JP2002011100A - Artificial respiration equipment and its monitoring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable to detect precisely the carbon dioxide volume exhausted by a patient in the artificial respiration equipment of high frequency ventilation type. SOLUTION: A high pressure vibration is given to the gas inside the respiratory circuit 2, 3, with which (the lung H of) the patient K is connected, by a high frequency vibration generating device 15. The inspiration gas volume is measured by a sensor 12 which is connected with the inspiratory circuit 2. The carbon dioxide concentration is measured by a sensor 22 which is connected with the expiratory circuit 3. Based on the inspiration gas volume and the carbon dioxide concentration which are measured, the carbon dioxide volume (for example, carbon dioxide volume per minute) is calculated by a controller 31. The carbon dioxide volume calculated is displayed on the display screen 32.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an artificial respirator for applying high-frequency vibration to gas in a breathing circuit.

[0002]

2. Description of the Related Art Most artificial respirators are of a low-frequency ventilation type which performs the same number of respirations as a healthy person, and the number of respirations per minute is about 20 times. On the other hand, recently, a high-frequency ventilation type artificial respiration apparatus that vibrates gas in a respiratory circuit at a high frequency (often, vibrates at about 15 times per second) has been increasingly used (for example, See JP-A-2-131772).

As one method of knowing the ventilation state of a patient during artificial respiration, it is required to detect a value related to the amount of carbon dioxide (CO2) discharged from the patient. In a normal low-frequency ventilator, it is possible to accurately detect the concentration of carbon dioxide in the end gas discharged from the expiration circuit by the carbon dioxide detector, and that the concentration of carbon dioxide in the end gas is a patient's Since the concentration of the carbon dioxide gas in the blood matches well with the concentration of the carbon dioxide gas in the blood, the detected concentration of the carbon dioxide gas in the expired gas can be used as it is as a value relating to the amount of carbon dioxide gas discharged from the patient.

[0004]

However, in a high-frequency ventilation artificial respirator, the end gas discharged from the expiration circuit is vibrated at a high frequency, so that the response of the carbon dioxide concentration detector follows. However, the method of measuring the concentration of carbon dioxide in the terminal gas cannot be adopted since the terminal gas is not diffused and the terminal gas is subjected to a diffusion action by high frequency vibration. For this reason, it is conceivable to measure the concentration of carbon dioxide in the patient's blood by using a percutaneous monitor or by collecting blood, but it is of course that the patient suffers considerable pain, It is not possible to monitor values for quantities.

The present invention has been made in view of the above circumstances, and a first object of the present invention is to calculate a value relating to the amount of carbon dioxide gas discharged from a patient on the assumption that a high-frequency ventilation system is used. It is an object of the present invention to provide an artificial respiration apparatus which can continuously monitor without directly acting on a patient's blood.

A second object of the present invention is to provide a value relating to the amount of carbon dioxide gas discharged from a patient directly to the blood of a patient, which is used in addition to a high-ventilation type ventilation apparatus. It is an object of the present invention to provide a monitoring device for an artificial respiratory apparatus which can continuously monitor without any need.

[0007]

Means for Solving the Problems In order to achieve the first object, the present invention adopts the following solution. That is, in an artificial respiratory apparatus configured to apply high-frequency vibration to gas in a breathing circuit as described in claim 1 of the claims, an inspiratory gas amount detecting means for detecting an inspiratory gas amount flowing through an inspiratory circuit; A carbon dioxide gas concentration detecting means for detecting a carbon dioxide gas concentration in an expiratory circuit, and a carbon dioxide gas concentration detected by the carbon dioxide gas concentration detecting means and a carbon dioxide gas concentration detected by the carbon dioxide gas concentration detecting means, Emission value calculation means for calculating a value related to the amount of carbon dioxide discharged from the patient connected to the breathing circuit, and display means for displaying a value related to the amount of carbon dioxide calculated by the emission value calculation means There is.

[0008] The value calculated by the emission value calculation means, that is, the value relating to the amount of carbon dioxide gas that is laid on the display means can be the amount of carbon dioxide gas per predetermined time (for example, volume value). The carbon dioxide concentration detecting means continuously outputs an output related to the carbon dioxide concentration with the lapse of time, and the emission value calculating means performs a moving integration every predetermined time, and calculates the moving integrated value. It can be displayed on the display means.
By connecting the carbon dioxide concentration detecting means to a middle part of the expiration circuit via a water trap serving as a volume portion, it is preferable to detect a more averaged carbon dioxide concentration.

The intake gas amount detecting means, the carbon dioxide concentration detecting means, the emission value calculating means, and the display means can each be provided in a case for an artificial respiratory apparatus and set.
In this case, the controller that constitutes the display means and the calculation means can use those provided in the artificial respiration apparatus. Note that a high-frequency vibration generating means for giving high-frequency vibration to the gas in the breathing circuit may be provided in the case.

In order to achieve the second object, the present invention adopts the following solution. That is, as described in claim 6 of the claims,
Equipped with an inspiratory gas amount detecting means for detecting an inspiratory gas amount flowing through the inspiratory circuit and connected to an artificial respirator adapted to apply high-frequency vibration to gas in the respiratory circuit, and discharged from a patient connected to the artificial respiratory device A monitor device for notifying the amount of carbon dioxide gas to be performed, a case, a controller mounted on the case, and a controller mounted on the case,
Display means for receiving an output from the controller, carbon dioxide concentration detection means provided in the case and having a first connector for outputting to the controller and for an expiration circuit of a ventilator, the case being equipped with the case, A second connector for connecting a controller and the intake gas amount detecting means, wherein the controller detects the intake gas amount detected by the intake gas amount detecting means and the intake gas amount detected by the carbon dioxide concentration detecting means. Based on the concentration of carbon dioxide, a value relating to the amount of carbon dioxide per predetermined time discharged from the patient is calculated, and the calculated value is set to be displayed on the display means. is there. The case may further include a water trap interposed between the first connector and the carbon dioxide concentration detecting means.

It should be noted that the object of the present invention is not limited to the specified one, but implicitly includes providing what is substantially preferred or expressed as an advantage. Further, the present invention can be expressed as a method of monitoring the amount of carbon dioxide.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIG. 1, K is a patient and H is a lung of the patient K. An inspiratory circuit 2 and an exhalation circuit 3 are connected to a patient connection circuit 1 connected to the lung K, and the confluence of these circuits 1, 2 and 3 is indicated by reference numeral 4. These circuits 1 to 3 constitute a breathing circuit. The inspiratory circuit 2 allows the inspiratory gas for artificial respiration to flow toward the junction 4. The inspiratory circuit 2 includes a flow control valve 11 and a flow meter (inspiratory gas amount) sequentially from the upstream side in the inflow direction of the inspiratory gas. (Detection means) 12 is connected. The exhalation circuit 3 discharges exhaled gas from the junction 4 to the atmosphere, and an exhalation valve 13 is connected near the final end.

A high-frequency vibration generator (high-frequency vibration generating means) 15 is connected to an intermediate portion of the expiration circuit 3 via a high-frequency vibration circuit 14. In the middle of the high-frequency vibration circuit 14, a movable partition (for example, a diaphragm)
16 are connected. The high-frequency vibration generator 15 generates high-frequency vibration of air (for example, about 15 vibrations per second).
To the respiratory circuit 3, that is, the respiratory circuit, causing the gas in the respiratory circuit to vibrate at high frequency, thereby ventilating between the lungs H of the patient K and the inspired gas (replacement of carbon dioxide and oxygen).
Is performed. The movable partition 16 shuts off the high-frequency vibration generator 15 and the exhalation circuit 3 in an airtight (hygienic) manner, thereby preventing the high-frequency vibration generator 15 from being contaminated by the patient K.

If the high-frequency vibration generator 15 is cleaned (sterilized) every time a different patient is used, the movable partition 16 need not be separately provided. Further, the portion to which the high-frequency vibration generator 15 is connected is not limited to the expiration circuit 3 but may be connected to the inspiration circuit 2, but is preferably connected to a position near the lung H of the patient K. Further, as the high-frequency vibration generator 15, a known appropriate type such as a type that reciprocates a piston or a type that uses a blower and a rotary switching valve as described in the above-mentioned publication is used. Can be.

A carbon dioxide concentration detector (detection means) 22 is connected to an intermediate portion of the expiration circuit 3 via a sampling tube 21. Sampling tube 2
A water trap 23 is connected in the middle of 1. The gas (exhaled gas) in the exhalation circuit 3 has a carbon dioxide gas concentration averaged by high-frequency vibration, and the water trap 16 has a relatively large volume. The concentration of carbon dioxide in the exhaled gas supplied to the air is promoted more evenly.

The output from the flow rate measuring device 12 (the detected intake gas amount) and the output from the carbon dioxide concentration detector 22 (the detected carbon dioxide concentration) are each configured using a microcomputer. Is input to the controller 31. The controller 31 calculates a value relating to the amount of carbon dioxide gas discharged from the patient K, and the calculation result is displayed on a display device (display means) 32 including, for example, a liquid crystal screen or the like.

In the embodiment, the flow rate measuring device 12 is configured to continuously output the detected intake gas amount to the controller 31 as time passes (analog output). Similarly, in the embodiment, the carbon dioxide concentration detector 22 is configured to output the detected carbon dioxide concentration continuously to the controller 31 as time passes (analog output).

The controller 31 includes two detectors 11 and 22.
The output from is subjected to moving integration every predetermined time (for example, one minute) to calculate the amount of carbon dioxide per predetermined time (volume in the embodiment). For example, the amount of carbon dioxide at the time of the sampling is calculated from the detected amount of intake gas and the concentration of carbon dioxide in a sampling cycle every 5 seconds, and the calculated amount of carbon dioxide is subjected to moving integration for one minute. , The total amount of carbon dioxide per minute is calculated. For example, assuming that the amount of inspired gas detected at a certain sampling time is X liters and the concentration of carbon dioxide detected at this time is Y%, the amount Z of carbon dioxide discharged from the patient K is X × Y × It becomes 1/100 liter. Then, the obtained carbon dioxide gas amount Z is moved and integrated for one minute to calculate the carbon dioxide gas discharge amount per minute, and the total carbon dioxide gas amount is displayed on the display device 32.

The values detected by the detectors 11 and 12 are temporarily stored for each predetermined sampling period, and when the stored values for a predetermined time (for example, one minute) are obtained, the total value is obtained. The amount of carbon dioxide can also be calculated. That is, it suffices if a calculated value corresponding to the moving integration is finally obtained. As a moving integration method, the moving integrated value is finally obtained by adding the amount of carbon dioxide calculated for each sampling time for a predetermined time. Alternatively, the moving integral value may be calculated all at once from the detected values stored up to a predetermined time.

FIG. 2 is a flowchart showing the control contents of the controller 31. This flowchart will be described below. In the following description, Q indicates a step. First, in Q1, it is determined whether or not a transition is made, that is, whether or not the fluctuation of the inspiratory gas amount is large (for example, when the operation of the artificial respiratory apparatus starts or when the inspiratory gas amount is changed, it is stable) Until a predetermined period of time for the operating state has elapsed, it is assumed to be a transitional state). If the determination in Q1 is NO, in Q2 the outputs (detected intake gas amount, carbon dioxide concentration) from the detectors 11 and 22 are read, and the read values are temporarily stored. In Q3, it is determined whether or not measurement has been performed for a predetermined time (for example, one minute). If the determination in Q3 is YES, Q
In step 4, the total amount of carbon dioxide per predetermined time is calculated by moving integration. Then, in Q5, the calculated total carbon dioxide gas amount is displayed on the display device 32.

If the determination in Q1 is NO, the process returns to Q1 after clearing the measured value up to that time in Q6. When the total carbon dioxide gas amount calculated in Q4 is an abnormal value (for example, at least one of an upper limit or more and a lower limit or less), a separately provided alarm buzzer may be activated.

Referring again to FIG. 1, the above-described various devices 1
1, 12, 13, 15, 16, 22, 23, 31, 32
Are all provided in a case C for a high-frequency ventilation type artificial respiration apparatus. In this case, since the high-frequency ventilation type ventilator has the flow rate measuring device 12, the controller 31, and the display device 32, the carbon dioxide concentration detector 22 is separately provided for monitoring the carbon dioxide gas amount. That is to say, a program corresponding to the calculating means is separately incorporated into the controller 31. Note that the high-frequency vibration generator 15 may be provided outside the case C depending on the type of the artificial respirator.

FIG. 3 shows an example in which a monitoring device for monitoring carbon dioxide gas is separately provided independently of the high-frequency ventilation type artificial respiration device, and the same elements as those shown in FIG. Is attached. In FIG. 3, a case C that can be carried independently and independently of a case C for an artificial respiration apparatus
2 are provided. The case C2 includes a carbon dioxide concentration detector 22, a water trap 23, a controller 31,
A display device 32 is provided. In such a monitor device, a first connection connector 41 and a second connection connector 42 are separately provided in order to connect to the artificial respiration device. First
The connection connector 41 is for connection to an expiration circuit (for receiving expiration gas). The second connector 42 is
It is used for connection to the flow meter 11 provided in the artificial respirator (for inputting the amount of inspired gas). By using such a monitor device, the amount of carbon dioxide gas can be continuously known in an existing high-frequency ventilation type artificial respiration device having no carbon dioxide gas monitor, similarly to the example of FIG.

[0024]

According to the first aspect of the present invention, in a high-frequency ventilation type ventilator, the value relating to the amount of carbon dioxide gas discharged from a patient is not directly affected on the blood of the patient. , You can know continuously.

According to the second aspect of the present invention, the total amount of carbon dioxide per predetermined time can be known.

According to the third aspect of the present invention, a specific method for obtaining the total amount of carbon dioxide is provided.

According to the fourth aspect of the present invention, the carbon dioxide in the exhaled gas supplied to the carbon dioxide concentration detecting means is more averaged, and the carbon dioxide concentration can be accurately detected. Is preferred.

According to the fifth aspect of the present invention, it is preferable to make the entire artificial respirator compact, including the monitoring part of the amount of carbon dioxide gas.

According to the sixth aspect of the present invention, an effect corresponding to the first and second aspects is obtained in a high-frequency ventilation type artificial respiration apparatus having no nest monitor for the amount of carbon dioxide. Becomes possible.

According to the invention described in claim 7, the effect corresponding to claim 4 can be obtained.

[Brief description of the drawings]

FIG. 1 is an overall system diagram showing an embodiment of the present invention.

FIG. 2 is a flowchart showing control contents of a controller of FIG. 1;

FIG. 3 is an overall system diagram showing a monitor device used in connection with an artificial respiration device.

[Explanation of symbols]

 C: Case of artificial respiration device C2: Case of monitor device K: Patient H: Lung 1: Patient connection circuit 2: Inspiration circuit 3: Expiration circuit 12: Inspiration gas amount detector 15: High frequency vibration generator 21: Sampling tube 22 : Carbon dioxide concentration detector 23: Water trap 31: Controller 32: Display device

Claims (7)

[Claims] 1. An artificial respiratory apparatus for applying high-frequency vibration to gas in a respiratory circuit, an inspiratory gas amount detecting means for detecting an inspiratory gas amount flowing through the inspiratory circuit, and a carbon dioxide gas concentration in the expiratory circuit. Carbon dioxide concentration detecting means; and exhaled from a patient connected to a breathing circuit based on the inspired gas amount detected by the inspired gas amount detecting means and the carbon dioxide concentration detected by the carbon dioxide concentration detecting means. An artificial respiratory apparatus comprising: an emission value calculating unit that calculates a value related to a carbon dioxide amount; and a display unit that displays a value related to the carbon dioxide amount calculated by the emission value calculating unit. 2. The method according to claim 1, wherein the value relating to the carbon dioxide gas amount calculated by the emission value calculating means is a carbon dioxide gas amount per predetermined time, and the display means displays the carbon dioxide gas amount per predetermined time. An artificial respiration apparatus, which is displayed. 3. The apparatus according to claim 2, wherein the carbon dioxide concentration detecting means continuously outputs an output relating to the carbon dioxide concentration with the passage of time, and the emission value calculating means comprises a control unit for detecting the output of the both detecting means. An artificial respiration apparatus characterized in that a carbon dioxide gas amount per predetermined time is calculated by performing a moving integration of the carbon dioxide gas amount obtained based on the output at every predetermined time. 4. The apparatus according to claim 1, wherein said carbon dioxide concentration detecting means is connected to a middle part of an expiration circuit via a water trap. Artificial respiration equipment. 5. The case for an artificial respiratory apparatus according to claim 1, wherein said intake gas amount detecting means, carbon dioxide concentration detecting means, emission value calculating means and display means are respectively provided in a case for an artificial respirator. An artificial respiration apparatus provided. 6. An artificial respiratory apparatus which is provided with an inspiratory gas amount detecting means for detecting an inspiratory gas amount flowing through an inspiratory circuit and is connected to an artificial respiratory apparatus adapted to apply high frequency vibration to gas in the respiratory circuit. A monitor device for notifying the amount of carbon dioxide gas discharged from the patient, comprising: a case; a controller mounted on the case; a display unit mounted on the case and receiving an output from the controller; A carbon dioxide concentration detecting means, which is provided in the case and outputs to the controller and has a first connector for an expiration circuit of an artificial respirator, and connects the controller and the inspired gas amount detecting means provided in the case. And a second connector for connecting the intake gas amount detected by the intake gas amount detection means. Based on the carbon dioxide concentration detected and detected by the carbon dioxide concentration detecting means, a value relating to the amount of carbon dioxide per predetermined time discharged from the patient is calculated, and the calculated value is displayed on the display means. A monitoring device in a ventilator, wherein the monitor device is set to: 7. The artificial respiration according to claim 6, wherein the case is further provided with a water trap interposed between the first connection connector and the carbon dioxide concentration detecting means. Monitor device in the device.