KR20120041644A - Adaptor for endotracheal tube - Google Patents

Abstract

PURPOSE: An endotracheal tube connecting adapter is provided to make body fluid suction possible by using an oxygen inhaler and a catheter. CONSTITUTION: An endotracheal tube connecting adapter comprises first, second, and third connection parts(21, 22, 23) and a movable member(30). The second connector is connected to an oxygen supply device and communicates with the first connector. A catheter is inserted into the third connector which communicates with the first connector. The movable member comprises an insertion part and a movable part. In the insertion part, an insertion hole is formed. The movable part is movable in the insertion direction of the catheter.

Description

Adapter for endotracheal tube {Adaptor for endotracheal tube}

The present invention relates to an adapter for connecting an endotracheal tube capable of inserting a catheter through an endotracheal tube and supplying oxygen at the same time.

Lung disease produces a lot of phlegm in the lungs. Patients, children, and the elderly with weak respiratory muscles may not be able to spit out sputum well and the sputum may fill the lungs, making breathing difficult and, in severe cases, death. Therefore, draining sputum from the lungs of patients with lung disease is very important.

Typically, a suction catheter is inserted into the body through the respirator and the phlegm is discharged out of the body using a vacuum pressure. In general, the inhalation operator can not see the body because it does not know whether the catheter reaches the sputum standing position, and depending on the shape of the body can also occur if the catheter is caught in the partially concave part. Therefore, the operator repeatedly inserts and removes the catheter and discharges sputum, which causes the patient to feel pain and may damage the respiratory tract.

Patients who are unable to voluntarily breathe sufficiently rely on an oxygen respirator, which requires removal of the respirator and insertion of a catheter for sputum inhalation. Therefore, when the sputum inhalation time is long, blood oxygen concentration decreases, so the sputum discharge should be stopped and the oxygen respirator should be connected again.

The catheter is generally in the form of a flexible hollow tube. If the inside is temporarily narrowed by sputum, the inner pressure of the tube may be drastically lowered, and the inner walls of the tube may be constricted with each other. The sputum can no longer be suctioned and the catheter must be removed and reinserted.

It is an object of the present invention to provide an adapter for endotracheal tube connection, which enables simultaneous inhalation of body fluid using an oxygen respirator and a catheter.

Adapter according to an aspect of the present invention, the adapter for tracheal tube, the first connecting portion connected to the endotracheal tube; A second connection part connected to an oxygen supply device and in communication with the first connection part; And a third connector inserted into the catheter and communicating with the first connector.

The endotracheal tube connection adapter includes an insertion portion having an insertion hole into which the catheter is inserted, and a flow portion supporting the insertion portion to the third connection portion and movable in the insertion direction of the catheter, and connected to the third connection portion. It may further include a member.

The flow portion may be formed of a flexible material and may be corrugated in the insertion direction of the catheter.

The adapter may further include a stopper for blocking the insertion hole.

According to the adapter for connecting the endotracheal tube of the present invention, it is possible to supply oxygen during the fluid discharge operation using the catheter. In addition, since the catheter can be flown, the ease of catheter operation can be improved.

1 is a perspective view showing an example of a catheter;
2 is a partial cross-sectional view of the catheter shown in FIG. 1.
Figure 3 is a cross-sectional view showing a state that the walls are stricted with each other in the conventional catheter.
4 is a cross-sectional view showing the deformation of the wall due to the temporary blockage in the catheter shown in FIG.
5 is a partial cross-sectional view of another example of a catheter.
6 is a cross-sectional view showing a deformation of the wall by the temporary blockage in the catheter shown in FIG.
7 is a block diagram of the adapter for connecting the internal tube according to an embodiment of the present invention.
8 is a cross-sectional view showing an example of forming an insertion hole using an incision line.
9 is a cross-sectional view showing a state in which a catheter is inserted in an example of the insertion hole shown in FIG.
10 is a cross-sectional view showing a stopper for blocking the insertion hole.
11 is a sectional view showing an example of a flow section.
12 is a block diagram of an embodiment of a body fluid discharge device.
FIG. 13 is a view illustrating a catheter inserted into a respirator. FIG.
14 is a configuration diagram showing a state in which the valve is located in the second position.
15 is a configuration diagram of an embodiment of a control unit.
16 is a diagram showing an example of a drive signal for driving an actuator.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings refer to like elements, and the size or thickness of each element may be exaggerated for clarity.

1 is a perspective view showing an example of a catheter. 1, the catheter 1 includes a hollow tube 11 provided with an inlet 12 at one end thereof. The hollow tube 11 may be formed of a flexible material. 1 illustrates an example in which the inlet 12 is formed at the front end of the hollow tube 11, but the scope of the present invention is not limited thereto. Although not shown in the drawings, the inlet 12 may be formed at the tip and / or the side of the hollow tube 11. In addition, a plurality of suction ports 12 may be formed. The other end of the hollow tube 11 is provided with a connecting portion 13 for connecting with a pumping means (not shown) for providing a vacuum pressure.

FIG. 2 is a cross-sectional view of the catheter 1 shown in FIG. 1. 2, a plurality of ring-shaped members 15 are arranged inside the wall 14 of the hollow tube 11. The plurality of ring shaped members 15 are arranged to be spaced apart from each other. The arrangement interval P of the plurality of ring-shaped members 15 can be within the outer diameter D2 of the hollow tube 11. The ring shaped member 15 may be formed of various materials such as plastic, rubber, and metal.

In the process of inserting the catheter 1 into the body, for example into the respiratory tract, and sucking the body fluid, for example, sputum, the interior of the hollow tube 11 may be temporarily narrowed by the sucked sputum or blocked by sputum. In this case, the pressure inside the hollow tube 11 is drastically reduced by the vacuum pressure provided by the pumping means, so that the wall 14 is retracted inward. This phenomenon may occur even when the inlet 12 of the hollow tube 11 touches the inner wall of the respirator.

Referring to FIG. 3, since the hollow tube 11 ′ used in the conventional catheter 1 ′ is formed of a flexible material, the wall 14 ′ may be caused by a sharp decrease in pressure when the inside is partially or entirely blocked by sputum. As it retracts inwardly, it is narrowed and the hollow tube 11 'is blocked. In order to eliminate this blockage, it is necessary to remove the catheter 1 'and then remove the stenosis and then reinsert it or flow the catheter 1' several times in the insertion direction to eliminate the stenosis. In this process, there is a risk of damage to the inside of the respiratory tract by the catheter (1 '). In addition, while inserting the catheter (1 ') again, there is an inconvenience in that the sputum is found again.

According to the catheter 1 of this embodiment, the ring-shaped member 15 is inserted into the wall 14. When the inside of the hollow tube 1 is temporarily blocked or narrowed by sputum, the ring-shaped member 15 reinforces the rigidity of the wall 14 even if the internal pressure of the hollow tube 11 is increased. 14) is not constricted as shown in FIG. When the pressure inside the hollow tube 11 becomes somewhat high, the wall 14 deforms as shown in FIG. 4. That is, since the ring-shaped member 15 is supported by the ring-shaped member 15 of the wall 14, the portion 16 with the ring-shaped member 15 does not retract in the radial direction or the amount of retracted is very small. The portion 17 between the ring-shaped members 15 of the wall 16 is retracted inward and the portion 16 with the ring-shaped member 15 is retracted in the longitudinal direction of the hollow tube 11. At this time, the maximum constriction amount A of the retracted portion 17 of the wall 14 is 1/2 of the arrangement interval P of the ring-shaped member 15. According to the catheter 1 of this embodiment, since the arrangement | positioning spacing P of the ring-shaped members 15 is within the outer diameter D2 of the hollow tube 11, the maximum narrowing amount A is the outer diameter of the hollow tube D. It is smaller than 1/2 of (D2). Theoretically, since the maximum constriction amount A should be less than 1/2 of the inner diameter D1 of the hollow tube 11, the hollow tube 11 is not completely constricted, and therefore the arrangement interval P of the ring-shaped members 15 is It should be smaller than the inner diameter D1 of the hollow tube 11. However, since the ring-shaped member 15 substantially complements the rigidity of the hollow tube 11 and the hollow tube 11 itself also has some degree of rigidity, even if the hollow tube 11 is retracted in the longitudinal direction, The portions 16 with the ring shaped member 15 do not completely abut one another. Therefore, even if the arrangement | positioning space P of the ring-shaped members 15 is larger than the inner diameter D1 of the hollow tube 11, the wall 14 of the hollow tube 11 is constricted and it does not completely block. In general, when the arrangement interval P of the ring-shaped members 15 is smaller than the outer diameter D2 of the hollow tube 11, the hollow tube 11 is not completely blocked. Therefore, since the passage for discharging the sputum is formed in the hollow tube 11 to some extent, when the sputum blocking the inside of the hollow tube 11 is discharged, the hollow tube 11 is restored to its original shape. That is, unlike the conventional catheter 1 ', there is almost no need to remove the catheter 1' or make it flow several times in the insertion direction in order to eliminate the narrowing.

As shown in FIG. 5, the plurality of ring-shaped members 15 may be replaced with a spiral coil-shaped member 18. In this case, the pitch P1 of the helical coil-shaped member 18 is preferably within the outer diameter D2 of the hollow tube 11. That is, referring to FIG. 6, when the internal pressure of the hollow tube 11 is sharply lowered, the wall 14 between the pitches P1 of the coil-shaped member 18 is retracted inwardly from the lower side and the upper side. At this time, the maximum value of the narrowing amount (B1) (B2) of the wall 14, which squeezes on both sides is theoretically within 1/2 of the pitch P1, that is, within 1/2 of the outer diameter D2, 11) may be completely blocked, but as described with respect to FIG. 4, the maximum value is substantially 1/2 of the inner diameter D1 due to the rigidity of the coil-shaped member 18 itself and the rigidity of the wall 14. Falls short of Therefore, even if the pitch P1 of the helical coil-shaped member 18 is within the outer diameter D2 of the hollow tube 11, the inside of the hollow tube 11 is not constricted so that it may be completely blocked.

As described above, according to the catheter 1 of the present invention, the catheter 1 'is repeatedly inserted into and out of the respirator in order to eliminate the temporary blockage as in the conventional catheter 1'. The difficulty of repeating the sputum's sputum away from the sputum and trying to find it again can alleviate the risk of respiratory damage and patient pain. In addition, when the inside of the hollow tube 11 is temporarily blocked or narrowed by the suctioned phlegm as shown in FIGS. 4 and 6, the catheter 1 ′ in which the wall 14 ′ is completely adsorbed is different. Alternatively, the wall 14 is retracted in the longitudinal direction. The inlet 12 is then lifted slightly from where the sputum has gathered to separate the inlet 12 from the sputum. Therefore, the phlegm in the hollow tube 11 is easily discharged by the vacuum pressure of the pumping means, so that clogging of the hollow tube 11 is quickly recovered. Then, the pressure inside the hollow tube 11 is restored to its original state and the hollow tube 11, which has been retracted in the longitudinal direction, is also restored to its original state, and the suction port 12 of the hollow tube 11 enters the collected sputum again. Therefore, it is easy to discharge phlegm.

Figure 7 is a block diagram of an adapter for connecting the internal tube according to an embodiment of the present invention. A patient having difficulty breathing may supply oxygen through the nasal cavity, or insert the endotracheal tube 100 into the airway through the oral cavity or bronchial incision, thereby supplying oxygen. In the case of oxygen supply through the nasal cavity, it is possible to discharge phlegm using the catheter 1 without interrupting the oxygen supply. However, in the case of a severe patient, the tracheal tube 100 is inserted into the airway through the oral cavity or bronchial incision and the oxygen supply tube 10 is connected to the tracheal tube 100 to supply oxygen. In this case, the oxygen supply tube 10 must be removed from the endotracheal tube 100 and the catheter 1 inserted for sputum discharge. This prevents the patient from receiving oxygen during sputum removal. In severe patients, when the oxygen supply is interrupted, the oxygen level in the blood may decrease.

Adapter 2 of the present embodiment is characterized in that the sputum discharge using the catheter 1 and the oxygen supply is possible at the same time. Referring to FIG. 7, the adapter 2 of the present embodiment includes first, second, and third connectors 21, 22, and 23. For example, the adapter 2 may be implemented as a cylindrical member 24 provided with the first, second, and third connectors 21, 22, 23. The first connecting portion 21 is connected to the internal tube 100. The first connecting portion 21 and the internal tube 100 may be fastened or separated by, for example, a screw method. The second connector 22 is connected to an oxygen supply device (not shown) through the oxygen supply tube 10. For example, an oxygen supply tube 10 extending from the oxygen supply device may be connected to the second connector 22. The third connecting portion 23 is for inserting the catheter (1). The catheter 1 may be inserted into the human body through the third connector 23 and the first connector 21.

The flow member 30 is coupled to the third connector 23. The flow member 30 supports an insertion part 32 having an insertion hole 31 into which the catheter 1 is inserted, and supports the insertion part 32 to the third connection part 23 in the insertion direction of the catheter 1. It has a flowable flow part 33. Insertion hole 31 may be provided with a structure that serves as a check valve. For example, when the insert 32 is made of an elastic material such as rubber, the thickness of the portion 34 in which the insertion hole 31 of the insert 32 is to be formed is partially shown in FIG. 8. It can be thinned to form an incision 35. In the state in which the catheter 1 is not inserted, the insertion hole 31 is maintained blocked by elasticity. When the catheter 1 is inserted, as shown in FIG. 9, the incision line 35 is opened and the thin portion 34 is pushed inward to form the insertion hole 31. The structure of the insertion hole 31 shown in FIGS. 8 and 9 is only an example. For example, as shown in Figure 10, further provided with a stopper 36 to block the insertion hole 31, in the state in which the catheter 1 is removed using a stopper 36 to block the insertion hole 31 , If you want to inhale phlegm, the stopper 36 may be removed and the catheter 1 may be inserted through the insertion hole 31.

Adapter 2 of the present embodiment is characterized in that the sputum discharge and oxygen supply using the catheter (1) at the same time, the insertion hole 31 is the catheter (1) in order to achieve a smooth oxygen supply during the operation for sputum discharge It should be in close contact with to minimize the leakage of oxygen. The catheter 1 needs to move to some extent in the insertion direction for sputum discharge, but it is not easy to move the catheter 1 in a state where the insertion hole 31 and the catheter 1 are in close contact with each other. Thus, the flow member 30 of the present embodiment has a flow portion 33 to allow flow of the catheter 1. Flow portion 33 may be corrugated in the insertion direction of the catheter 1, for example, as shown in FIG. One end portion 37 of the flow portion 33 may be connected to the third connecting portion 23 by being coupled to the cylindrical member 24 and the other end portion 38 may be connected to the insertion portion 32. In addition, as shown in FIG. 11, the flow part 33 may be formed of a flexible material capable of allowing flow in the insertion direction of the catheter 1.

As such, the adapter 2 of the present embodiment enables simultaneous insertion of the catheter 1 for supplying oxygen and sputum discharge through the tracheal tube 100. Therefore, sputum discharge can be performed without causing hypoxia.

12 is a configuration diagram of an embodiment of a body fluid discharge device. Referring to FIG. 12, the body fluid discharge device may include pumping means 210 for supplying a vacuum pressure for discharging the body fluid to the catheter 1 inserted into the body. Drained body fluids, such as sputum, may be received in drain 260. The catheter 1 may be inserted into the respiratory tract through the airway through the oral cavity. In addition, the catheter 1 may be inserted into the respiratory tract via the endotracheal tube 100 inserted into the airway through the oral cavity or bronchial incision.

For example, in the case of sputum discharge operation, it is not easy to insert the catheter 1 into the sputum. Even if the operator is skilled in sputum discharge, the patient's posture or the position of the patient's neck is repeated and the catheter 1 is inserted and removed, and the sputum is returned to the deceased position (E of FIG. 13). . One reason for the catheter 1 not being able to easily find its position in the phlegm is that the tip of the catheter 1, i.e., the portion where the inlet 12 is located, is locally low in the respirator. You may get stuck in (C) and can't move forward anymore. In this case, the operator repeats the operation of retracting the catheter 1 and advancing it.

In order to solve the above problems, the body fluid discharge device of the present embodiment is located between the catheter 1 and the pumping means 210 includes a vibration means 250 for intermittent vacuum pressure to induce vibration of the catheter 1 do. The vibration means 250 includes a valve 220 having a first position (see FIG. 12) for transmitting the vacuum pressure to the catheter 1 and a second position (see FIG. 14) for communicating the vacuum pressure to the atmosphere, and a valve ( An actuator 230 for driving 220 and a control unit 240 for controlling the actuator 230 to periodically switch the valve 220 to the first and second positions. In particular, the vibration means 250 of the present embodiment communicates with the atmosphere instead of completely blocking the vacuum pressure transmitted to the catheter 1, so that the pressure shock due to the rapid vacuum pressure is blocked, the pumping means 210 and the pumping means 210. And it is characterized in that configured to prevent the hammering generated by being transmitted to the path connecting the valve 220.

The valve 220 may be in any form switchable to the first and second positions. Actuator 230 may be a solenoid, for example. For example, a commercially available solenoid valve may be employed in which valve 220 and solenoid 230 are combined.

The controller 240 generates a drive signal for driving the actuator 230. For example, as illustrated in FIG. 15, the controller 240 generates an oscillation waveform, and the oscillation waveform has a predetermined duty ratio. A monostable multivibrator 242 as waveform shaping means for shaping into a signal waveform to have, and an amplifier 243 for amplifying the signal waveform to generate a drive signal. The frequency of the driving signal may be, for example, about several to several tens of hertz (Hz). The configuration of the control unit 240 shown in FIG. 15 is just an example, and the scope of the present invention is not limited thereto.

By the above configuration, the actuator 230 periodically switches the valve 220 to the first and second positions by the driving signal. When the valve 220 is positioned in the first position, the vacuum pressure is transmitted to the catheter 1, and when the valve 220 is positioned in the second position, the vacuum pressure is communicated with the atmosphere and is transmitted to the catheter 1. The vacuum pressure is rapidly lost and reduced. This periodic supply and decrease of vacuum pressure causes vibration of the catheter 1. That is, as shown in FIG. 13, since the tip portion of the catheter 1 periodically vibrates, it is easily escaped from the locally low position C by artificially retreating the catheter 1, and is shown by a dotted line. As can be moved to the position (E) where the phlegm collected.

The duty ratio of the signal waveform is preferably within 50%. That is, referring to FIG. 16, it is preferable that the ratio d = t / T of the time t when the signal at which the valve 220 is positioned at the second position with respect to the period T of the signal waveform is applied is within 0.5. . By such a configuration, while reducing the loss of vacuum pressure for the discharge of sputum can cause the vibration of the catheter 1 to easily operate the catheter 1 can discharge the sputum.

When the catheter 1 shown in Figs. 1, 2 and 5 is employed in the above-described body fluid discharge device, the longitudinal vibration of the catheter 1 can be easily induced. That is, when the tip of the catheter 1 is in the position C, the inlet 12 is in the same state as the blockage, and when the vacuum pressure is provided in this state, the catheter 1 is shown in FIG. 4 or 6. Likewise, it is temporarily retracted in the longitudinal direction, and is restored to its original state when the vacuum pressure is reduced. Therefore, when the vacuum pressure is periodically provided / decreased to the catheter 1, the tip portion of the catheter 1 may vibrate as shown in FIG. 13 to easily leave the position C. FIG.

In addition, when the adapter 2 shown in FIGS. 7-11 is employ | adopted as the body fluid discharge apparatus mentioned above, oxygen supply is possible in a sputum discharge operation.

In the above-described embodiment, a case of discharging phlegm inside the human body has been described, but the scope of the present invention is not limited thereto. The catheter, adapter, and body fluid ejection device described herein may be applied to animals.

The above embodiments are merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined by the technical idea of the invention described in the following claims.

1, 1 '... catheter 2 ... Adapter for pipe connection
11, 11 '... hollow tube 12 ... intake
13 Connections 14, 14 '... wall
15 ... ring shaped members 21, 22, 23 ... first, second, third connection
24 ... cylindrical member 30 ... fluidic member
31 Insert hole 32 Insert part
33.flow section 34.incision
36 ... stopper 100 ... internal tube
10 ... oxygen supply tube 210 ... pump means
220 ... valve 230 ... actuator
240 ... control unit 250 ... vibration means
260 ... drain

Claims (5)

Adapter for endotracheal tube connection,
A first connection part connected to the endotracheal tube;
A second connection part connected to an oxygen supply device and in communication with the first connection part; And
Adapter for tracheal tube including a; catheter is inserted and the third connecting portion in communication with the first connecting portion. The method of claim 1,
And a flow member having an insertion portion having an insertion hole into which the catheter is inserted and a flow portion supporting the insertion portion to the third connection portion and movable in the insertion direction of the catheter, and connected to the third connection portion. Adapter for connection. The method of claim 2,
Adapter for connecting the tracheal tube, characterized in that the flow portion is formed of a flexible material. The method of claim 2,
The flow unit is an adapter for tracheal tube, characterized in that the corrugated form in the insertion direction of the catheter. The method according to any one of claims 2 to 4,
Adapter for connecting the tracheal tube further comprising a stopper for blocking the insertion hole.

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