RU99712U1 - NOSOROTOVA OXYGEN MASK WITH PORT TO THE GAS ANALYZER - Google Patents

Abstract

 A nasal cavity oxygen mask, including a mask with side openings for the inlet and outlet of the air mixture and the connector to the oxygen hose, characterized in that a port to the gas analyzer is installed in the nasal cavity oxygen mask.

Description

The utility model relates to medicine, namely to anesthesiology-resuscitation, intensive care, pulmonology, thoracic surgery, and can be used for inhaled oxygen therapy and diagnostic tests of the gas composition of the respiratory mixture on inhalation and exhalation, and control of external respiration.

Nasal (facial) oxygen masks are known [Big Medical Encyclopedia / Editor-in-Chief B.V. Petrovsky. Moscow, 1979. Volume 10. P.328, Kassil V.L., Vyzhigina M.A., Leskin G.S. Artificial and assisted ventilation. - M.Meditsina, 2004. P.113, http://www.rosmed.ru/catalog/144/maska_licevaya_kislorodnaya/4236.html] and are used for inhalation of oxygen in the human respiratory tract or oxygen-enriched mixtures, fixed on the head, hermetically covering the mouth and nose and attached to a source of oxygen. They are used in patients with respiratory failure in the intensive care unit and intensive care unit, as well as during surgery with intravenous anesthesia or sedation in non-intubated patients.

Closest to the utility model is the nasal (face) oxygen mask described in the source [http://www.a-medical.ru/catalog/_item69.html], consisting of a nasal mouth mask with side openings, with a connector to the oxygen hose and elastic adjustable fixing strap. The supply of oxygen to the mask increases the oxygen concentration in the breath and increases the oxygen concentration in the alveolar space, which is accompanied by an increase in oxygen tension in the blood and increased tissue oxygenation.

The known rhinoceros oxygen mask has the following disadvantages: the use of the rhinoceros oxygen mask only for the treatment procedure - oxygen inhalation, the inability to determine the concentration of oxygen and carbon dioxide on inhalation and exhalation, the inability to control external respiration (frequency and depth of breathing).

The technical result, which can be achieved by a useful model, is to create conditions for a diagnostic procedure for determining the concentration of oxygen and carbon dioxide in the submascule space for inhalation and exhalation, to assess the frequency and depth of breathing, which allows you to immediately identify disorders and respiratory arrest and disturbance in the supply line oxygen from the rotameter to the mask, improve patient safety during surgery and intensive care.

The specified technical result is achieved due to the fact that a port to the gas analyzer is installed in the nasal cavity oxygen mask. The essence of the utility model is as follows: on the lateral surface of the nasal cavity oxygen mask (Figure 1) at a distance of 1-1.5 cm down from the side hole for entering and exiting the air mixture and at a distance of 2.5-3 cm from the side edge of the mask a perforation hole with a diameter of 4 mm into which the port is installed (cap from an injection intramuscular needle with a cut distal end). The proximal (wide) part of the port is located in the submask space at a depth of 2-3 mm, and the distal (narrow) part of the port projects 1.5-2 cm above the side surface of the mask and connects to the gas analyzer through the transition line. On the monitor of the gas analyzer, the parameters of the concentration of oxygen and carbon dioxide in the submascule space for inspiration and expiration, and the respiration rate are recorded, and the depth of respiration is visually estimated by the amplitude of the capnogram curve. When breathing stops or depression, an immediate change in the parameters and amplitude of the capnogram is observed, which is simultaneously accompanied by a monitor alarm. Disconnecting or squeezing the oxygen hose is accompanied by a decrease in the oxygen concentration on inspiration (FiO ₂ ) and expiration.

The choice of the installation location of the port to the gas analyzer at a distance of 1-1.5 cm from the side hole for entering and exiting the air mixture and at a distance of 2.5-3 cm from the side edge of the mask is due to the fact that the port to the gas analyzer is located on the rhinoceros oxygen mask in a place close to the lips and the area of entry and exit of the air mixture.

The area of entry and exit of the air mixture most accurately reflects the concentration of gases in the inhaled and exhaled air.

Patients with respiratory failure breathe through the mouth.

Figure 1 shows a rhinoceros oxygen mask with a port to a gas analyzer, where:

1 - lateral hole for air inlet and outlet, 2 - elastic adjustable fixing strap, 3 - port to the gas analyzer, 4 - connector to the oxygen hose.

This device was used in 24 non-intubated patients during surgery under general intravenous anesthesia or regional anesthesia with intravenous sedation. Table 1. summarizes the changes in the concentration of the gas composition of the respiratory mixture in the mask space, blood oxygen saturation and respiratory rate recorded on the monitor (Cardiocap / 5, Datex-Ohmeda) when breathing through the mask with air (oxygen flow - 0) or oxygen-air mixture (oxygen flow of 0.2 and 0.5 liters per minute).

Table 1.
Change in the concentration of oxygen, carbon dioxide, oxygen saturation of the blood and respiratory rate at various oxygen flow rates, (n = 12, M ± δ). The flow of oxygen, l / min EtO ₂ ,% FiO ₂ ,% EtCO ₂ ,% FiC _O 2,% StO ₂ ,% Respiratory rate, min ^-1 0 15.0 ± 0.7 19.9 ± 0.3 5.04 ± 0.39 0.47 ± 0.18 98.1 ± 1.4 15.4 ± 2.5 0.2 18.1 ± 1.1 *** 21.0 ± 0.8 *** 4.93 ± 0.34 *** 0.37 ± 0.16 * 98.5 ± 1.0 * 14.8 ± 2.6 0.5 21.8 ± 1.5 ### 22.3 ± 1.2 ### 4.71 ± 0.35 ### 0.36 ± 0.18 98.6 ± 1.0 15.6 ± 2.5 Note: * - p <0.05, *** - p <0.001 between flow 0 and 0.2 l / min, ### - p <0.001 between flow 0.2 and 0.5 l / min; where, EtO ₂ is the concentration of oxygen on expiration, FiO ₂ is the concentration of oxygen on inspiration, EtCO ₂ is the concentration of carbon dioxide on expiration, FiCO ₂ is the concentration of carbon dioxide on inspiration, StO ₂ is the oxygen saturation of the blood.

Thus, the use of a nasal cavity oxygen mask with a port to the gas analyzer creates the conditions for a diagnostic procedure for determining the concentration of oxygen and carbon dioxide in the submaskule space for inspiration and expiration, estimates of the frequency and depth of breathing, which allows you to immediately identify disorders and respiratory arrest, improve patient safety during operations and in the intensive care unit.

Claims (1)

A nasal cavity oxygen mask, including a mask with side openings for the inlet and outlet of the air mixture and the connector to the oxygen hose, characterized in that a port to the gas analyzer is installed in the nasal cavity oxygen mask.