JP2010220717A - Suction system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a suction system for sucking sputum without forcing huge labor to a caregiver and without damaging a mucous membrane inside the trachea of a patient. <P>SOLUTION: The suction system 1 sucks saliva and the sputum sucked by a suction device 100, and includes: a continuous suction line 20 connected to a tracheal cannula 50 indwelt inside the trachea, for continuously sucking the sputum generated inside the trachea; and an occasional suction line 10 for sucking the saliva inside the oral cavity or the sputum accumulated inside the trachea as needed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a suction system for sucking sputum and saliva.

Conventionally, as a ventilation route of artificial respiration, one having a tracheotomy hole as a route is mentioned. Artificial respiration using this tracheotomy hole as a route is performed by an artificial respiration apparatus through a hole formed by incising the trachea. A tracheal cannula connected to the intubation is placed in the trachea to supply or exhaust air.
According to the artificial respiration through this tracheostomy hole, although there is a merit that ventilation efficiency is higher than other ventilation routes such as artificial respiration by insertion of trachea and mask type artificial respiration, it was placed in the trachea. The disadvantage is that the tracheal cannula stimulates the inner surface of the trachea, increasing sputum secretion. Therefore, when treating artificial respiration through the tracheostomy hole, it is necessary to treat sputum that may block the airway.

  In this regard, according to the following patent document, a suction system capable of sucking a sputum in the vicinity of a tracheal cannula placed in the trachea at any time is disclosed.

  Specifically, in Patent Document 1, a suction thin tube is provided on the outer peripheral side surface of the tracheal cannula to suck the phlegm accumulated on the upper side of the cuff, and is provided in a main suction pump connected to the tracheal cannula so that the tracheal cannula is clogged. A system for sucking sputum is disclosed.

  Patent Document 2 uses a double-tube tracheal cannula in which a suction path for sputum suction is separately formed in addition to a breathing path for air supply and exhaust. A system for sucking accumulated soot by connecting a suction device is disclosed.

Japanese Patent Laid-Open No. 2002-219175 (see FIG. 1) Japanese Patent Laying-Open No. 2004-283329 (refer to claim 6, FIG. 3)

  However, using the system disclosed in the above-mentioned patent document to aspirate the sputum accumulated in the trachea at any time requires a great deal of labor for the caregiver of the patient (hereinafter referred to as “caregiver”). It was work.

  On the other hand, in order to reduce the labor described above, the suction system disclosed in the above-mentioned patent document may be considered to continuously suck the wrinkles generated in the trachea with the suction system disclosed in the above-mentioned patent document. The suction pressure is generally a very high suction pressure of about -18 kPa. Therefore, the mucous membrane in the trachea is very weak, and there is a possibility that the mucous membrane in the trachea may be damaged if the sputum is sucked continuously with the suction pressure.

  Accordingly, in view of the above problems, the present invention provides a suction system capable of sucking sputum without forcing a caregiver with great effort and without damaging the mucous membrane in a patient's trachea. Let it be an issue.

  In order to solve the above problems, an aspiration system according to the present invention is an aspiration system that is aspirated by a suction device to aspirate saliva and sputum, and is connected to a tracheal cannula placed in the trachea. A continuous suction line for continuously sucking wrinkles generated in the tube, and a continuous suction line for sucking saliva in the oral cavity or wrinkles accumulated in the trachea as needed.

  According to the invention, since the wrinkles generated in the trachea are continuously sucked by the continuous suction line, the wrinkles are not accumulated in the trachea, and the caregiver has the labor of performing suction whenever the fistula accumulates. It is reduced. Further, since the suction pressure continuously sucked by the continuous suction line is lower than that at any time, there is no possibility of damaging the mucous membrane in the patient's trachea.

  The configuration according to claim 2 is characterized in that the tracheal cannula has a cuff on the outer peripheral surface on the distal end side, and the continuous suction line sucks sputum at a lower part of the cuff on the lung side.

According to the above configuration, since the sputum is continuously sucked by the continuous suction line at the lower part of the cuff on the lung side, there is no possibility that the sputum is clogged in the respiratory tract of the tracheal cannula.
In addition, when a gap is formed between the cuff and the inner wall of the trachea and saliva flows into the trachea, the continuous suction line can suck the saliva.

  According to a third aspect of the present invention, a fluctuation-compatible pressure regulator corresponding to fluctuations in suction pressure is provided between the suction device and the continuous suction line and the occasional suction line.

  According to the above configuration, since the fluctuation-compatible pressure regulator is interposed between the suction device and the continuous suction line and the occasional suction line, even if the suction pressure of the suction device fluctuates, the continuous suction line and the occasional suction line Is sucked at a constant suction pressure.

  According to a fourth aspect of the present invention, the continuous suction line includes a flow meter that controls a flow rate to be sucked and a safety mechanism that detects whether or not the flow rate to be sucked is within a predetermined flow rate. To do.

According to the said structure, when the flowmeter which controls the flow volume of a continuous suction line fails, a safety mechanism detects the raise of the flow volume by failure.
Therefore, the risk of damaging the mucous membrane in the patient's trachea can be prevented by increasing the suction force of the continuous suction line accompanying the increase in flow rate.

  According to a fifth aspect of the present invention, the continuous suction line includes a flow meter for controlling a flow rate to be sucked, and the flow meter is a pressure fluctuation-compatible flow meter corresponding to a change in suction pressure. Features.

  According to the above configuration, since the continuous suction line is equipped with the pressure fluctuation type flow meter, the flow rate of the continuous suction line does not change even if the suction pressure fluctuates, and the mucous membrane in the trachea of the patient may be damaged. Can be avoided.

  As described above, according to the present invention, it is possible to provide an aspiration system capable of aspirating sputum without imposing great efforts on a caregiver and without damaging the mucous membrane in a patient's trachea.

It is a figure which shows the structure of the suction system in embodiment. It is side surface sectional drawing which shows the cross section when the tracheal cannula indwelled in the patient's trachea is seen from the side surface. It is a side view which shows the safety mechanism used for embodiment.

  Next, an embodiment of a suction system according to the present invention will be described with reference to the drawings.

(Suction system 1)
The suction system 1 is a system that collects and removes sputum and saliva from the body of the patient S by applying a negative pressure to the suction tube or the like inserted through the body of the patient S using a suction device.
As shown in FIG. 1, the suction system 1 according to the embodiment includes a suction line 10 that can be inserted into the oral cavity of the patient S or the tracheal cannula 50 at one end, and a tracheal cannula in which one end is placed in the trachea of the patient S. 50, a variable pressure regulator 40 connected to the suction line 10 and the other end of the continuous suction line 20 as needed, and a suction device 100 connected to the variable pressure regulator 40. It becomes.

(Suction line 10 as needed)
The occasional suction line 10 shown in FIG. 1 is a line for sucking saliva in the oral cavity of the patient S or sputum accumulated in the trachea as needed. Saliva or gas sucked from the oral cavity of the patient S and the pressure regulator 12 that controls the suction pressure of the suction tube 11 that is sucked by the suction device 100 and the suction tube 11 that communicates the inside of the tube with the variable pressure regulator 40 It comprises a fluid recovery container 17 for recovering the soot sucked from the inside of the tube.

At any time, the suction tube 11 is connected to the fluctuation-compatible pressure regulator 40 at one end side, and is sucked into the suction device 100 through the fluctuation-compatible pressure regulator 40, so that saliva in the oral cavity from the other end side. Or the saliva collected in the trachea can be sucked.
When the saliva in the oral cavity is sucked, the other end of the suction tube 11 is inserted through the other end of the suction tube 11 from the pharynx of the patient S as shown in FIG. So as to enter the oral cavity. On the other hand, when suctioning the sputum accumulated in the trachea, as shown in FIG. 2, it is made to enter to the extent that it reaches the trachea through the respiratory path 51 formed in the tracheal cannula 50.
As shown in FIG. 2, the tracheal cannula 50 is placed in the trachea of the patient S, and is in a tubular shape curved in a substantially J shape in a side view in which a breathing path 51 is formed to supply and exhaust air. It is a member. And as shown in FIG. 1, the other end side of the artificial respiration tube connected to the artificial respiration apparatus is detachably connected to one end side of the respiratory path 51. The tracheal cannula 50 preferably includes a cuff 52 on the outer peripheral surface on the distal end side. The cuff 52 is a member that is inflatable by inflowing gas, and the tracheal cannula 50 can be fixed in the trachea by inflating the gas by inflowing with a cuff tube (not shown).

The pressure regulator 12 is a device for controlling the suction pressure of the suction tube 11 that is negatively applied to the suction device 100 to a predetermined suction pressure, so that the suction tube 11 can be inserted into the oral cavity as needed. It is possible to aspirate the saliva or the sputum accumulated in the trachea at any time.
In addition, the predetermined suction pressure here is zero when no suction is performed at any time, and on the other hand, when suction is performed at any time, the suction tube 11 accumulates in the saliva or trachea in the oral cavity at any time. The suction pressure that can suck the soot is generally about -18 kPa. In addition, the pressure regulator 12 shall have the operation part which is not shown in figure for the patient S or the caregiver of the patient S to adjust the suction pressure of the suction tube 11 at any time.

  The fluid recovery container 17 is a container for recovering saliva or sputum sucked into the suction tube 11 as needed.

(Continuous suction line 20)
The continuous suction line 20 shown in FIG. 1 is a line for continuously sucking sputum generated in the trachea of the patient S, and the sputum suction tube 53 provided in the tracheal cannula 50 and the fluctuation-compatible pressure regulator 40. A continuous suction tube 21 that communicates with each other, a pressure fluctuation type flow meter 22 that adjusts a flow rate sucked by the continuous suction tube 21, and a safety that detects whether the flow rate sucked by the continuous suction tube 21 is a predetermined flow rate or less. It comprises a mechanism 23 and a fluid recovery container 27 that recovers the soot sucked by the continuous suction tube 21.

One end of the continuous suction tube 21 shown in FIG. 1 is connected to the fluctuation-compatible pressure regulator 40. Further, the continuous suction tube 21 can suck the sputum suction tube 53 connected to the other end side by being sucked by the suction device 100 through the fluctuation-compatible pressure regulator 40.
As shown in FIG. 2, the sputum suction tube 53 connected to the other end side of the continuous suction tube 21 is a thin tubular tube, and one end side is provided with a connection portion, and the connection portion is interposed therebetween. The continuous suction tube 21 of the continuous suction line 20 is connected (see FIG. 1). The other end side of the sputum inhalation tube 53 is located on the lung side (downstream side) of the cuff 52 of the tracheal cannula 50 and on the outer peripheral surface of the lower side (esophageal side) of the tracheal cannula 50. Yes. Thereby, the continuous suction tube 21 sucks the soot suction tube 53, so that soot generated in the trachea can be sucked. 2 is embedded in the tube wall forming the respiratory tract of the tracheal cannula 50. However, the present invention is not limited to this, and the narrow tube forming the sputum suction tube 53 is a trachea. It may be provided in the respiratory path 51 which is the outer peripheral surface of the cannula 50 or the inner peripheral surface side of the tracheal cannula 50.
Alternatively, the tracheal cannula 50 without the cuff 52 may be used to suck saliva that has flowed from the oral cavity at the same time as suctioning the sputum.
In addition, the continuous suction line 20 creates a gap between the tracheal wall and the cuff 52 of the tracheal cannula 50 when the patient S changes its position or breathes greatly, and saliva flows into the trachea from the oral cavity. In some cases, the saliva can be aspirated.

(Pressure variation type flow meter 22)
The pressure fluctuation-compatible flow meter 22 shown in FIG. 1 is a device that controls the flow rate of suction from the continuous suction tube 21 sucked by the suction device 100.
Note that the flow rate meter 22 that supports the pressure fluctuation is a flow rate that allows the continuous suction tube 21 to suck the soot that has accumulated in the trachea. The flow rate is preferably such that the inner mucous membrane is not damaged, and is generally controlled to about 300 ml / min.
Further, the pressure fluctuation-compatible flow meter 22 is based on a thermal flow sensor (not shown) and a flow signal output from the thermal flow sensor in response to a change in the suction pressure for sucking the continuous suction tube 21. A flow control valve that can be controlled by an epizo or solenoid actuator is provided. Therefore, even if the suction pressure on the downstream side of the pressure fluctuation type flow meter 22 changes, the opening degree of the flow control valve can be controlled based on a flow signal from a thermal flow sensor (not shown). There is no risk of change. Therefore, the continuous suction tube 21 can suck a constant flow rate without changing the flow rate to be sucked.

(Safety mechanism 23)
The safety mechanism 23 shown in FIG. 1 is a device that is provided on the continuous suction line 20 and detects whether or not the flow rate sucked by the continuous suction tube 21 is equal to or lower than a predetermined flow rate.
Specifically, as shown in FIG. 3, the safety mechanism 23 includes a float type flow meter 24 in which a float 24 b is provided in a conical tapered tube 24 a whose upper end (downstream side) is wider than the lower end (upstream side). The LED 25 and the light receiving sensor 26 are provided at a position where the predetermined flow rate is obtained.
According to the safety mechanism 23, the float 24b rises with the flow rate of the fluid sucked by the continuous suction tube 21. When the flow rate exceeds the predetermined flow rate, the float 24b blocks the light of the LED received by the light receiving sensor 26, and therefore detects whether the continuous suction tube 21 is within the predetermined flow rate with the amount of light received by the light receiving sensor 26. Is going.
Here, the predetermined flow rate refers to a flow rate at which the continuous suction tube 21 sucks may damage the mucous membrane in the trachea of the patient S.

(Variable pressure regulator 40)
A variable pressure regulator 40 shown in FIG. 1 is connected to a suction device 100, which will be described later, a suction line 10 and a continuous suction line 20 as needed, and a suction line 10 and a continuous suction line which are suctioned by the suction device 100. This is a device that keeps the suction pressure of 20 constant.
Specifically, a diaphragm-type regulator is an example of the fluctuation-compatible pressure regulator 40. According to this, even if the suction pressure of the suction device 100 suddenly fluctuates, the diaphragm expands or contracts, and the suction pressure of the suction line 10 and the continuous suction line 20 can be kept constant as needed.

(Suction device 100)
The suction device 100 has a pipe embedded in a wall of a facility such as a hospital, and is divided into each room from the pipe so that suction can be performed in each room. Is provided, and when connected to the suction port, the connected pipe is negatively pressured to enable suction.
As shown in FIG. 1, the suction device 100 in the embodiment includes a suction tube 11 and a continuous suction tube 21 connected to each other via a fluctuation-compatible pressure regulator 40, and the suction tube 11 and the continuous suction tube as needed. 21 is continuously negatively pressurized at a predetermined pressure.
The pressure in the piping of the suction device is -300 to -500 mmHg (-40 to -66.7 kPa), and the maximum flow rate at the end is 40 NL / min (NL / min is 1 degree at 0 degree) The amount of gas) is defined as Japanese Industrial Standard (JIST7107).

(how to use)
Next, a method for using the suction system 1 in the embodiment will be described with reference to the drawings.

(1) As shown in FIG. 1, the suction device 100 continuously sucks the connected suction line 10 and the continuous suction line 20 via the fluctuation-compatible pressure regulator 40.
Here, in the suction line 10 as needed, the suction pressure of the suction tube 11 is controlled by the pressure regulator 12 as needed. Therefore, the suction pressure of the suction tube 11 is controlled to be zero at any time except when sucking sputum accumulated in the trachea or saliva in the oral cavity. .
Further, since the continuous suction line 20 is provided with a pressure fluctuation-compatible flow meter 22, the continuous suction tube 21 has a suction pressure for sucking 300 ml of fluid per minute.

(2) The continuous suction tube 21 continuously sucks the sputum generated in the oral cavity through the connected sputum suction tube 53 with a suction pressure that sucks 300 ml of fluid per minute. Since the suction pressure of the suction tube 11 is zero at any time, no suction is performed.

(3) On the other hand, when saliva accumulates in the oral cavity, the suction pressure of the suction tube 11 is adjusted to about −18 kPa as needed by operating the operation unit (not shown) of the pressure regulator 12 interposed in the suction line 10 as needed. To do. Therefore, the suction tube 11 can suck the saliva in the oral cavity as needed.
In addition, when suction cannot be performed by the above-described continuous suction and soot has accumulated in the trachea, the artificial respiration tube connected to the tracheal cannula 50 is removed, and the respiratory path of the opened tracheal cannula 50 as shown in FIG. The suction tube 11 is inserted through 51 as needed. According to this, the suction tube 11 can reach the trachea at any time via the respiratory path 51, and the soot collected in the trachea can be sucked.
Here, if the pressure regulator 12 increases the suction pressure of the suction tube 11 as needed, the suction pressure of the continuous suction line 20 may change as shown in FIG. However, each line of the suction line 10 and the continuous suction line 20 has the pressure fluctuation type flow meter 22 so that the flow rate in the continuous suction tube and the continuous suction line in the continuous suction line 10 and the continuous suction line 20 is as follows. A flow rate of 300 ml per minute is maintained without fluctuation.

Although the method of using the suction system 1 has been described above, according to the system, since the sputum generated in the trachea of the patient S is continuously sucked, the number of times the sputum accumulates in the trachea is reduced. Therefore, it is possible to reduce the labor of performing suction as needed every time soot accumulates in the trachea.
In addition, the suction pressure for continuously sucking sputum generated in the patient's trachea and saliva flowing into the trachea is low enough to suck 300 ml of fluid per minute, so there is a risk of damaging the patient's mucous membrane Absent.
In addition, according to the system, since the suction line is provided at any time, sputum accumulated in the trachea and saliva in the oral cavity can be sucked as needed.

Further, according to the conventional suction system, if the suction pressure of the suction device that is a negative pressure source fluctuates, the suction pressure of the suction line and the continuous suction line that sucks saliva or sputum fluctuates, and the inside of the patient's trachea There was a risk of damaging the mucous membrane.
However, according to the suction system 1 of the present invention, since the fluctuation-compatible pressure regulator 40 is interposed, the suction line 10 and the continuous suction line 20 are always kept at a constant suction pressure even if the suction pressure of the suction device 100 fluctuates. In this case, sputum or saliva can be sucked, and there is no risk of damaging the mucous membrane in the patient's trachea due to fluctuations in suction pressure.

Also, according to the prior art, when performing suction at any time, the pressure regulator provided in the suction line at any time varies the suction pressure of the suction tube at any time. The suction pressure of the line may also fluctuate and damage the mucous membrane in the trachea.
However, since the suction system 1 according to the present invention has the pressure fluctuation-compatible flow meter 22, even if the suction pressure of the suction tube 11 is changed at any time, the flow rate in the continuous suction tube 21 does not change for one minute. A flow rate of 300 ml per minute can be maintained.
Therefore, according to the present invention, there is no possibility of damaging the mucous membrane of the patient S due to fluctuations in flow rate fluctuations in the continuous suction tube 21 due to fluctuations in the suction pressure of the suction tube 11 as needed.

In addition, according to the prior art, when the pressure fluctuation-compatible flow meter fails, the flow rate to be sucked in the continuous suction line is not controlled. That is, there is a risk of damaging the mucous membrane of the patient S due to an increase in the flow rate of suction with the continuous suction tube.
However, according to the suction system 1 of the present invention, since the continuous suction line 20 includes the safety mechanism 23, the float 24b shown in FIG. The amount of light received decreases.
That is, it is possible to detect whether or not the suction flow rate is equal to or less than a predetermined flow rate based on whether or not the amount of light received by the light receiving sensor 26 has decreased. Therefore, when the flow rate is detected by the light receiving sensor 26 to be equal to or higher than the predetermined flow rate, the valve can be closed and a situation in which the mucous membrane of the patient S is damaged can be avoided.

DESCRIPTION OF SYMBOLS 1 Suction system 10 Anytime suction line 11 Anytime suction tube 12 Pressure regulator 17, 27 Fluid collection container 20 Continuous suction line 21 Continuous suction tube 22 Pressure fluctuation type flow meter 23 Safety mechanism 40 Fluctuation type pressure regulator 50 Tracheal cannula 53 痰 Inhalation Tube 100 suction device

Claims (5)

A suction system that sucks saliva and sputum by being sucked into a suction device,
A continuous suction line that is connected to a tracheal cannula placed in the trachea and continuously sucks sputum generated in the trachea;
An occasional suction line that aspirates saliva in the oral cavity or sputum that accumulates in the trachea;
A suction system comprising: The tracheal cannula has a cuff on the outer peripheral surface on the tip side,
The suction system according to claim 1, wherein the continuous suction line sucks sputum at a lower part of the cuff on the lung side.   3. The suction system according to claim 1, wherein a fluctuation-compatible pressure regulator corresponding to fluctuations in suction pressure is provided between the suction device and the continuous suction line and the suction line as needed. The continuous suction line includes a flow meter that controls a flow rate of suction;
The suction system according to any one of claims 1 to 3, further comprising a safety mechanism that detects whether or not the flow rate to be sucked is within a predetermined flow rate. The continuous suction line includes a flow meter for controlling the flow rate of suction,
The suction system according to any one of claims 1 to 4, wherein the flowmeter is a pressure fluctuation-compatible flowmeter corresponding to a fluctuation in suction pressure.

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