their use, etc. . indicators. For this reason, the described method can not be applied neither in experimental nor in practical medicine, biology, veterinary medicine, etc.

The closest analogue adopted for the prototype of the claimed invention) is a method of forming a therapeutic gas mixture and an apparatus for its implementation according to the patent of the Russian Federation 2072241 of 1997 MKI A 61 M 16/00, according to which the gas mixture is supplied by a circulation stream to a breathing mask. In the process of preparing the gas mixture, it is mixed from the necessary constituent components, dosed, heated, inhaled substances are added and fed to the patient through the main gas channel. The exhaust gas mixture is passed in recirculation mode through microflora purification apparatus, an impurity absorber and a partial absorber of carbon dioxide and moisture, and then, at the signal of the gas analyzer, it is again brought to the required condition and fed to a breathing mask.

The disadvantage of this method is that it provides for the patient to be fed only one composition of the gas mixture during the procedure and only through a breathing mask with strictly defined parameters of the physical state of the gas mixture (temperature, pressure, percentage of components).

The objective of the invention is to enhance the oxidation-reduction and energy processes occurring in biological objects of different levels of structural and functional organization in order to activate their activities aimed at increasing their specific and non-specific adaptation to environmental changes. In particular, the objective of the method is to expand the scope of oxygen-containing gas mixtures in the treatment of broncho-pulmonary, cardiovascular diseases, including chronic ones, in first aid, as anesthesia, as a rehabilitation tool in the postoperative period, to relieve drug dependence syndrome and in other cases.

This problem is solved in that the method of exposure of gas mixtures to a biological object is carried out by removing the replaced gas mixture from the body placed in the environment and introducing a pre-metered and prepared replacement gas mixture containing oxygen and a solvent gas, followed by the biological object being in the replaced gas environment. The introduction of a replacement gas mixture into a biological object is carried out periodically with the simultaneous forced displacement of the replaced gas mixture by giving the dilution gas of the replacement gas mixture a higher partial pressure than the diluent gas of the replaced mixture or by lowering or increasing the pressure of the environment surrounding the biological object. When changing the physical characteristics and / or the quantitative and qualitative composition of the replacement gas mixture, the oxygen content in the composition of each mixture is maintained within 12-85%. When preparing a replacement oxygen-containing gas mixture, helium and / or argon and / or xenon and / or krypton and / or nitrogen and / or hydrogen and / or neon and / or sulfur hexafluoride can be used as a diluent gas, and / or methane and / or nitrous oxide, or mixtures thereof. In the process of replacing one gas mixture with another, an additional change is made in the quantitative and qualitative composition and / or physical characteristics of the replacement mixture. A replacement oxygen-containing gas mixture may be introduced through a breathing mask, and / or through an intubation tube, and / or through a helmet, and / or in an intensive care chamber, and / or under a local cap. Oxygen-containing gas mixtures are introduced in a natural or forced mode. The impact is carried out at a barometric pressure of 0.35-4 kgf / cm ² and at a temperature of 18-100 degrees Celsius. The period of introduction of the replacement mixture may be from 4 seconds to 24 hours. The biological object is exposed to this mixture after the introduction of the replacement gas mixture for 5 seconds to 7 days. The composition of the oxygen-containing gas mixture may include inhalation and / or therapeutic substances.

A comparative analysis of the proposed invention with the prototype shows that it differs in that the introduction of the replacement gas mixture into the biological object is carried out periodically with simultaneous forced displacement of the replaced gas mixture by giving the replacement gas mixture diluent gas a higher partial pressure than the replacement mixture diluent gas or by lowering or increasing the pressure of the environment surrounding the biological object. When changing the physical characteristics and / or the quantitative and qualitative composition of the replacement gas mixture, the oxygen content in the composition of each mixture is maintained within 12-85%. When preparing a replacement oxygen-containing gas mixture, helium and / or argon and / or xenon and / or krypton and / or nitrogen and / or hydrogen and / or neon and / or sulfur hexafluoride can be used as a diluent gas and / or methane and / or nitrous oxide or mixtures thereof. In the process of replacing one gas mixture with another, an additional change is made in the quantitative and qualitative composition and / or physical characteristics of the replacement mixture. A replacement oxygen-containing gas mixture may be introduced through a breathing mask, and / or through an intubation tube, and / or through a helmet, and / or in an intensive care chamber, and / or under a local cap. Oxygen-containing gas mixtures are introduced in a natural or forced mode. The impact is carried out at a barometric pressure of 0.35-4 kg / cm ² and at a temperature of 18-100 degrees Celsius. The period of introduction of the replacement mixture may be from 4 seconds to 24 hours. The biological object after the introduction of the replacement gas mixture is exposed to this mixture for 5 seconds to 7 days. The composition of the oxygen-containing gas mixture can be entered inhalation and therapeutic substances.

A comparative analysis indicates the presence of novelty in the proposed method.

Comparison of the claimed method with other known technical solutions for a similar purpose shows that the processes of saturation-desaturation, or desaturation-saturation, or simultaneously saturation-desaturation with one or different diluent gases and oxygen of cells and tissues in which physical and chemical interaction of molecules of one or different indifferent gases diffusing in one direction or towards each other with molecules, organelles, synapses and membrane membranes OK, accompanied by a number of physiological changes - changes in osmotic pressure, the threshold of excitability of cells, microcirculation, etc., which, ultimately, leads to increased resistance of the organism. The introduction into the composition of gas mixtures of inhalation and therapeutic substances expands the scope of application of the proposed method. It can be used in the treatment of bronchopulmonary, cardiovascular diseases, including those of a chronic nature, first aid, as anesthesia, as a rehabilitation tool in the postoperative period, to relieve drug dependence syndrome and in other cases, when an increase in the general non-specific resistance of the body.

This comparison indicates the excess of the claimed prior art by the claimed invention and the solution of the task with its help.

The basis of the method is the periodic forced replacement in a biological object of one (replaceable) gas mixture with another (substitute), which includes the same gas with a different partial pressure or a different oxygen diluent gas than in the replaced mixture. In this case, forced displacement of the replaced gas mixture occurs by imparting a higher partial pressure to the diluent gas of the replacement gas mixture than the diluent gas of the replaced mixture or by lowering or increasing the pressure of the environment surrounding the living organism. As a result of the variation of these effects, transmembrane and intracellular metabolism is activated, tissue respiration, the synthesis of hormones, indicators and other biologically active substances are activated, the adaptation processes shift to the anabolic stage and, as a result, the totality of all effects, including the physical properties of gases, increases non-specific resistance of the body.

The essence of the proposed method is illustrated by examples of saturation-desaturation of oxygen-containing gas mixtures. In all cells of the human body as a biological object, from 1 to 2 liters of nitrogen is dissolved under normal barometric pressure. When breathing a helium-oxygen mixture, when the partial pressure of nitrogen in the cell exceeds its partial pressure in the mixture, nitrogen tends to diffuse out of the cell, and helium molecules take its place. A peculiar molecular-cell massage of the body occurs. The same effect is observed with all other gas mixtures, oxygen diluent gases in which inert gases can act: helium, argon, neon, xenon, krypton, as well as nitrogen, hydrogen, sulfur hexafluoride, methane, nitrous oxide, etc. ., as well as mixtures thereof. Various tissues in the body are saturated, and therefore, desaturated differently, therefore, the anti-diffusion of gases in these tissues is not the same. The degree of tissue saturation with gases depends on the time of saturation, the difference in the partial pressures of a particular gas in the environment and tissues, the method of its supply and the physical state of the gas: on the temperature of the gas mixture, its humidity, and also on the ambient pressure. Its temperature is especially relevant for a helium-oxygen mixture: heating the mixture much higher than thermoneutral temperature (body temperature) ensures uniformity and high heat transfer in the human ducts and lung tissue, improves the rheological properties of sputum, facilitates its drainage, improves capillary blood flow in the lungs and stimulates thermo and chemoreceptors.

Helium-oxygen mixture is fed into the human body cyclically. The delivery time can be from one breath (approximately 4 seconds) to 24 hours, the break time can be the same - this is due to the level of exposure of various gases to different tissues and the physical condition of a person adequate to his illness. Numerous experiments conducted indicate that in 24 hours there is almost complete desaturation and, accordingly, the saturation of even bone tissue with oxygen-containing gas mixtures and it is not practical to lengthen this time. The pressure of the environment also affects the time of saturation and desaturation, the optimal value of which is in the range from 0.35 to 4 kgf / cm ² . After the introduction of the replacement gas mixture, a break may occur from 5 seconds to 7 days.

The number of variations in the use of oxygen-containing gas mixtures, their physical and quantitative states, the percentage of components included in the gas mixture, the order of saturation-desaturation of the body, the devices and equipment used in this case are practically unlimited, for each specific patient in each case these parameters are selected individually , but at the same time, among other things (the patient’s condition, compliance with the specified modes and sequences, etc.), it is necessary to ensure that o complete saturation of the body tissues with the use of oxygen-containing gas mixtures, which can cause the opposite effect to the therapeutic one. With all changes in physical characteristics and / or quantitative and qualitative composition of the replacement gas mixture, the oxygen content in the composition of each mixture should be in the range of 12-85%.

Assessment of the degree of saturation of blood and tissues with gases dissolved in them is determined by the formula

P = P _g + P _O2 + P _CO2 + P _H2O -B-T,

where P _ig , P _O2 , P _CO2 , P _H2O are the partial pressures of indifferent gases, oxygen, carbon dioxide and water vapor, respectively;

B is the external pressure of the environment;

T - blood pressure in the bloodstream or elastic tissue pressure.

In the process of replacing one gas mixture with another, an additional change in the quantitative and qualitative composition and / or physical characteristics of the replacement mixture can be made.

The oxygen-containing gas mixture is introduced through a breathing mask, or through an intubation tube, or through a helmet, or in an intensive care chamber, or under a local cap, or a combination thereof. This allows you to localize the effect of the process of saturation-desaturation of the body with gas mixtures or to spread it to the whole body. In addition, it is possible to introduce a replacement oxygen-containing gas mixture through a breathing mask, or through an intubation tube, or through a helmet simultaneously with cardiopulmonary bypass, and the blood is saturated with xenon or krypton anesthetizing gas, which expands the possibilities of using the method during surgical operations.

The method can be carried out at temperatures of gas mixtures from 18 to 100 degrees Celsius.

The effectiveness of the application of the method can be increased by the introduction of inhaled and / or therapeutic substances into the gas mixture.

The quantitative and qualitative composition of the replacement gas mixture, its constituent components, and the order of introduction of the mixtures are preliminarily determined depending on the human tissues exposed and their condition, and in the process of replacing the gas mixtures, the human condition is constantly monitored.

Example 1. Depending on the condition of the patient, the initial parameters of the procedure are established: the time of the procedure, the temperature of the helium-oxygen gas mixture, the percentage of oxygen in its composition. At the same time, the patient controls the oxygen content in the blood, pulse rate, and the percentage of carbon dioxide in the exhaled mixture. After 3-7 minutes of the procedure, the oxygen content in the blood and the percentage of carbon dioxide in the exhaled gas mixture stabilizes (for a healthy person, the content of oxyhemoglobin in the blood is 98-99%, and the carbon dioxide content in the exhaled mixture is 4.8-5.2% ) As soon as the process stabilizes, the procedure is interrupted for 5-7 minutes, then it is repeated. During the procedure, partial saturation of the tissues with helium and desaturation with nitrogen occurs; when the procedure is interrupted, the process goes in the opposite direction. The procedure is repeated no more than three times, after which they take a longer break, optimally from 3 to 4 hours, but not more than a day. The patient's condition is monitored both during the procedure and in breaks.

During the procedure, depending on the individual characteristics and condition of the patient, various options for its implementation are possible: for example, a slow increase in the partial pressure of oxygen in the blood, a change in the oxygen content in the gas mixture from 21 to 35-40%. The oxygen content in the blood can increase not only due to ventilation of the lungs, but also due to the antidiffusion of oxygen in the tissues. Moreover, the physical properties of helium and its temperature, especially if it is much higher than thermoneutral, play their positive role, noted above.

Example 2. The patient is placed in a pressure chamber, the environment of which is air. The ambient temperature is set to 28-32 degrees Celsius, the pressure is raised to 3 kgf / cm ² . The patient is maintained at this pressure for 20 minutes. Then the patient is given an oxygen-helium gas mixture, decompressed to 1.2 kgf / cm ² and incubated for 15 minutes, after which an oxygen-argon gas mixture is fed for 15 minutes and decompressed to normobaric. During the procedure, the oxygen content in gas mixtures remains constant, equal to 23-25%.

Example 3. The conditions and modes of the procedure are the same as in example 2, however, instead of increasing the pressure of the gas mixtures create a vacuum up to 0.35-0.4 kgf / cm ² . At the same time, at the lowest pressure values of the gas mixture, breathing is performed with an oxygen-argon mixture.

Example 4. The procedure is carried out at normobaric pressure of the environment. The patient is given a helium-oxygen gas mixture for 3-8 minutes, then an oxygen-argon mixture for 3-8 minutes, after which they take a break for 1-2 hours and the cycle repeats 2-3 times. During the procedure, the temperature of the argon-oxygen gas mixture is 15-20 degrees Celsius below the temperature of the helium-oxygen gas mixture. The oxygen content in gas mixtures is kept constant in the range of 26-28%.

Example 5. The conditions and modes of the procedure are the same as in example 4, however, the oxygen content in gas mixtures varies from 28 to 14% and vice versa at a constant temperature.

The proposed method allows the use of inert gases in a mixture with oxygen as new non-medicament means of improving, rehabilitating and therapeutic effects on the human body.

Example 6. The procedure is carried out in a pressure chamber. The patient breathes air at normal pressure. The pressure chamber is closed, the pressure is reduced to - 0.6 kgf / cm ² , at this pressure the patient breathes rarefied air for 3-4 minutes, and the pressure returns to normal, after 5-6 minutes the procedure is repeated. For a session of such effects, spend 5-6 times daily, the course is 6-7 days.

Example 7. The procedure is carried out in a pressure chamber. The patient breathes air at normal pressure. The pressure chamber is closed, the air pressure is increased to 2.0 kgf / cm ² , at this pressure, the patient breathes compressed air for 10 minutes and then decompress to normal pressure. The procedure is repeated 3-4 times, with each subsequent time the time spent under pressure is reduced by 2 minutes. The course of treatment is 3-5 days.

The diagram shows the possible options for the interaction of gas mixtures in various combinations on a biological object.

Claims (10)

1. The method of exposure to the body of a gas mixture containing oxygen and at least one diluent gas, characterized in that the exposure is carried out by changing the conditions and mode of exposure with a periodic change of one gas mixture to another gas mixture, characterized by composition and / or physical characteristics, moreover, the stage of exposure to a gas mixture of a certain composition is carried out with a change in at least one of the physical characteristics of the mixture and / or parameters characterizing the mode of exposure, and maintaining the oxygen content in it is in the range of 12-85%. 2. The method according to claim 1, characterized in that the replacement of one gas mixture with another is carried out with the provision of forced displacement of at least one gas component from the body. 3. The method according to claim 1, characterized in that the replacement gas mixture is introduced into the body by giving the replacement gas diluent a higher partial pressure than the gas component displaced from the body. 4. The method according to claim 1, characterized in that the replacement gas mixture is introduced into the body by lowering or increasing the pressure of the gas medium into which the body is placed. 5. The method according to claim 1, characterized in that the exposure to the replacement gas mixture is carried out with a change in its oxygen content. 6. The method according to claim 1, characterized in that the replacement gas mixture is introduced into the body at a temperature of 18-100 ° C, and the temperature is kept constant or is changed within the specified limits. 7. The method according to claim 1, characterized in that the period of introduction of the replacement gas mixture is from 4 s to 24 hours 8. The method according to claim 1, characterized in that inhalation substances are introduced into the composition of the replacement gas mixture. 9. The method according to claim 1, characterized in that therapeutic agents are introduced into the composition of the replacement gas mixture. 10. The method according to claim 1, characterized in that helium and / or argon and / or xenon and / or krypton and / or neon and / or nitrogen are introduced into the composition of the replacement gas mixture as a replacement gas diluent , and / or hydrogen, and / or hexophosphorus sulfur, and / or methane, and / or nitrous oxide, or mixtures thereof.