RU59415U1 - DEVICE FOR INHALATION - Google Patents

Abstract

The utility model relates to medicine and can be used in narcology, psychiatry, neurology, pulmonology, therapy, in the treatment of occupational diseases, preventive medicine, during rehabilitation and recovery of the body after an illness, and also after exhausting mental and physical stress. The device comprises a breathing circuit connected to the gas supply unit 6 from sources of compressed gas 7, 8, 9, 10, 11 and including a patient’s breathing mask 3, a gas analyzer 4. The difference between the device is that the breathing circuit is closed in the form of a breathing gas chamber 1 connected through the inhalation / exhalation line 2 with the respiratory mask 3 of the patient, with a gas analyzer 4, the sensor 5 of which is installed inside the respiratory gas chamber 1. The respiratory gas chamber 1 is connected to the gas supply unit 6, with the possibility of supplying, as a finished gas mixture of 7.8, and individual gases from sources 9, 10, 11 of compressed gases into the respiratory gas chamber 1. The respiratory gas chamber 1 is equipped with at least one replaceable additional respiratory capacity 12. The line of inhalation / exhalation 2 is made in the form of a breathing tube on which, at the outlet of the breathing gas chamber 1, a shutter 14 for opening and closing the breathing circuit and a valve device 15 are installed, the expiration channel of which is connected to the carbon dioxide and water absorber 18 installed inside the breathing gas chamber. The device for inhalation is equipped with a compressor 21 for collecting xenon in separate containers 22 for its further processing (purification). The technical result consists in reducing the consumption of xenon, increasing the efficiency of the inhalation procedure. The inventive device is a mobile, multivariate, universal, fairly structurally simple device.

Description

The utility model relates to medicine and can be used in narcology, psychiatry, neurology, pulmonology, therapy, in the treatment of occupational diseases, preventive medicine, during rehabilitation and recovery of the body after an illness, and also after exhausting mental and physical stress.

The use of inert gases in medicine is currently becoming more widespread. It is well known to use an oxygen-helium mixture by inhalation for the treatment of lung diseases, warming the body during hypothermia (2), an oxygen-xenon mixture for the treatment of drug addiction, diseases of the central nervous system (1,3).

At the same time, the main obstacle to the widespread adoption of noble gases in practice is the use of expensive equipment, the high cost of inert gases, especially xenon, which makes the inhalation procedure for treatment inaccessible to most of the population.

A device for autoanalgesia with a xenon-oxygen mixture is known, according to which the patient is independently invited to inhale the xenon-oxygen mixture in a ratio of xenon to oxygen in vol.% From 30-70 to 50-50 before stopping the pain syndrome (RU Pat No. 2271815, op. 20.03.2006 )

In the device used to implement this method, the respiratory circuit is limited to 3 liters, and the absence of an additional outlet to increase the capacity to 5-6 liters leads to a greater consumption of xenon, due to the additional supply of the mixture from the balloon and its discharge into the atmosphere without taking into account the percentage xenon in the circuit.

The absence of a gas analyzer that monitors the level, content and consumption of oxygen in the gas mixture in the device can lead to patient hypoxia, especially if the patient is unconscious.

The device does not provide for other gas sources (for example, strippers, mini-balloons), there is no possibility of mixing gases.

In addition, there is no possibility of collecting spent xenon, which leads to an increase in its consumption.

Known devices used for inhalation of a xenon-oxygen mixture. Basically, these are anesthesia devices equipped with flow meters (1, 3).

There is also a known device called Ingalit B, Ingalit BM, which allows inhalation with heated gas mixtures (2), however, a constant gas flow, the absence of a gas analyzer leads to a large consumption of xenon and a significant increase in the cost of treatment.

The closest analogue adopted for the prototype is a device for inhalation anesthesia with a gas mixture of xenon with oxygen (RU, No. 2183476, op. 20.06.2002). The device comprises a gas supply unit with sources of compressed gases, a breathing circuit including a breathing mask, a gas analyzer,

The disadvantages of the device include the possible loss of xenon due to the complexity of the design. In addition, it is equipped with rotameters, a cryopump, a chromatograph, which requires special maintenance, makes the device expensive, bulky, this does not allow it to be used in the field, clinics, ambulances.

The task to which this technical solution is directed is to create a mobile, multivariate, universal, structurally simple enough device with a reduced consumption

xenon, as well as increasing the effectiveness of the inhalation procedure and therapeutic effects.

To solve the problem in a device for inhalation of a xenon-oxygen gas mixture containing a gas supply unit connected to sources of compressed gases, a breathing circuit including a gas analyzer, a patient’s breathing mask, according to the invention, the breathing circuit is made closed in the form of a breathing gas chamber connected to gas supply unit, with the patient’s breathing mask through the inspiratory / expiration line and with a gas analyzer, the sensor of which is located inside the respiratory gas chamber, in addition, the gas chamber is equipped with on at least one additional breathing capacity, the inspiratory line / exhalation valve is provided for opening and closing the breathing circuit.

The inspiratory / expiratory line is made in the form of a breathing tube equipped with a valve device installed at the outlet of the respiratory gas chamber having two channels — the inspiratory channel and the exhalation channel, with the inspiratory valve and the exhalation valve installed on them, respectively. The damper for opening and closing the respiratory circuit is installed at the outlet of the respiratory gas chamber, after the valve device.

The respiratory circuit can be equipped with a CO ₂ and H ₂ O absorber located inside the respiratory gas chamber and connected to the outlet of the exhalation channel.

The absorber of CO ₂ and H ₂ O can be made, for example, in the form of a column with soda lime.

As a source of compressed gases can be used cylinders of the finished mixture or single cylinders with clean gases or mini-cylinders with the finished mixture or cylinders of desorbers with a heating element.

The heating element may be removable.

The heating element may be in the form of a chemical heater or in the form of an electric heater.

Additional respiratory capacity can be made removable.

Additional respiratory capacity can be made in the form of a breathing bag.

The respiratory circuit can be equipped with a disinfecting element, which can be made in the form of a bactericidal filter mounted on the inspiratory / expiratory line or can be made in the form of an ultraviolet emitter installed in the gas chamber.

The inhalation device can be equipped with a compressor connected to the respiratory gas chamber and with a xenon trapping unit or a cylinder for collecting the spent mixture.

Figure 1 shows a schematic diagram of a device for implementing the inhalation method.

Figure 2 shows a schematic diagram of a device for inhalation, a mobile version.

The device comprises a breathing circuit made in the form of a breathing gas chamber 1 connected through an inhalation / exhalation line 2 with a respiratory mask 3 of a patient, to a gas analyzer 4, the sensor 5 of which is installed inside the respiratory gas chamber 1. The respiratory gas chamber 1 is connected to the gas supply unit 6 , which has, for example, five channels: for supplying the finished mixture, for supplying oxygen, for supplying xenon (channels 2 and 3 are used in the case of working with pure gases from standard cylinders), a channel for supplying the gas mixture from the mini-balloon , a channel for supplying gas from the stripper with the possibility of supplying both the finished gas mixture and individual gases from sources of compressed gases into the breathing gas chamber 1.

Each channel is equipped with a faucet (not shown in the drawing) that opens during gas supply from compressed gas sources, which can be used as cylinders 7 with a mixture of gases (ordinary cylinders) or mini-cylinders 8 with a capacity of 20-50 ml with the finished mixture, or

cylinders 9 with oxygen, or cylinders 10 with xenon, or strippers 11 (column in which the gas is in a state associated with the sorbent).

The desorber 11 is equipped with a heating system - a chemical or electric heater (not shown in the drawing), which can operate both in stand-alone and in stationary modes. Structurally, a variant is possible when the stripper is placed in the heating element or the heating element is mounted in the bottom of the stripper. Desorbers contain only xenon. When the stripper is heated, gas from it passes through the channel of the gas supply unit 6 into the respiratory gas chamber 1. At the same time, an additional effect of the heating device is achieved — inhalation of warm (hot) gases.

The respiratory gas chamber 1 is provided with at least one additional respiratory capacity 12, made, for example, in the form of a breathing bag with a capacity of 2-3 l, preferably latex.

The capacity of the respiratory gas chamber 1 is 3-5 l, and with an additional capacity of up to 8 l. The possibility of using replaceable additional respiratory containers of 12 different sizes allows you to use this inhalation device for both children and adults with different lung capacity, which in adults can range from 2.5 l to 7-8 l (athlete has a lung capacity of 7 liters, an ordinary person - 4 liters, children - 1 liter or less, elderly patients - less than three liters, tidal volume is reduced in the absence of one lung and pneumonia).

This is the main function of the extra breathing bags. They also allow you to visually observe the degree of filling of the respiratory gas chamber with gas.

The respiratory gas chamber 1 is equipped with a relief valve 13.

A relief valve is a safety feature to prevent overpressure in the patient's lungs. In the event of hypoxia conditions, a gas mixture is added to the respiratory circuit, while

the valve automatically discharges excess gas and thereby prevents pulmonary barotrauma.

The inspiratory / expiratory line 2 is made in the form of a breathing tube, on which, at the inlet / outlet of the respiratory gas chamber 1, a shutter 14 for opening and closing the breathing circuit and a valve device 15, made, for example, in the form of two channels — the inspiration channel and the channel the exhalation, with the inspiratory valve 16 and the exhalation valve 17 respectively installed on them. The exhalation channel is connected to, installed inside the respiratory gas chamber 1, a carbon dioxide and water absorber 18, made, for example, in the form of a column with soda lime. During inhalation, gas purified from carbon dioxide and water enters the respiratory gas chamber 1 and is then inhaled by the patient through the inhalation valve 16. When inhaling, the valve 16 standing on the inhalation channel opens, and the exhalation valve 17 closes; upon exhalation, the valve 17 standing on the channel the exhalation opens, and on the inspiration channel, the valve 16 closes. Valves are a standard version and can be performed, for example, in the form of flap valves, or ball and others.

The respiratory circuit is equipped with a disinfecting element, which can be made in the form of a bacterial-viral filter 19 installed on the breathing tube 2 or in the form of an ultraviolet radiation source 20 installed in the respiratory gas chamber 1. Possible use of one of these elements in the device, as well as options for sharing them.

The respiratory mask 3 line inhalation / exhalation 2 through the bacterial-viral filter 19, the valve 14, the valve device 15 is connected to the respiratory gas chamber 1.

The damper 14 for opening and closing the breathing circuit is located at the outlet of the breathing gas chamber 1, after the valve device 15. The damper has two functions - firstly, it prevents the loss of the gas mixture from the breathing gas chamber 1, the second function of the damper is

after the procedure, it closes and it becomes possible to collect the spent mixture either into the cylinders of the spent mixture or into the xenon recovery unit (BUC).

The gas analyzer 4 allows you to control the content in the gas mixture of oxygen and xenon. If not a ready-made mixture of gases is used, but separately gases - oxygen and xenon, then the gas analyzer monitors the content, in particular, oxygen in the respiratory circuit so that there is no hypoxia - lack of oxygen in the respiratory circuit. The sensor 5 of the gas analyzer is located directly inside the respiratory gas chamber 2, and not in the gas stream, which provides less resistance to breathing and makes the external gas breathing circuit shorter.

The device for inhalation can be equipped with a compressor 21, which allows collecting expensive xenon gas into separate containers 22, for example, in a xenon trapping unit (BUC) or in cylinders - adsorbers, where the exhaust gases (xenon, nitrogen, carbon dioxide, water) enter for further processing (purification) and reuse of xenon. This ensures the principle of recycling, the principle of saving xenon.

The device operates as follows.

The device is preparing for the procedure.

Sources 7 or 8 of compressed gases of prepared mixtures of xenon with oxygen with a high oxygen content are connected to the respiratory gas chamber 1 through a gas supply unit 6. Install an additional respiratory capacity 12 (one or more). The filling of the respiratory chamber 1 and the additional respiratory container 12 with a gas mixture occurs when the shutter 14 is closed under the control of the gas analyzer 4. In the case of using cylinders separately with oxygen and separately with xenon, the respiratory gas chamber is pre-filled with oxygen 9, then xenon 10, 11 under the control of the gas analyzer 4 to xenon: oxygen content - 70-10: 30 -90%. about. with the shutter closed 14. After

filling the breathing gas chamber 1 with a gas mixture shut off the valve of the gas supply unit 6.

The inhalation procedure is carried out on an empty stomach or 3-6 hours after a meal.

Before the procedure, the internal surfaces of the device are sterilized using an integrated ultraviolet light source for 30 minutes.

Immediately before inhalation with a xenon-oxygen mixture, the patient for 1 min. independently carries out hyperventilation of the lungs by deep inhalation / exhalation, after which it produces a deep exhalation into the atmosphere. Then it holds the breath, while holding the breath, the patient is connected to the device (an anesthetic respiratory mask 3 is put on). Then, the shutter 14 opens immediately and the treatment gas mixture is supplied through the valve device 15 and the bacterial-viral filter 19. The patient spontaneously breathes under the supervision of a doctor with a frequency of 5-10 breaths per minute for up to 5 minutes. The person who is starting the procedure monitors the patient’s condition and when objective and subjective signs (nystagmus of the eyeballs (twitching), dizziness, parasthesia - goosebumps, tingling, euphoria - the feeling of intoxication) occur, which indicate the effect of the treatment gas mixture on the body and the oxygen content decreases to 20-23%, which is confirmed by the testimony of the gas analyzer, stops the treatment procedure.

After the procedure, the spent mixture from the apparatus with the help of the compressor 21 is sent to a separate container 22: a cylinder - adsorber or to a xenon recovery unit (BUC) for further processing (purification) and reuse of xenon. Turn off the source of the gas mixture.

Disconnect the breathing mask 3 with the breathing tube from the camera 1

If a stripper 11 and mini-balloons 8 were used as a gas source, then they are replaced.

Below are examples of the use of the inventive device.

Example 1

Patient K., 38 years old. Complaints of weakness, fatigue, lack of appetite, pain in the epigastric region. Objectively: with FGDS the phenomenon of superficial gastritis; Kerdo index +8, Ashner test +1; hemogram: segmented neutrophils 69%, stab neutrophils 7%, eosinophils 2%, monocytes 3%, lymphocytes 19%, the total number of leukocytes 4.5 G / l. Diagnosis: chronic fatigue syndrome, chronic stress. Adaptogenic therapy was prescribed by inhalation in a closed circuit apparatus using xenon (5 inhalations every other day), the total dose was 12.5 liters (70 g). After 10 days of therapy, the patient's condition improved significantly, the pains in the epigastric region disappeared, appetite improved significantly, and working capacity increased. Kerdo index was - 6, Ashner test -2; hemogram - 56% segmented neutrophils, stab neutrophils 2%, eosinophils 4%, monocytes 3%, lymphocytes 35%. Conclusion: healthy, activation reaction (calm activation zone).

Example 2

For drivers, practically healthy men, resistance to stress factors of a long trip (motion sickness, static and dynamic physical activity) and the state of the visual analyzer in the initial state and after conducting a closed loop of xenon inhalation with oxygen in a mass ratio of 30/70 in within 3.5-4 minutes. The consumption of a mixture of xenon with molecular oxygen averaged 2.5 L (14 g) per person. Resistance to motion sickness increased after inhalation on average 2 times; an increase in the “reserve time” of travel time - an average of 1.7 times, while maintaining a positive effect for 20 ± 2 days. Inhalation also increased the reserve capacity of the external respiration apparatus and physical

working capacity: VC increased by 6-10%, MVL by 15-20%, the duration of breath holding by 17-25%, the efficiency of muscle work - by 15%. The level of functional activity of the visual analyzer also increased: the throughput increased by 10-12% while reducing the thresholds of brightness sensitivity by 25-43%. During the experiment, each subject completed a self-assessment questionnaire, which was then analyzed. 6 out of 7 evaluations of experimental results were high.

Table 1
Comparative analysis of xenon consumption in the treatment of conventional methods using standard anesthetic-respiratory equipment and the proposed inhalation device Used device Xenon consumption for the procedure Xenon Consumption per Course of Treatment (10 treatments) Procedure cost The cost of a course of 10 procedures Standard equipment 7-15 liters 70-150 liters 70-150 $ USA 700-1500 $ USA The proposed equipment 1.5-2.5 liters 15-25 liters 15-25 $ USA 150-250 $ USA

Note: The cost of xenon in the market is currently 10 $ USA per 1 liter.

As can be seen from the table, the cost of treatment using the proposed device is 5-6 times cheaper than those that use standard methods and equipment. This type of treatment is becoming more economical and affordable for the population.

As can be seen from the above, the use of the inventive device for inhalation has the following technical advantages and features:

The main difference of the proposed device is a closed respiratory circuit, providing a hypoxic mode of respiration, which provides an economical mode of flow of the respiratory mixture, in particular, xenon and faster delivery of the mixture to the central nervous system.

The consumption of xenon gas is reduced by 5-10 times (table 1)

Xenon consumption for the procedure is 1.5-2 l

The effectiveness of the inhalation procedure and therapeutic effect, as a closed circuit leads to the accumulation of carbon dioxide in the respiratory gas chamber, which increases the permeability of blood vessels, and this already leads to a more intensive flow of xenon into the tissue.

The use of various gas sources - cylinders with pure gases, cylinders with gas mixtures, mini-cylinders, strippers (sorption columns) equipped with a heating system, when using a closed breathing circuit gives the multivariance of the use of the inventive device. In addition, the heated gases themselves enhance the therapeutic effect.

The use of 20-50 ml mini-cylinders as a source of compressed gases ensures the mobility of the device and makes it possible to use it in outpatient and field conditions.

The use of the finished mixture or the mixing of individual gases in a closed circuit of the apparatus eliminates rotameters and other equipment, which simplifies the device, in addition, creates the possibility of using it in the field. The flow rate and the state of the gas mixture are controlled using a gas analyzer, the sensor of which is located in the respiratory gas chamber.

Placing the gas analyzer sensor directly inside the respiratory gas chamber rather than in the gas stream provides less breathing resistance and makes the external gas circuit shorter, which virtually eliminates the loss of xenon in the inhalation treatment procedure.

If there is a column with soda lime inside the breathing chamber, the gas collected from the apparatus into xenon trapping units and into the spent mixture cylinders will be cleaner without carbon dioxide and water or with a lower content of them. And the capture unit will collect more xenon.

The option of the absence of columns with soda lime does not entail negative consequences for the patient, because carbon dioxide stimulates the respiratory center, which is located in the brain and increases the respiratory rate. This indicates the excitation of the respiratory center of the brain, and not that there is not enough oxygen for patients. And the apparatus will be simplified at the same time, for a short period of the inhalation procedure, pronounced hypercapnia (increased content of carbon dioxide in the blood) will not develop, and breathing resistance will decrease, while the onset of the stage of the appearance of signs of a therapeutic effect is accelerated, xenon consumption is reduced,

The possibility of using interchangeable breathing bags of different sizes allows you to use this device in both children and adults with different lung capacity, which in adults can range from 2.5 liters to 7-8 liters. The absence of this difference in the prototype does not allow it to be widely used in the treatment of various age groups.

The presence of a removable heating element allows the use of warm gases for therapy, which improves blood flow in the lungs, and the presence of a chemical heating element allows the device to be used in the field and in cold weather offline.

The portability and autonomy of the device ensures its operation in the field and can be used in disaster medicine and field medicine.

The presence of a compressor allows you to quickly collect the exhaust gas from the breathing gas chamber into a cylinder or a xenon recovery unit for further processing (purification) and reuse of xenon. The principle of recycling, the principle of economy.

Thus, when using the proposed inhalation device increases the safety, efficiency and effectiveness of the xenon therapy method, significantly reduces the cost of expensive xenon.

In addition, the inventive device is a mobile, multivariate, universal, fairly structurally simple device.

Literature

1. Patent No. 2156,270 of the Russian Federation A method for the treatment of drug addiction. Vovk S.M., Efimov V.V., Naumov S.A. et al. 2004.20.04.2001. Bull. Number 11

2.Pavlov B.N., Dyachenko A.I., Shulgin Yu.A. et al. Study of the physiological effects of breathing with heated oxygen-helium mixtures // Human Physiology. - 2003. - T.29. - No. 5. - S.69-73.

3. Naumov S.A. et al. The role of xenon in the treatment of opium addiction // Issues of Addiction. - 2002. - No. 6. - S.13-18.

Claims (19)

1. Device for inhalation with a gas mixture of xenon with oxygen, comprising a gas supply unit connected to sources of compressed gases, a breathing circuit including a patient’s breathing mask, a gas analyzer, characterized in that the breathing circuit is closed as a breathing gas chamber connected to the supply unit gases, with a patient’s breathing mask through the inspiratory / expiration line and with a gas analyzer, the sensor of which is located inside the respiratory gas chamber, in addition, the respiratory gas chamber is provided with at least discharge more breathing capacity, the inspiratory line / exhalation valve is provided for opening and closing the breathing circuit. 2. The device according to claim 1, characterized in that the line of inspiration / expiration is made in the form of a breathing tube. 3. The device according to claim 1, characterized in that the inspiratory / expiratory line is provided with a valve device having two channels — the inspiratory channel and the exhalation channel, with the inspiratory valve and the exhalation valve installed on them, respectively, installed at the outlet of the respiratory gas chamber. 4. The device according to claim 1, characterized in that the shutter for opening and closing the respiratory circuit is installed at the outlet of the respiratory gas chamber, after the valve device. 5. The device according to claim 1, characterized in that a CO ₂ and H ₂ O absorber is connected to the outlet of the expiratory channel inside the respiratory gas chamber. 6. The device according to claim 1, characterized in that the CO ₂ and H ₂ O absorber is made, for example, in the form of a column with soda lime. 7. The device according to claim 1, characterized in that the finished mixture cylinders are used as a source of compressed gases. 8. The device according to claim 1, characterized in that as a source of compressed gases used one-time cylinders with clean gases. 9. The device according to claim 1, characterized in that mini-cylinders are used as a source of compressed gases. 10. The device according to claim 1, characterized in that as a source of compressed gases used cylinders strippers with a heating element. 11. The device according to claim 1, characterized in that the heating element is made in the form of a chemical heater. 12. The device according to claim 1, characterized in that the heating element is made in the form of an electric heater. 13. The device according to claim 1, characterized in that the heating element is removable. 14. The device according to claim 1, characterized in that the additional respiratory capacity is made in the form of a breathing bag. 15. The device according to claim 1, characterized in that the additional respiratory capacity is removable. 16. The device according to claim 1, characterized in that the respiratory circuit is equipped with a disinfecting element. 17. The device according to claim 1, characterized in that the disinfecting element is made in the form of a bacterial-viral filter mounted on the inspiratory / expiratory line. 18. The device according to claim 1, characterized in that the disinfecting element is made in the form of an ultraviolet emitter installed in a breathing gas chamber. 19. The device according to claim 1, characterized in that it is equipped with a compressor connected to a breathing gas chamber and with a xenon trapping unit or a cylinder for collecting the spent mixture.