RU2344807C1 - Method of breath training - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves change of carbon dioxide and oxygen content in inhaled air due to expansion of additional 'dead' space volume. Hydraulic resistance at inhale and exhale is measured and gradually increased to the maximum hydraulic resistance of hypoxic hypercapnia apparatus. Breathing through the set apparatus for a specified time period, then hydraulic resistance at inhale and exhale is gradually changed to the original level. Time interval of hydraulic resistance change from original to maximum is not less than 3 minutes, and period of breath training at maximum hydraulic resistance is not more than twice longer than time period of hydraulic resistance change from maximum to original level.

EFFECT: method takes adaptation ability of organism into account at the beginning and end of breath training with hypoxic hypercapnia apparatus.

1 tbl, 1 dwg

Description

The invention relates to medicine, namely to cardiology, neurology and pulmonology, and can be used to study the body's response to dosed hypoxic hypercapnia, in particular to assess the reactivity of cerebral vessels and perfusion reserve of cerebral circulation, as well as for hypercapnic training aimed at increase in body resistance (resistance) to adverse stress factors, training of adaptive systems, preparation for surgical interventions with temporary rekrascheniem blood flow in the arteries feeding the brain, and the treatment of diseases, in particular cerebral circulatory disorders, coronary circulation disorders, hypertension, respiratory insufficiency, and others.

There are several ways to create hypoxic hypercapnia:

1. The use of finished gas mixtures with a specific content of O ₂ and CO ₂ . This method requires expensive anesthesia and respiratory equipment and cannot be used for individual training and treatment.

2. There is a simplified option for creating hypoxic hypercapnia by holding a breath-hold test. The main drawback of a breath-holding test is the inability to standardize the level of hypercapnia.

3. Another alternative option for creating hypoxic hypercapnia is a test with acetazolamide. The test is carried out by intravenous administration of 1 gram of acetazolamide. This technique was not widely used primarily due to invasiveness and long-term research.

The limitation for the widespread use in medicine of hypoxic hypercapnia is the lack of affordable methods and inexpensive small-sized devices for its creation.

A known method of breathing training, based on increasing the additional volume of the "dead" space (AS USSR No. 112692), in which exhaled air is used to create hypoxic hypercapnia. Dosing of carbon dioxide in the range of 1-5% is carried out by regulating the flow of air from the environment.

The disadvantages of this method are:

1. The inability to create a concentration of carbon dioxide in the inhaled air of more than 5%, which is necessary for assessing the perfusion reserve of cerebral circulation and conducting effective hypercapnic training.

2. The method does not allow to achieve the maximum stratification of exhaled air in portions, which leads to a decrease in the effective concentration of carbon dioxide.

The closest in technical essence and the achieved result is a method of breathing training, based on the increase in the additional volume of the "dead" space (US Pat. No. 2248812), which consists in the fact that through the openings in the absorber body the atmospheric air enters and mixes with exhaled air forming a hypoxic gas mixture. In this case, the bag is filled with exhaled air, depleted of oxygen due to absorption by the patient’s body, and after 12-14 sessions, the absorption of carbon dioxide in the device decreases, and it begins to function as a moderate hypercapnicator. The gas mixture is formed from exhaled carbon dioxide and atmospheric air, therefore, the concentration of carbon dioxide in arterial blood does not reach values that cause negative reactions in humans.

The disadvantages of this method are:

1. The inability to adjust the volume of the "dead" space and, accordingly, dosing the concentration of carbon dioxide.

2. When breathing according to the method proposed in the prototype, through a closed volume, the concentrations of carbon dioxide and oxygen are constantly changing and depend both on time and on patients using this method. Further, there is a probability of accumulation of not only carbon dioxide, but also nitrogen, which is unacceptable for medical reasons.

3. In addition, when breathing in this way, the patient experiences double stress, firstly, from an increase in hydraulic resistance during inhalation and exhalation (inspiratory and expiratory resistance to breathing), and secondly, from changes in the content of carbon dioxide and oxygen at the beginning of breathing training and a rapid change in these concentrations after training, which is especially detrimental to weakened patients and significantly reduces the applicability of the method.

So tests have shown that some patients, using the known method of breathing, experience discomfort associated with difficulty and even the inability to breathe at the beginning of the procedure, and after the procedure is terminated, headache and dizziness occur due to a sharp change in the concentration of carbon dioxide and oxygen . To reduce the risk of “failure” of adaptation and the occurrence of destructive changes in the vestibular and visceral organs, it is necessary to find the optimal time and magnitude of hypoxic and hypercapnic effects to increase the functional reserves of the body. Since the effectiveness of adaptation to environmental factors is determined by the well-known “force – duration” relationship, short-term (10–20 min) interval hypoxic and hypercapnic stimuli, which lead to mobilization of the functional reserves of the respiratory, circulatory, and blood systems, were determined as training ones. At the same time, carbon dioxide production and oxygen consumption significantly increased with the activation of carbohydrate metabolism, which indicates the formation of adaptive processes and, obviously, is associated with an increase in the efficiency of tissue respiration against the background of a decrease in the reactivity of oxygen transport systems.

The technical result of the proposed method is to increase the efficiency of the method by creating an effective concentration of carbon dioxide in the alveolar air with the possibility of independent changes in hydraulic resistance during inhalation and exhalation and smooth dosing of oxygen and carbon dioxide, taking into account the adaptation time of the body.

The technical result is achieved by smoothly changing the hydraulic resistance during inhalation and exhalation, gradually increasing it from the initial to the maximum hydraulic resistance of the hypoxic hypercapnia apparatus, then breathing for a predetermined period of time through the said apparatus, after which the hydraulic resistance during inhalation and exhalation is gradually changed to the initial level, while the time interval for the change in hydraulic resistance from initial to maximum is chosen not less than 3 minutes, and the time interval of the subsequent exit from the breathing process with hypoxic hypercapnia is chosen proportional to the time of breathing training with maximum hydraulic resistance, but not less than two times less.

The effectiveness of the method is demonstrated by the operation of a device for breathing training (see drawing).

The device consists of a mask 1 from a gas mask GP-4u, two cartridges 2, 3, a hose 4, an adapter 5 and a control valve 6. A hose 4 is attached on one side to the mask 1, and on the other to the cartridge 2. Cartridges 2, 3 are connected between each adapter 5, and the cartridge 3 is connected to the cartridge 2 in an opposite way, so that the standard air inlet of the cartridge 2 is connected to the output of the cartridge 3. At the bottom of the mask 1 there is an adjustable valve 6. Inside the free space of the cartridges 2, 3 between the filter (not marked) located inside the cartridge 2, 3, and the wall of the cartridge 2, 3 s strew trehmillimetrovye glass beads to increase the dead space and the number of dead zones with reduced convective transport of gas molecules.

The device operates as follows. At the initial moment, the adjustable valve 6 is fully open, so that the patient takes a free breath and exhale with virtually no additional resistance. Then, for three minutes, the valve is manually manually closed gradually by turning the valve cover 6. When the valve 6 is completely closed, breathing goes through the hole at the bottom of the cartridge 3. An additional amount of dead space includes the free space of the pore space of the backfill from the glass balls and the hose 4 between cartridges 2, 3 In this case, the hydraulic resistance due to breathing through two cartridges 2, 3 led to a pressure drop not exceeding 100 mm of water column. When breathing through one cartridge 2, the value of the additional pressure drop decreased by about half. After valve 6 is completely closed, the patient breathes for no more than 20 minutes, and then there is a gradual transition to open breathing due to the gradual opening of valve 6. Only the interval for opening valve 6 was selected for no less than 10 minutes if the patient was breathing for 20 minutes at full closed valve 6. In a simplified version, a more sparing mode of breathing training through one cartridge 2 was used.

Gas analysis during operation of the device for breathing training using the above-described apparatus of hypoxic hypercapnia was performed on a Spirolyt-2 gas analyzer (Germany). The results of gas analysis are shown in the table. The table contains three double columns. The first column shows the results of an experiment to determine the carbon dioxide content (in percent) and oxygen deficiency (in percent) when creating a hypoxic hypercapnia with a device with two cartridges 2, 3. In the second double column, the same thing with one cartridge 2, and the third column contains experimental data on the percentage of carbon dioxide and oxygen deficiency with one hose 4 without cartridges.

The table shows that the device allows you to provide a given hypercapnia (7%) with two cartridges and hypoxia within normal limits. The third column shows the results of gas analysis with one hose without cartridges, which allows for hypoxic hypercapnia in the most lightweight version. Consequently, different options for using the method and the corresponding device can be recommended to different categories of patients. For athletes and employees of the Ministry of Emergency Situations, two or even three cartridges can be used for training hypoxic hypercapnia, for weakened people, it is recommended to breathe no more than one cartridge and the weakest - leave breathing only through the hose.

Justification of the time intervals necessary for adaptation of the body to hypoxic hypercapnia. Within 1 minute of breathing through the device in the alveolar air, the concentration of carbon dioxide is set in the range of 5-7%, depending on the selected value of the additional volume of "dead" space. To adapt the body, as shown by experiments, it takes 2-3 minutes. Moreover, a three-minute adaptation of 15 patients was only in one person with a pathology of the respiratory system, first breathing through the apparatus of hypoxic hypercapnia. In the future, the patient’s adaptation period of entry also did not exceed 2 minutes. Therefore, this three-minute time interval for adaptation of the beginning of the implementation of the breathing training method is selected even with a certain margin.

After the initial adaptation time, the phase of the breath training itself begins through the apparatus of hypoxic hypercapnia, while breathing, the hydraulic resistance and carbon dioxide content are maximum, and the oxygen content is minimal. This extreme training in the tests did not exceed 20 minutes, but the time out of the training breath to normal, with the initial content of oxygen and carbon dioxide, varied. As a result of tests, it was found that the longer the time of hypoxic hypercapnia, the more time the body needs to adapt. In almost all cases, a painless exit was observed if the duration of the exit to the initial breath was approximately half the time of breathing training. For example, for a 20 minute breath training interval, the adaptation time or gradual exit to normal breathing was 10 minutes.

Note the advantage of the method when using a combined-arms insulating gas mask, shown in the drawing. The use of these gas masks is recommended in military units and in civil defense, since these gas masks have passed all stages of a medical examination and are certified. The proposed method makes minimal changes in the design of gas masks. So the use of glass balls in addition to the filters available in a gas mask due to the inertness of the glass material cannot be attributed to the use of harmful substances. Glass products are widely used in medicine. The adjustable valve is also widely used in insulating gas masks-recuperators. In addition, when implementing the method in lightweight versions, it is generally possible to dispense with not only glass balls in the cartridges, but also the cartridges themselves with filters. It should be noted that the main hydraulic resistance during breathing through a gas mask is provided by filters, but their effect on air separation and the creation of extended stagnant zones with reduced mass transfer coefficients is very insignificant due to the small pore diameter of the filter material. Therefore, as one of the embodiments of the method, the design of the cartridge that does not contain a filter filled only with glass balls was considered, which significantly reduced the hydraulic resistance to breathing while maintaining a positive effect of hypoxic hypercapnia.

Thus, the advantage of the proposed method is to take into account the adaptive properties of the body at the beginning and end of breathing training through the apparatus of hypoxic hypercapnia.

Claims (1)

A method of breathing training, which consists in changing the content of carbon dioxide and oxygen in the inhaled air, by increasing the additional volume of the "dead" space, characterized in that the hydraulic resistance is smoothly changed during inhalation and exhalation, gradually increasing it from the initial to maximum hydraulic resistance of the hypoxic apparatus hypercapnia, then breathing for a predetermined period of time through the apparatus, after which the hydraulic resistance during inhalation and exhalation to the initial level, while the time interval for changing the hydraulic resistance from initial to maximum is left at least 3 minutes, and the ratio of the time for breathing training with maximum hydraulic resistance is chosen no more than two times the time interval for changing hydraulic resistance from the maximum to the initial.