KR101678545B1 - An endotracheal intubation system enabling verification of tube position using electrical stimulatio - Google Patents

Abstract

The present invention relates to an endotracheal intubation tube and an endotracheal intubation system for enabling the determination of whether a tube inserted in an endotracheal intubation is inserted correctly in the trachea or in the esophagus in order to secure a patient's airway. A tubular body; An electrode disposed on the tube body or the cuff surface and adapted to deliver current to the esophagus or organ according to the insertion position; And a sensor for measuring a change in pressure applied to the tube body due to the magnetic pole of the electrode. According to the present invention, the inserted position of the tube body can be determined through the measured pressure.

Description

[0001] The present invention relates to an endotracheal intubation system, and more particularly, to an endotracheal intubation system capable of determining an insertion position of a tube through electrical stimulation,

The present invention relates to an endotracheal intubation tube and an endotracheal intubation system that enable the determination of whether a tube inserted in an endobronchial organs is correctly inserted into an organs to secure a patient's airway.

Intubation is the technique of inserting a tube into the patient's organ. Endotracheal intubation is used to provide air or oxygen to the patient's airway in a variety of emergencies, such as when there is a risk of airway obstruction due to unconsciousness, when hypoxia or ventilatory depression is required, or when ventilation is required .

 The endotracheal tube is provided with an adapter at the upper end to which an oxygen source such as a respirator or an ambulatory bag can be connected, and supplies air from the connected oxygen source to the patient's airway through the tube body.

Conventional endotracheal intubation tubes are inserted through the vocal cords, and in this case, the operator inserts the tubes while visually checking the vocal cords using the laryngoscope. However, in an emergency, it is often difficult to visually confirm that the tube enters the organ through the vocal cords. At this time, if the tube is inserted into the esophagus rather than the airway, the patient may be exposed to hypoxia, resulting in brain damage or death. A prior art related to the intubation tube is Korean Patent Publication No. 2003-0003636.

The incidence of endotracheal intubation in the esophagus is reported to be 5% to 25% (Ann Emerg Med 1998; 31: 325-32; Jenkins WA et al. Am J Emerg Med 1994; 12: 413-6 .; Bozeman WP et al. Ann Emerg Med 1996; 27: 595-9 .; Katz SH et al. Ann Emerg Med 2001; 37: 32-7.)

 Therefore, when a tube is inserted into an organ, a method is needed to determine whether the tube is correctly inserted into the organ or incorrectly inserted into the esophagus. Previously, we assessed whether the tube was correctly inserted into the organ using a clinical evaluation method of observing chest wall motion or by stethoscope, or using an end-tidal CO2 detector, an end-tidal CO2 monitor, and an esophagus sensor.

In the case of conventional clinical evaluation, it has been reported that even if the tube is inserted into the esophagus, it is 0.4% ~ 15% that the stethoscope does not recognize it. Therefore, the conventional clinical evaluation method has a problem that the position of the endotracheal tube can not be accurately determined. (Menegazzi JJ et al. Anesth Analg 1990; 71: 440-6 .; Anderson KH et al. Anesthesiology 1989; 44: 984-5 .; Schwartz DE et al. Anesthesiology 1995; 82: 367-6 .; Stewart RD et al. Chest 1984; 85: 341 -5.)

Conventional end-of-life CO2 detectors and end-of-life CO2 monitoring systems are based on the principle that carbon dioxide is detected from the patient's exhalation when the intubation tube is correctly inserted into the organ. The end-of-term CO2 monitor has the advantage of being able to determine the location of the most intubated tube in the most accurate way known to date.

However, this method is problematic in that the blood flow to the lung is small, as in patients with massive pulmonary embolism or cardiac arrest, or in cases where artificial respiration is performed before oral intubation. (Takeda T Tanigawa K et al. Anesthesiology 2000; 93: 1432-6.

In addition, severe pulmonary edema can not be used if a large amount of secretion comes out through the endotracheal tube. In addition, there is a need for a relatively expensive carbon dioxide monitoring monitor in the actual field, and there is a disadvantage that preparations for a certain period of time are required before use.

The present invention seeks to provide an intubation tube and an endotracheal intubation system that enable the determination of whether an intubated tube is correctly inserted into the trachea or incorrectly inserted into the esophagus.

In order to accomplish the above object, the present invention provides an intubation tube for an endoscope, comprising: a tube body inserted into an organ of a patient; An electrode disposed in the tube body for supplying current to the organ; And a sensor for measuring a change in pressure applied to the tube body due to the magnetic pole of the electrode, wherein the insertion position of the tube body can be determined through the measured pressure.

The present invention also relates to a medical device comprising: a tube body inserted into an organ of a patient; A cuff which is disposed at the lower end of the tube body and expands to urge the patient's organ wall when the tube body is inserted into the trachea; An electrode disposed in the cuff and passing current to the squeezed engine wall; And a sensor for measuring a change in pressure applied to the cuff due to the stimulation of the electrode, wherein the insertion position of the tube body can be determined through the measured pressure.

The present invention also provides an endotracheal intubation tube inserted into an organ of a patient to supply air; A power supply unit for applying power to the intubation tube; And a display unit for displaying the result of the determination of the pressure of the intubation tube or the insertion position of the intubation tube. The power unit applies power to the electrode, and the display unit displays the measured pressure from the sensor, Another characteristic is that the position can be determined.

According to the present invention, it is possible to determine whether the inserted tube is inserted into the organ or the esophagus by measuring the change in pressure through the electric stimulus.

The present invention also has the advantage that it is possible to accurately determine whether the inserted tube is inserted into an organ or into the esophagus at an inexpensive manufacturing cost.

Figure 1 shows an endotracheal intubation tube according to one embodiment of the present invention.
Figure 2 shows an endotracheal intubation tube according to another embodiment of the present invention.
Figure 3 shows a cross-sectional view of the tube body.
Figure 4 shows an endotracheal intubation system according to another embodiment of the present invention.
FIG. 5 shows a pump of an endotracheal intubation system according to another embodiment of the present invention connected to a module including a power source unit and a display unit.
FIG. 6 shows the results of an experiment on an intubation intubation tube according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the exemplary embodiments. Like reference numerals in the drawings denote members performing substantially the same function.

1 shows an intubation intubation tube 1 according to an embodiment of the present invention. 1, an endotracheal intubation tube 1 includes a tube body 10 inserted into an organ of a patient; An electrode (30) disposed in the tube body (10) and for supplying electric current to the organ; And a sensor 50 for measuring a change in the pressure applied to the tube body 10 due to the magnetic pole of the electrode 30.

An adapter 101 for connecting with the oxygen supplier may be connected to the upper end of the tube body 10 and an expansion part 60 may be provided inside the lower end of the tube body 10 to expand the tube body 10, May be provided. The expanding part 60 may be inflated by receiving air from a check valve 701 connected through a tube tube 103 (FIG. 3) formed along the longitudinal direction inside the tube body 10.

In the present embodiment, the tube body 10 may be made of a material having a rigid upper portion and a soft material capable of bending and expanding the lower portion. The check valve 701 is capable of injecting air into the inflation section 60 and inflating the inflation section 60 to prevent backflow of the air supplied into the patient's organ through the tube body 10, So that the pressure can be kept constant.

One or more electrodes 30 may be disposed on the tube body 10. Electrode 30 includes means for current stimulation in the trachea wall or esophagus of a patient, and may be conductive in this embodiment. The electrode 30 can be powered from a conductor 40 connected to the inside of the tube body 10 through a tube tube 104 (FIG. 3) formed along the longitudinal direction.

When the electrode 30 inserted into the organism together with the tube body 10 applies electrical stimulation to the organ (airway), the organ does not shrink because it is made of cartilage and a fiber elastic membrane. On the other hand, when the electrode 30 is inserted into the esophagus and electrical stimulation is applied to the esophagus, the esophagus shrinks because it is a fibrous muscle tissue.

The sensors 50 and 50 may be a piezoelectric sensor 50 in this embodiment. In this case, the piezoelectric sensor 50 can be placed on the tube body 10 or placed on the inflation part 60 disposed inside the tube body 10 to measure the pressure applied to the tube body 10 .

 The sensors 50, 50 may be a pressure sensor 50 in yet another embodiment. The pressure sensor 50 is disposed in the check valve 701 and can measure a change in pressure applied to the tube body 10 by measuring the air pressure of the expanding portion 60. In another embodiment, the pressure sensor 50 is disposed on a module provided with a power source unit 80 and a display unit 90 described later in FIG. 4 and connected to the check valve 701 to apply a voltage to the tube body 10 The change in pressure can be measured. Thus, the sensors 50 and 50 mean means for measuring a change in pressure applied to the tube body 10 according to the current stimulus.

As a result, if there is no change in the pressure applied to the tube body 10 or if there is only a small rise, the user can judge that the tube is correctly inserted into the tube. If the pressure applied to the tube body 10 is elevated, It can be judged that the tube 1 is inserted into the esophagus.

The endotracheal intubation tube 1 according to the present embodiment is inserted into the organ through the oral cavity of the patient. After the tube body 10 is inserted into the organ, the practitioner inflates the inflating unit 60 by injecting air at a constant pressure through the check valve 701. The expandable portion 60 provided inside the tube body 10 expands and the tube body 10 can be brought into close contact with the engine wall.

After the tube body 10 is brought into close contact with the engine wall, when the electrodes 30 disposed in the tube body 10 pass current to the engine wall, the sensors 50 and 50 measure the change in pressure. If there is no change in pressure or only a small pressure rise, it can be judged that the intubation tube 1 is correctly inserted into the trachea, and then air is supplied to the patient's airway.

Although not shown in the figures, the intubation tube according to the present embodiment may not include the inflation portion 60 inside the tube body 10. In the case of a child, an intracoracal intubation tube without the expanding portion 60 or the cuff 70 may be used, and a person skilled in the art will understand that the tube body 10 is inserted into the trachea by the above- As shown in Fig.

2 shows an intubation intubation tube 1 according to another embodiment of the present invention. Referring to Fig. 2, a cuff 70 that expands to urge the patient's tracheal wall may be disposed outside the lower end of the tube body 10. [ Unlike FIG. 1 in which the tube body 10 is brought into close contact with the patient's organ wall, the cuff 70 disposed outside the tube body 10 forces the organ wall of the patient.

The cuff 70 functions to prevent the secretions from the oral cavity and the pusum from entering the lungs by expanding and to prevent the air and oxygen supplied through the tube body 10 from escaping into the space between the tube body 10 and the organ It plays a role.

In this case, the electrode 30 is disposed in the cuff 70 so that current can flow through the wall of the squeezed engine. The sensors 50 and 50 may be a piezoelectric sensor 50 disposed on the cuff 70 so as to be able to measure the change in pressure applied to the cuff 70 due to the stimulation of the electrode 30. [ Or disposed on the module with the check valve 701 or with the power supply 80 (FIG. 4) and the display 90 (FIG. 4) as described above and the pressure of the cuff 70 The pressure sensor 50 may be a pressure sensor for measuring the pressure.

The electrode 30 includes means for stimulating the current in the trachea wall or esophagus of the patient, and may be a conductive ink in this embodiment.

The intubation intubation tube 1 has a structure in which the electrode 30 disposed on the cuff 70 applies current stimulation to an organ made up of esophageal or cartilaginous tissue composed of muscle tissue to detect whether the tissue is contracted or not 50, and 50 may be measured to determine whether the tube body 10 has been inserted into the trachea or the esophagus.

Fig. 3 shows a cross-sectional view of the tube body 10. Fig. Referring to FIG. 3, tube tubes 103 and 104 are formed in the tube body 10 along the longitudinal direction. A plurality of tube tubes 103 and 104 may be formed so that the conductor 40 is connected to the electrode 30 through the tube tubes 103 and 104 or the check valve 701 is connected to the cuff 70 or the bulge 70. [ (Not shown).

4 shows an intramuscular intubation system 2 according to another embodiment of the present invention. Referring to FIG. 4, the intubation system 2 includes an intubation tube 1, 1 inserted into an organ of a patient to supply air; A power supply unit (80) for applying power to the intubation tubes (1, 1); A display part (90) for displaying the measured pressure of the intubation tube (1, 1); Sensors (50, 50) for measuring the pressure applied to the cuff (70) of the intubation tubes (1, 1); And a pump 703 that inflates the cuff 70 by injecting air into the check valve 701. The intubation tubes 1 and 1 according to the present embodiment may be constructed integrally with the check valve 701 and the connection terminal 401 formed at the end of the conductor 40 as shown in FIG.

The power source unit 80 is connected to the connection terminal 401 formed at the end of the conductor 40 to apply power to the electrode 30 and the display unit 90 can display the measured pressure from the sensors 50 and 50 have. In this case, as described above, the pressure sensor 50 is disposed on the module including the power source unit 80 and the display unit 90, and can measure the pressure of the cuff 70 through the check valve 701. [

The practitioner can check the change in the pressure displayed on the display unit 90 to determine whether the intubation intubation tube 1, 1 has been inserted into the trachea or the esophagus. In this embodiment, the display unit 90 can display a change in pressure, and can display whether the insertion position of the tube body 10 is an organ or an esophagus based on a change in pressure.

5 shows a pump 703 of the endotracheal intubation system 2 according to another embodiment of the present invention connected on a module equipped with a power source unit 80 and a display unit 90. [ The pump 703 is connected to the check valve 701 to inject air for expanding the cuff 70 to a certain pressure. The pump 703 means a means for directing air, for example, a syringe may be used.

In this embodiment, the pump 703 may be connected to a module provided with the power supply unit 80 and the display unit 90. [ In this case, the check valve 701 and the connection terminal 401 are connected to the module including the power supply unit 80 and the display unit 90, and the pump 703 injects air into the connected check valve 701.

When the pressure sensor 50, the check valve 701, the connection terminal 401 and the pump 703 are connected to the module including the power supply unit 80 and the display unit 90, The cuff 70 can be inflated at a constant pressure while checking the pressure measured from the sensor 50 on the display unit 90.

FIG. 6 shows the result of an experiment on an intubation tube 1, 1 according to an embodiment of the present invention. The experiment was conducted by measuring the pressure change of the cuff 70 according to various electric stimulation methods using about 25 kg of pigs.

Referring to Fig. 6 (a), when the intubation tubes 1 and 1 are correctly inserted into the trachea, it is possible to confirm that there is no pressure change 23 in the section of the electric stimulation 21. In the present embodiment, the stimulation condition was an electrical stimulation with a current of 30 mA and a frequency of 20 Hz.

Referring to FIG. 6 (b), when the endotracheal intubation tube 1, 1 was inserted into the esophagus, the pressure was measured at 70 mmHg at 30 mmHg from 40 mmHg for the electric stimulus 21 section. Therefore, the pressure change 25 can be visually confirmed when the intubation tube 1, 1 is inserted into the esophagus. In the present embodiment, a stimulation condition was set by setting a current of 20 mA to a frequency of 20 Hz and applying electric stimulation.

According to this embodiment, even if an electric stimulation of 30 mA maximum is applied, it does not affect the heart rhythm. In case of stimulation with a current range of 10 mA or more under the condition that the pulse width is 1 ms and the frequency is 40 Hz, ) Was inserted into the trachea or esophagus.

As described above, according to the embodiment of the present invention, only the electrodes (30) and the sensors (50, 50) capable of measuring the change in pressure can be used as the organ The insertion position of the intubation tubes 1, 1 can be judged with high accuracy. Further, it is possible to implement the intubation tubes 1, 1 in which the insertion position can be judged at a low manufacturing cost.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. will be. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by all changes or modifications derived from the scope of the appended claims and equivalents of the following claims.

1, 1 ': Intubation tube 2: Intubation system
21: electric stimulation section 23, 25: change of pressure
10: tube body 101: adapter
103, 104: tube tube 30: electrode
40: conductor 401: connection terminal
50, 50 ': sensor 60:
70: Cuff 701: Check valve
703: Pump 80: Power supply
90:

Claims (9)

A tube body inserted into an organ of a patient;
An electrode disposed inside the tube body along the longitudinal direction of the tube body and flowing an electric current received from the conductor to the organ or the esophagus according to the insertion position of the tube body;
A sensor disposed in the tube body for measuring a change in pressure applied to the tube body in accordance with the contraction of the organ or esophagus by the stimulation of the electrode; And
And a display unit for displaying whether the insertion position of the tube body through the pressure measured by the sensor is an esophagus composed of muscle tissue or an organ made of cartilage tissue,
Wherein the tube body includes a tube tube formed along a longitudinal direction thereof and connected to the electrode through the tube tube, wherein the electrode is a conductive ink.
The method according to claim 1,
An expanding part disposed inside the tube body and expanding to the outside of the tube body;
Further comprising:
Wherein the sensor measures the change in pressure applied to the tube body by the tube in the tube body in response to the contraction of the organ or esophagus by the stimulation of the electrode,
A tube body inserted into an organ of a patient;
A cuff which is disposed outside the lower end of the tube body and expands to urge the trachea or esophagus wall of the patient according to the insertion position of the tube body;
An electrode disposed in the cuff and flowing current to the urged tracheal wall or esophagus wall;
A sensor disposed in the cuff for measuring a change in pressure applied to the cuff in accordance with the contraction of the trachea wall or esophagus wall by the stimulation of the electrode; And
And a display unit for displaying whether the insertion position of the tube body through the pressure measured by the sensor is an esophagus composed of muscle tissue or an organ made of cartilage tissue,
Wherein the tube body includes a tube tube formed along a longitudinal direction thereof and connected to the electrode through the tube tube, wherein the electrode is a conductive ink.
The method of claim 3,
Wherein the sensor is a piezoelectric sensor disposed on the cuff.
The method of claim 3,
Further comprising a check valve for injecting air to inflate the cuff,
Wherein the sensor is a pressure sensor disposed on the check valve.
delete delete An intubation tube inserted into the patient's organ to supply air;
A sensor for measuring a pressure of the endotracheal intubation tube;
A power supply unit for applying power to the intubation tube; And
And a display unit for displaying a result of the determination of the pressure of the intubation tube or the insertion position of the intubation tube,
Wherein the intubation-
A tube body inserted into an organ of a patient;
A cuff that is disposed at a lower end of the tube body and expands to urge the trachea or esophagus wall of the patient according to the insertion position of the tube body; And
An electrode disposed in the cuff and operative to deliver current to the pressurized tracheal wall or esophagus wall,
The power source applies power to the electrode,
Wherein the sensor measures a change in pressure applied to the cuff in accordance with contraction of the trachea wall or esophagus wall by the stimulation of the electrode,
The display unit displays whether the insertion position of the tube body through the pressure measured by the sensor is an esophageal muscle tissue or an organ made of cartilage tissue,
Wherein the tube body includes a tube tube formed along a longitudinal direction thereof and connected to the electrode through the tube tube, wherein the electrode is a conductive ink.
9. The method of claim 8,
A check valve for injecting air to inflate the cuff; And
A pump for inflating the cuff by injecting air into the check valve;
Further comprising: an endotracheal intubation system.

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