RU196168U1 - Feedback xenon therapeutic inhalation apparatus - Google Patents

Abstract

The utility model relates to medical equipment and can be used in physiotherapeutic and neurological departments of medical institutions and health care facilities, spa facilities, in disaster medicine, ambulance and emergency services, in medical centers of military camps using gaseous xenon medicine and oxygen, or other respiratory gases and their mixtures approved for medical use. The proposed therapeutic apparatus for inhalation by medical ha The system has a patient monitoring system that provides adequate analgesia during the procedure due to the device’s feedback to the patient, as well as increased safety of inhalation with medical gases and their increased duration, simplicity and reliability in operation associated with the organization of the respiratory system with disjoint flows and concentration control medical gases and gas flow pressure through the control unit and control units.

Description

The utility model relates to medical equipment and can be used in physiotherapeutic and neurological departments of medical institutions and health care facilities, spa facilities, in disaster medicine, ambulance and emergency services, in medical centers of military camps using gaseous xenon medicine and oxygen, or other respiratory gases and their mixtures approved for medical use

In recent decades, international interest in inert gases, especially xenon as a fundamentally new, alternative gas anesthetic with properties close to ideal anesthetics, has increased significantly. The therapeutic properties of xenon are also attracted to researchers: analgesic, antidepressant, neuroprotective agent, muscle relaxant, anxiolytic. Xenon easily penetrates the lungs, dissolves well in fats, after the cessation of supply for 3-4 minutes is excreted from the body. Xenon does not have a toxic effect on the body, is devoid of side effects, does not cause carcinogenic, allergic and cardiodepressive effects. It does not affect blood morphology, immunity, environmentally friendly and safe for sick and surrounding personnel.

The prior art method for autoanalgesia with xenon-oxygen mixture RU 2271815, according to which the patient is invited to inhale the xenon-oxygen mixture in the ratio of xenon to oxygen in about. % from 30-70 to 50-50 before the relief of pain. According to the invention, the device for autoanalgesia contains a cylinder with a gas mixture of XeO ₂ with a capacity of from 500 to 1000 cm ³ , a T-shaped connecting tube, a breathing bag with a capacity of up to 3 liters, made of polyethylene or rubber, a face mask, a L-shaped tube with a standard depressurization valve , a shutter for opening and closing the respiratory circuit, a nozzle with a rubber cap for introducing bronchodilators, a cap for the injection valve of the XeO ₂ mixture. The T-shaped tube is connected at its ends with a balloon, a breathing bag and a face mask, the end of the tube for placement in the breathing bag has two unconnected cavities.

The main disadvantage of the proposed method is the absence of a carbon dioxide (CO ₂ ) absorber in the system, which leads to a gradual increase in its level in the respiratory gas mixture and the development of hypercapnia in the patient. In this connection, such a device allows for therapeutic inhalations lasting no more than 3 minutes. Longer inhalations require a complete replacement of gas in the breathing bag, with a frequency of every 2 ... 3 minutes, which leads to an increased consumption of an expensive xenon-oxygen mixture.

A known method of inhalation and a device for its implementation RU 2317112. According to the invention, the respiratory circuit is closed in the form of a respiratory gas chamber connected to the gas supply unit, with the patient's respiratory mask through the inspiration / expiration line and with a gas analyzer, the sensor of which is located inside the respiratory gas chamber, in addition, the gas chamber is provided with at least one additional respiratory capacity, while the inspiratory / expiratory line is provided with a shutter for opening and closing the respiratory circuit, the inspiratory / expiratory line and is formed as a respiratory tube equipped mounted on the outlet of the respiratory gas chamber, the valve assembly having two channels - channel inspiratory and expiratory channel fitted with the valve, respectively inhaling and exhaling valve. The damper for opening and closing the respiratory circuit is installed at the outlet of the respiratory gas chamber, after the valve device. The absorber of CO ₂ and H ₂ O is made in the form of a column with soda lime, placed inside the respiratory gas chamber and connected to the outlet of the exhalation channel.

The disadvantages of the proposed method are the complexity of the organization of the absorber CO ₂ and H ₂ O. The efficiency of such a unit depends on the organization of gas flows through it. Its presence in the breathing chamber will not allow for high-quality cleaning and can lead to excessive humidification of the gas environment, as well as an increase in the level of CO ₂ in it, which in turn can cause the patient to develop hypercapnia. For high-quality cleaning of the gaseous medium, the exhaled gas mixture must pass through a similar cleaning system, and only then enter the gas chamber.

The closest in essence and the achieved result is the inhalation device, patent of the Russian Federation 174585, which is a respiratory system in which the port for supplying xenon or xenon-oxygen mixture is located in the connector in front of the variable volume tank, behind which there is a non-reversing valve that allows gas to pass into the coaxial breathing hose for inhalation the patient, and the exhalation is connected to a carbon dioxide absorption unit connected to an oxygen supply port located in the connector, which in turn is silver stvom adapters connected to a reservoir of variable volume, with gas flows of inhalation and exhalation are disjoint and circulating in a closed volume.

The proposed inhalation apparatus is universal and can be used in various conditions: stationary or field, as well as in ambulance vehicles. It is easy to maintain and reliable in operation, but does not allow for a personalized approach when carrying out inhalations. The lack of monitoring of the patient's condition and the presence of feedback with the patient does not allow for an adequate level of analgesia during xenon inhalation.

In addition, the lack of a monitoring system for carbon dioxide in the respiratory circuit does not allow to meet modern requirements for the level of patient safety presented to medical equipment, leaving the possibility for the occurrence of hypercapnia in the patient due to the fault of the human factor, when the doctor, according to the primary signs of the development of the phenomenon of hypercapnia, does not stop carrying out the procedure.

The objective of the present utility model is the creation of a universal apparatus for inhalation with medical gases in various conditions: stationary or field, as well as on ambulance vehicles with a patient monitoring system that provides adequate analgesia during the procedure due to the feedback of the device with the patient, as well as increasing the safety of inhalations with medical gases and increasing their duration, ensuring simplicity and reliability in the operation of the device.

To solve the tasks in this utility model, use:

1. An inhalation device containing a variable volume reservoir, connectors, adapters, non-reversing valves, a carbon dioxide absorption unit, a supply unit for a xenon or xenon-oxygen mixture and oxygen mixture to a patient, which is a face mask, a filter, and a gas gas monitoring unit mixtures, characterized in that they are introduced into it, a control and display unit, including program-controlled gas supply valves, configured to signal the level of analgesia of the patient and the danger to him in the case of immersion in the state of anesthetic sleep and connected to the node supplying a mixture of xenon or xenon-oxygen mixture and oxygen to the patient on the inspiratory line through a non-reversing valve, and patient monitoring sensors connected to the control and indication unit, while the gas content monitoring unit in the gas mixture, located on the exhalation line after the non-reversible valve, connected to the control and display unit, connected to an electromechanical valve, configured to relieve pressure when it is increased and transmitted and information about a deviation of pressure and in a carbon dioxide absorption unit is connected to a reservoir of variable volume for mixing gases.

2. The inhalation apparatus according to claim 1, characterized in that the gas content control unit in the gas mixture is configured to control carbon dioxide content.

A schematic diagram of a feedback xenon therapeutic inhalation apparatus is shown in FIG. 1.

Hereinafter in FIG. 1. The following position designations are used:

1 - control unit; 2 - flexible corrugated tube on the gas supply line to the respiratory system; 3 - tee; 4 - non-reversible valve on the line of inspiration; 5 - an angular connector; 6 - direct connector; 7 - flexible corrugated inspiration breathing hose; 8 - tee node delivery of the gas mixture to the patient; 9 - bacterial-viral filter; 10 - respiratory mask; 11 - flexible corrugated breathing hose exhale; 12 - non-reversible valve on the exhalation line; 13 - angular connector; 14 - node monitoring the content of gases, xenon and oxygen (and carbon dioxide, depending on version) in the respiratory system, combined in one unit with an electromechanical pressure control valve; 15 (16) - an angular connector; 17 - an absorber for trapping carbon dioxide; 18 - angular connector; 19 - direct connector; 20 - tee; 21 - a respiratory bag or reservoir of variable volume; 22 - an angular connector; 23 - sensors for monitoring the condition of the patient.

The claimed utility model works in the following way: from specialized reservoirs, cylinders, through pressure reducers and gas hoses, xenon or xenon-oxygen mixture gases and oxygen, are supplied to the control unit (1), which contains valves for supplying gases to the respiratory system, controlled by a software algorithm. When using valves, the amount (volume) of gases required to ensure the operation of the apparatus and the patient's breathing is supplied through a flexible corrugated tube (2) to the respiratory system.

The gas mixture through tees (3), (20) and the connector (22) is collected in a breathing bag or other variable volume reservoir (11), or is inhaled to the patient through a tee (3), a non-reversing valve on the inspiration line (4), connectors (5) and (6), a flexible corrugated inspiratory breathing hose (7), a tee of the gas mixture delivery unit to the patient (8), a bacterial-viral filter (9) and a breathing mask (10). The facial breathing mask (10) is fixed on the patient either using a mask holder or manually.

The exhalation is carried out through the exhalation line through a flexible corrugated breathing exhalation hose (11), a non-reversing valve on the exhalation line (12), a connector (13), a unit for monitoring the content of gases, xenon and oxygen (and carbon dioxide, depending on version) in the respiratory system, combined in one unit with an electromechanical pressure control valve (14), connectors (15) and (16), an absorber for trapping carbon dioxide (17), in which the exhaled air is purified from carbon dioxide; as well as through connectors (18), (19), a tee (20) into the breathing bag (21). Then the gas mixture is fed back to the patient for inspiration.

The control unit is responsible for ensuring the safety of the patient, monitoring his condition and controlling the quantity and composition of the gas mixture in the respiratory circuit. The electromechanical pressure control valve (14) transmits information about the deviation of pressure in the respiratory system from atmospheric. If the pressure in the respiratory system decreases, the control unit (1) supplies gases to the respiratory system in such a way as to maintain the established concentration. If the pressure rises, the control unit (1) opens the electromechanical valve (14) to atmospheric air to relieve pressure. In this case, the control unit for the content of gases, xenon and oxygen (and carbon dioxide, depending on the version) in the respiratory system (14) transmits data on gas concentrations to the control unit (1). The control unit (1) in turn regulates the flow of gases into the respiratory system, so as to maintain the target concentration. If a dangerous concentration of carbon dioxide in the respiratory circuit is reached on the patient’s exhalation line, the control unit will issue a danger signal, stop the procedure and open the electromechanical valve (14) to the “atmosphere”.

During inhalation, the patient condition monitoring sensors (23) transmit data to the control unit (1) and signal the level of analgesia of the patient, and if the patient is immersed in a state of anesthetic sleep, the control unit (1) signals the danger to the patient and gives oxygen to the respiratory system to lower xenon concentration. If the patient will continue to be in a state of anesthetic sleep, the device stops inhalation and opens the electromechanical valve (14) to the “atmosphere”.

A utility model can be embodied in other specific forms without deviating from its essence or essential features. Therefore, these options for implementing the utility model should in all respects be considered as illustrative and non-restrictive. The limits of a utility model are indicated by the attached formula rather than the previous description, and therefore it is understood that it covers all changes that fall within the concept and limits of equivalence of the formula.

Claims (2)

1. An inhalation device containing a variable volume reservoir, connectors, adapters, non-reversing valves, a carbon dioxide absorption unit, a supply unit for a xenon or xenon-oxygen mixture and oxygen mixture to a patient, which is a face mask, a filter, and a gas gas monitoring unit mixtures, characterized in that a control and indication unit is introduced into it, including program-controlled gas supply valves, configured to signal the level of analgesia of the patient and the danger to him the case of immersion in the state of anesthetic sleep and connected to the node supplying a mixture of xenon or xenon-oxygen mixture and oxygen to the patient on the inspiration line through a non-reversing valve, and patient monitoring sensors connected to the control and indication unit, while the gas content control unit in the gas mixture located on the exhalation line after the non-reversible valve, connected to the control and display unit, combined with an electromechanical valve, configured to relieve pressure when it is increased and transmitted and information about a deviation of pressure and in a carbon dioxide absorption unit is connected to a reservoir of variable volume for mixing gases. 2. The inhalation apparatus according to claim 1, characterized in that the control unit for the gas content in the gas mixture is configured to control the content of carbon dioxide.

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