RU2604129C2 - Agent for increasing resistance to hypoxia - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to agent for increasing resistance to hypoxia, intended for oral administration. Agent represents 0.3-0.5 % solution of hydrogen peroxide, oxygen at excess pressure of 0.2 ATM at +8 °C and drinking water.

EFFECT: invention implementation provides higher body resistance to hypoxia in conditions of respiratory distress due to additional involvement in gas exchange of gastric mucosa, intragastric ingress of oxygen in blood.

1 cl, 1 tbl

Description

The invention relates to medicine, in particular to ambulance, resuscitation and pharmacy, and can be used to revive clinical death.

Known hypergas and hyperosmotic antiseptic intended for the repair of purulent wounds, cavities and fistulas, containing 2.7-3.0% hydrogen peroxide, 0.9-10.0% sodium chloride, water for injection (the rest) and carbon dioxide up to creating an excess pressure of 0.2 atm at + 8 ° C (RU 2331441).

The disadvantage of this tool is a narrow range of applications, low safety and effectiveness. The fact is that the agent excessively violently foams the contents of the oral cavity, larynx, esophagus and stomach when taken orally. This is due to the fact that carbon dioxide is rapidly released from it, since carbon dioxide is in a known medium under overpressure. When the agent interacts with the liquid contents of the digestive tract, carbon dioxide is intensively formed, the bubbles of which form a foam, since proteins are contained in saliva, mucus and gastric juice, which increase the viscosity and surface tension of these fluids. Moreover, the foam is formed not only due to the release of carbon dioxide, but also due to the release of oxygen gas. This is due to the fact that the contents of the oral cavity, larynx, esophagus and stomach in people requiring emergency care are not sterile, therefore, microbial decomposition of the remnants of food masses, cells of desquamated epithelium occurs inside these cavities, and in some people additionally form purulent masses. In particular, purulent masses can be located on the surface of diseased teeth in the area of caries and periodontal disease, on the surface of the pharyngeal tonsils in people suffering from tonsillitis, on the surface of the larynx in people suffering from acute respiratory diseases (ARI), on the surface of the mucous membrane of the esophagus and stomach in people suffering from esophagitis and gastritis. In addition, in some people, there may be blood in the oral cavity, as injuries to oral tissue are possible. In addition, some people have bleeding gums. Blood and purulent masses contain catalase - an enzyme under the influence of which the catalase release of oxygen gas from hydrogen peroxide takes place. Since hydrogen peroxide is in a known means in high concentration, the interaction of the means with blood and / or pus causes an intense formation of oxygen gas.

Excessively active and rapid foaming of saliva, mucus and gastric juice forms a foam, the volume of which increases very quickly to excessively large values. The increasing volume of the foam makes it rampantly move in all possible directions. Therefore, immediately after the introduction of funds into the oral cavity, foam is formed almost instantly. Moreover, the foam is formed in the oral cavity and larynx before the completion of the process of swallowing the drug and getting it into the stomach. Therefore, the foam fills all possible cavities, including the nasopharynx, nasal cavity, larynx and threatens to disturb the ventilation of the upper respiratory tract.

In addition, the tool does not ensure the stability of the osmotic pressure within the physiological norm for the liquid contents of the gastrointestinal tract and larynx, since it has a high concentration of ingredients, which gives the agent hyperosmotic activity. The presence of hyperosmotic activity gives the drug a local irritant effect, which, in turn, causes a cough and runny nose. The local irritant effect exerted by a known agent on the mucous membrane of the larynx aggravates the pathological condition of a person, especially if he has hypoxia due to respiratory failure.

Known tool for removing sulfuric plugs, which is a solution consisting of 0.3-0.5% hydrogen peroxide, 1.7-2.3% sodium bicarbonate and water for injection (the rest) (RU 2468776).

The disadvantage of this tool is a narrow range of applications, low safety and effectiveness. The fact is that the product contains sodium bicarbonate, which, when reacted with hydrochloric acid of the gastric juice, forms carbon dioxide. The rapid release of carbon dioxide inside the stomach neutralizes the hydrochloric acid of the gastric juice, worsens the quality of the gastric juice, and therefore contributes to the development of foodborne infection and putrefactive processes in the stomach. At the same time, the pressure of carbon dioxide increases inside the stomach, which, being under excessive pressure, irritates the gastric mucosa, causes the formation of hyperemia, and enhances its blood supply. Under these conditions, the absorption of carbon dioxide into the blood increases. As a result, the concentration of carbon dioxide in the blood flowing from the stomach to the heart increases, which changes the buffer and acid activity of blood plasma, since it increases the alkalinity of the plasma and shifts the buffer capacity to the alkaline side. In other words, alkalization of the blood occurs. Therefore, the known agent promotes the development of alkalosis. At the same time, the gas composition of the blood deteriorates, the concentration of carbon dioxide in the blood increases, which exacerbates the symptoms of hypoxic hypoxia, especially significantly in patients with respiratory failure.

A hyperoxygenated agent is known for saturating donated venous blood with oxygen, consisting of 0.85% sodium chloride, 0.10% sodium bicarbonate, 0.05-0.29% hydrogen peroxide and water for injection (RU 2538662).

The disadvantage of this tool is a narrow range of applications, low safety and effectiveness. The fact is that the product contains a low concentration of hydrogen peroxide. In this regard, the known tool when interacting with the contents of the oral cavity, larynx, esophagus and stomach does not provide intensive formation of oxygen gas, therefore, the tool is not able to quickly generate a sufficient amount of oxygen gas and is not able to quickly increase the amount of oxygen gas in the stomach. However, the tool does not provide rapid stimulation of oxygen absorption in the stomach and therefore does not provide emergency hyperbaric oxygenation in the stomach cavity.

In addition, the known agent contains sodium bicarbonate, which, when reacted with hydrochloric acid of gastric juice, forms carbon dioxide. The rapid release of carbon dioxide inside the stomach exceeds in its intensity the release of oxygen gas, so the concentration of carbon dioxide in the stomach exceeds 90%. In addition, sodium bicarbonate neutralizes the hydrochloric acid of the gastric juice, increases its pH and reduces the disinfecting activity of the juice. Therefore, the known tool contributes to the development of foodborne infections and rotting food masses in the stomach. At the same time, the pressure of carbon dioxide increases inside the stomach, which, being under excessive pressure, irritates the gastric mucosa, causes hyperemia in it, increases its blood supply and absorption. Therefore, carbon dioxide is actively absorbed from the stomach into the blood. As a result, the concentration of carbon dioxide in the blood flowing from the stomach to the heart increases, which shifts the alkalinity of the blood plasma to the alkaline side. In this case, alkalization of blood occurs. Therefore, the known agent promotes the development of alkalosis. At the same time, the concentration of carbon dioxide in the blood rises, which exacerbates the symptoms of hypoxic hypoxia, especially significantly in patients with respiratory failure.

It is known a means intended for oral administration - nootropil solution for oral administration of a 20% 125 ml bottle containing 20% piracetam and the following excipients, without regard to their concentration: glycerol, sodium saccharin, sodium acetate, methyl parahydroxybenzoate, propyl parahydroxybenzoate, apricot flavor, caramel flavor , glacial acetic acid, water (http: www.eapteka-msk.ru> model.php? id = 50021808 (accessed: 01/22/2015).

The disadvantage of this tool is a narrow scope, low safety and effectiveness. The fact is that when administered internally, the agent reduces the level of oxygen in the blood flowing from the stomach and worsens its quality due to the lack of oxygen in the agent itself, due to the dilution of blood by this agent and due to the enrichment with auxiliary substances that increase the likelihood the development of an allergic reaction, including anaphylactic shock. In addition, the drug aggravates metabolic acidosis due to the presence of glacial acetic acid and an increase in its concentration in plasma, promotes plasma acidification and a decrease in its pH, which contributes to acidosis and increased hypoxic damage to the body in conditions of cardiopulmonary insufficiency.

The objective of the invention is the expansion of the scope, increasing safety and effectiveness by increasing the area of gas exchange, intragastric hyperbaric oxygenation, oxygenation of plasma and blood cells, the use of the gastric mucosa to absorb oxygen into the blood and release carbon dioxide from the blood, stabilize the concentration of red blood cells in the blood and circulating blood volume.

This goal is achieved through a drug that provides increased resistance to hypoxia in conditions of respiratory failure due to the additional involvement of gas into the gas mucous membrane of the stomach, intragastric oxygen supply to the blood, oxygenation of plasma and blood cells, stabilization of the concentration of red blood cells and circulating volume blood.

The essence of the proposed means for intragastric hyperbaric oxygenation containing gas at an overpressure of 0.2 atm at + 8 ° C, 0.3-0.5% hydrogen peroxide and water, consists in the fact that the agent contains drinking water as water as a gas contains oxygen in the following ratio of components, wt. %:

Hydrogen peroxide 0.3-0.5 Oxygen to create an overpressure of 0.2 atm at + 8 ° C Drinking water Rest

The fact is that a solution containing 0.3-0.5% hydrogen peroxide in drinking water and oxygen gas at an excess pressure of 0.2 atm at + 8 ° C is moderately carbonated water with oxygen. In this regard, the claimed tool is an oxygenated drinking water, similar to a food product - drinking water, moderately carbonated with carbon dioxide. Therefore, similarly to such carbonated drinking (or mineral) water, carbonated with carbon dioxide, the claimed means after ingestion begins to release gas from the water, but this is not carbon dioxide, but oxygen. The release of oxygen gas bubbles in water begins already at the beginning of the digestive tract, that is, in the oral cavity, since oxygen is in excess pressure in the water. The rate of formation of oxygen gas bubbles in water is the same as the rate of formation of carbon dioxide bubbles in drinking water in the presence of carbon dioxide under the same excess pressure. After the drug enters the stomach, oxygen gas continues to be rapidly released from the water, so the cavity of the stomach increases in volume. In this case, the wall of the stomach is stretched and baro- and mechanoreceptors are excited in it. Excitation of these receptors causes an increase in the tonus of smooth muscles in the wall of the stomach. An increase in the tonus of the wall of the stomach, together with an increase in the volume of oxygen gas inside the cavity of the stomach, leads to an increase in intragastric pressure. A few tens of seconds after ingestion, the release of oxygen gas, which is in the water inside the stomach under excessive pressure, begins to decrease. A decrease in the intensity of oxygen gas evolution occurs because the reserves of dissolved oxygen gas are depleted and at the same time, the intragastric pressure that oxygen gas creates itself increases. Under these conditions, the process of separation of dissolved oxygen gas from the water is completed after the pressure inside the stomach cavity rises to the value of the excess pressure of the oxygen gas dissolved in the water inside the stomach cavity. In parallel with this, when the claimed agent interacts with the contents of the stomach, the catalase reaction of the breakdown of hydrogen peroxide immediately begins. As a result, the tool begins to release oxygen gas released from hydrogen peroxide. This process flows inside the stomach more slowly than the process of evolution of oxygen gas dissolved in water under excessive pressure. Oxygen, slowly released from hydrogen peroxide, continues to maintain excess pressure inside the stomach. This occurs despite the fact that in the same period of time, some of the injected agent begins to be absorbed into the blood in liquid and gaseous form. Drinking water diluted with gastric juice is absorbed in liquid form with the remains of oxygen gas and hydrogen peroxide dissolved in it. Absorption of this liquid and gas in the stomach is not able to reduce the pressure inside the cavity of the stomach, since the volume of the absorbed liquid is several times less than the volume of the oxygen gas generated in parallel in the stomach cavity. At the same time, water is absorbed into the blood together with oxygen dissolved in it and with dissolved hydrogen peroxide. After absorption, hydrogen peroxide in the blood plasma is immediately subjected to catalase exposure and therefore oxygen is split into water and gas. Dissolved oxygen gas enriches the plasma and red blood cells. Venous blood located in the wall of the stomach, sucking in the gaseous and liquid contents of the stomach, oxygenated with oxygen, immediately changes its color from dark cherry to bright red.

It should be noted that the proposed tool is introduced into the stomach, from where it is absorbed into the blood in parallel with the release of gastric juice from the blood into the stomach. Gastric juice is formed from blood plasma and the amount of gastric juice discharged into the stomach is commensurate with the amount of drinking water absorbed from the stomach. In this regard, the volume of circulating blood remains without significant changes, therefore, the claimed tool does not reduce the concentration of red blood cells in the blood.

Moreover, the oxygen gas released into the cavity of the stomach increases intragastric pressure, inflates the stomach and irritates almost its entire mucous membrane (since a large gas bubble is formed in the cavity of the stomach). All this increases the intensity of blood supply in the wall of the stomach. An increase in intragastric pressure creates the conditions for the intensive dissolution of oxygen in the gastric mucus, which covers the wall of the stomach, and then - to increase the rate of penetration of oxygen through the wall of the stomach into the blood. Simultaneously with absorption, gastric juice is released into the cavity of the stomach. In this case, gastric juice is formed from blood plasma, which under hypoxia is poor in oxygen and enriched in carbon dioxide. Therefore, gastric juice secreted into the cavity of the stomach promotes the release of carbon dioxide from the blood into the stomach. In other words, the claimed agent introduced into the stomach allows using the entire area of the gastric mucosa for gas exchange.

Thus, the claimed tool, when introduced into the stomach, quickly forms conditions in it that provide intragastric hyperbaric oxygenation, which enriches the blood flowing from the stomach with oxygen. In other words, after the introduction of drinking water enriched in hydrogen peroxide and gas-gassed with oxygen into the stomach cavity, oxygen appears under increased pressure in the stomach cavity. Under these conditions, gas exchange begins to occur in the wall of the stomach. By this, the stomach is to some extent likened to the lung, since it, like the lungs, begins to increase the flow of oxygen into the blood. In the absence of oxygen in the inhaled air, oxygen-enriched blood moves from the stomach, first to the heart, and then to all other parts of the body, including the head. In it, blood enriched in the stomach with oxygen protects the cells of the cerebral cortex from irreversible hypoxic damage, therefore, the drug helps to revive hypoxia caused by respiratory failure. Therefore, this tool can be used to increase the effectiveness of resuscitation benefits in conditions of hypoxia caused by respiratory failure (in the absence of oxygen in the inhaled air, drowning, hanging, crushing the lung, pulmonary edema, laryngeal edema, laryngospasm, bronchospasm, respiratory arrest, etc. )

The proposed composition of the ingredients and the ratio of their concentration in drinking water are optimal for giving the tool the ability to perform the function of an oxygen accumulator without physicochemical aggressive effect on the epithelial cells of the gastrointestinal tract, as well as for rapid absorption into the blood. Moreover, the use of drinking water provides the product with food quality and physiological safety, since the mucous membranes of the oral cavity, larynx, esophagus and stomach have a high adaptation to the ingestion of drinking water.

The presence in the proposed aqueous solution of hydrogen peroxide in a concentration of 0.3-0.5% ensures the efficiency and safety of the catalase reaction inside the gastrointestinal tract. The fact is that increasing the concentration of hydrogen peroxide above 0.5% increases the aggressiveness of the solution above the permissible values, since in case of accidental interaction with blood and purulent masses in the oral cavity, larynx, esophagus or stomach at a temperature of about +36 - + 37 ° С the solution acquires excessive “explosive” activity, capable of enhancing gas evolution and pushing the foaming contents from the cavities of the gastrointestinal tract outward in the form of a bloody or purulent foam. In this case, there is a danger of regurgitation, impaired ventilation and aggravation of respiratory failure. On the other hand, lowering the concentration of hydrogen peroxide below 0.3% deprives the tool of the necessary intensity of oxygen gas formation at a temperature below 36 ° C. This does not contribute to the long-term preservation of effective hyperbaric oxygenation inside the stomach after the exhaustion of reserves of oxygen gas dissolved in water.

The temperature inside the stomach may be below 36 ° C in situations when cold water is introduced into it. A similar situation is possible when drinking cold water inside while drowning in cold water, when using cold water from an army flask by wounded soldiers, police officers in the military field, civilians injured on the streets of settlements in the winter season, as well as in northern latitudes in the conditions of the absence of heating devices during mass injuries due to technological disasters. The fact is that the presence of cold water in the stomach, which appeared in it before the introduction of the developed product, on the one hand, dilutes it, therefore, it reduces the concentration of oxygen and hydrogen peroxide. On the other hand, a decrease in temperature inside the stomach, according to Arrhenius law, reduces the rate of all physicochemical reactions, including the catalase reaction of the breakdown of hydrogen peroxide.

An agent intended for intragastric hyperbaric oxygenation can be introduced into the stomach naturally by analogy with the ingestion of drinking carbonated mineral water or through a gastric tube. The introduction of the agent into the stomach leads to the instantaneous lowering of the agent into the lower part of the stomach cavity, to its interaction with the gastric juice and to the rapid onset of the release of oxygen gas from the agent dissolved in the agent at the initial overpressure. The released gas, oxygen moves to the upper part of the stomach cavity and increases the gas bubble, increasing the oxygen concentration in it. At the same time, the formation of molecular oxygen from hydrogen peroxide begins, which is determined by the activity of catalases. The free oxygen gas generated in significant quantities inflates the stomach cavity, irritates its wall, stimulates the absorption of liquid and gaseous contents of the stomach cavity enriched with oxygen, promotes the release of gastric juice enriched in carbon dioxide into the stomach, increases the value of intragastric pressure and provides conditions for hyperbaric oxygenation, which promotes oxygen enrichment of venous blood flowing from the stomach to the heart.

Therefore, this tool expands the range of application, creates optimal conditions for fast, safe and effective intragastric hyperbaric oxygenation, since the blood inside the blood vessels located in the gastric wall is enriched with oxygen and changes its color from dark cherry to bright red; increases the effectiveness of resuscitation benefits in case of hypoxia developed as a result of respiratory failure, reduces the likelihood and degree of hypoxic damage to the cells of the cerebral cortex, the development of hypoxic encephalopathy, therefore it increases the effectiveness of treating patients with hypoxia caused by severe respiratory failure.

In studies on 3 adult healthy male volunteers, we reproduced the process of intragastric hyperbaric oxygenation using the proposed tool enriched with oxygen and hydrogen peroxide. Before this, 3 remedies were prepared.

Means No. 1 was a solution of 0.3% hydrogen peroxide and 2% sodium bicarbonate in water for injection.

Means number 2 was a tool intended for oral administration - nootropil solution for oral administration 20% bottle of 125 ml.

Means No. 3 was drinking water containing 0.3% hydrogen peroxide and oxygen gas until an overpressure of 0.2 atm was created at + 8 ° C.

All products had a temperature of 25 ° C.

Previously, the test Volange was used in the studied volunteers in the initial state (in control). For this, all volunteers in a standing position voluntarily held their breath for the longest possible time. The duration of this period was determined using a stopwatch. The detected values were different. In this regard, in order to optimize the subsequent process of mathematical processing of the obtained data and to increase the visibility of the obtained results, it was decided that the detected parameters of the Stange test for each person should be taken as 100%. Then, after 5 minutes, each volunteer took 25 ml of one of the preparations we prepared inside, after which, after 1 minute, the Stange test was again applied. Moreover, all volunteers in a standing position voluntarily held their breath for the longest possible time. The duration of this time period was determined using a stopwatch. Then, mathematical processing of the obtained data was carried out. Moreover, the results were analyzed in absolute and relative values (in% in relation to the initial (control) value of the Stange sample for each volunteer studied) (Table 1).

As follows from the above results, the value of the Stange sample after ingestion of 25 ml of known liquid agents changes insignificantly. In particular, the introduction into the stomach of means No. 1 (a solution of 0.3% hydrogen peroxide and 2% sodium bicarbonate in water for injection) increased the volunteer's resistance to hypoxia by only 2.3%, and the introduction into the stomach of means No. 2 (a solution of nootropil for ingestion containing 20% pyrocetam) decreased the resistance to volunteer hypoxia by 1.2%. At the same time, the introduction of the proposed agent into the stomach of the volunteer (means No. 3 — drinking water containing 0.3% hydrogen peroxide and oxygen gas until an overpressure of 0.2 atm at + 8 ° C was created) increased the volunteer's resistance to hypoxia by 10, 6%

Therefore, an agent for intragastric hyperbaric oxygenation, which is a solution of 0.3-0.5% hydrogen peroxide and at an excess pressure of 0.2 atm at + 8 ° C of oxygen gas in drinking water, increases resistance to hypoxia due to the appearance of gas in the stomach oxygen under excessive pressure, oxygen absorption into the blood, plasma oxygenation and blood cells under conditions of high pressure. In addition, the claimed tool expands the scope, because it provides the use of the stomach for intragastric gas exchange and blood oxygenation in conditions of respiratory failure and / or lack of oxygen in the inhaled air.

The invention provides an expansion of the scope, increasing efficiency and safety by increasing the area of gas exchange, intragastric hyperbaric oxygenation, oxygenation of plasma and blood cells, the use of the gastric mucosa to absorb oxygen into the blood and release carbon dioxide from the blood, stabilize the concentration of red blood cells in the blood and circulating blood volume.

Claims (1)

A tool for increasing resistance to hypoxia, intended for oral administration, characterized in that it includes hydrogen peroxide, oxygen until an overpressure of 0.2 atm is created at + 8 ° C, and drinking water, in the following ratio of these components, wt. %:
Hydrogen peroxide 0.3-0.5 Oxygen until overpressure of 0.2 atm at + 8 ° C Drinking water Rest